Report of Investigation
Fatal Underground Coal Mine Fire
________________________________________________________________________
U.S. Department of Labor
Mine Safety and Health Administration
2007

Aracoma Alma Mine #1
Aracoma Coal Company, Inc.
Stollings, Logan County, West Virginia
I.D. No. 46-08801
January 19, 2006

 UNITED STATES
DEPARTMENT OF LABOR
MINE SAFETY AND HEALTH ADMINISTRATION
COAL MINE SAFETY AND HEALTH
REPORT OF INVESTIGATION
Fatal Underground Coal Mine Fire
January 19, 2006
Aracoma Alma Mine #1
Aracoma Coal Company, Inc.
Stollings, Logan County, West Virginia
I.D. No. 46-08801
by
Kenneth A. Murray
District Manager, District 6, Pikeville, KY
Charles W. Pogue
Roof Control Specialist, District 2, Ruff Creek, PA
Ronald W. Stahlhut
Electrical Supervisor, District 8, Vincennes, IN
Michael G. Finnie
Supervisory Special Investigator, District 10, Madisonville, KY
Arlie A. Webb
Supervisory Special Investigator/Staff Assistant, District 6, Pikeville, KY
Anthony L. Burke
Coal Mine Safety and Health Inspector, District 6, Whitesburg, KY
Dennis A. Beiter
Supervisory Mining Engineer, Technical Support, Triadelphia, WV
William J. Francart, P.E.
Mining Engineer, Technical Support, Pittsburgh, PA
Derrick M. Tjernlund
Senior Fire Protection Engineer, Technical Support, Triadelphia, WV
Jeffrey N. Waggett
Civil Engineer, Technical Support, Pittsburgh, PA
Originating Office
Mine Safety and Health Administration
Office of the Administrator
Coal Mine Safety and Health
1100 Wilson Boulevard
Arlington, Virginia 22209
Kevin G. Stricklin, Acting Administrator

 TABLE OF CONTENTS
OVERVIEW................................................................................................................................... 1
GENERAL INFORMATION ...................................................................................................... 2
DESCRIPTION OF THE ACCIDENT ....................................................................................... 4
Activities Prior to the Accident.............................................................................................. 4
Production Crews .................................................................................................................... 5
Outby Belt Examiners.............................................................................................................. 5
The Fire ...................................................................................................................................... 7
The Order to Evacuate............................................................................................................. 8
Evacuation of 2 Section ........................................................................................................... 9
Longwall Section Activities During the Fire...................................................................... 13
Initial Rescue and Firefighting Attempts ........................................................................... 14
MINE RESCUE AND RECOVERY OPERATIONS............................................................... 16
INVESTIGATION OF THE ACCIDENT ................................................................................ 21
DISCUSSION .............................................................................................................................. 21
Training ................................................................................................................................... 22
Roof Control Plan................................................................................................................... 23
Mine Emergency Evacuation and Firefighting Program of Instruction ........................ 24
Self-Contained Self Rescuers ................................................................................................ 25
SCSR Training, Testing and Examination Requirements............................................. 26
Required SCSR Training.................................................................................................. 26
Required SCSR Examinations and Tests ......................................................................... 27
Investigative Examination and Testing of Recovered SCSRs...................................... 28
Mine Ventilation Plan............................................................................................................ 29
Mine Ventilation..................................................................................................................... 31
Development Sections ....................................................................................................... 32
Longwall Section and Bleeder System ............................................................................ 33
Methane Liberation............................................................................................................ 34
Ventilation System Maintenance and Stability.............................................................. 34
Changes in Ventilation ...................................................................................................... 35
Belt Air Regulations............................................................................................................... 40
Atmospheric Monitoring System ........................................................................................ 41
AMS Event Log .................................................................................................................. 44
AMS Sensor Calibration Records..................................................................................... 44
Laboratory Testing............................................................................................................. 45
AMS Installation and Maintenance Related Deficiencies ............................................ 46
Alert, Alarm, and Malfunction Signal Response Deficiencies .................................... 48
AMS Response on January 19, 2006 ................................................................................ 49
Electrical System .................................................................................................................... 52
Electrical Examinations and Tests ................................................................................... 53
Inspection of the 9 Headgate Longwall Belt Drive Electrical Components .............. 53
Water Sprinkler System for the 9 Headgate Longwall Belt ......................................... 54
Escapeways, Escapeway Maps and Drills.......................................................................... 55

 Underground Escapeways ............................................................................................... 56
Main Escapeways ............................................................................................................. 57
Escapeways from 2 Section ............................................................................................... 57
9 Headgate Longwall Section Escapeways ....................................................................... 58
Escapeway Drills................................................................................................................ 59
Mine Examinations ................................................................................................................ 60
Preshift and On-shift Examinations ................................................................................ 62
9 Headgate Longwall Belt................................................................................................. 62
Dual Switch House Installation Project........................................................................... 64
No. 7 Belt and Underground Electrical Installations for the 9 Headgate Longwall Belt
Drive and Takeup Storage Unit ....................................................................................... 65
No. 7 Belt Structure Extension Project ............................................................................ 66
Roadway from NEM to 2 Section..................................................................................... 67
Weekly Examinations........................................................................................................ 68
Intake Air Courses and Primary Escapeway for 2 Section............................................... 69
No. 7 Belt Air Course ....................................................................................................... 70
Intake Air Course and Primary Escapeway for 9 Headgate Longwall Section ................ 71
Alternate Escapeways for 2 Section and 9 Headgate Longwall Section........................... 71
9 Tailgate Air Course........................................................................................................ 72
Fire Protection ........................................................................................................................ 72
Water Supply System ........................................................................................................ 72
Freshwater Supply Tank ................................................................................................... 73
Underground Freshwater Pumps.................................................................................... 75
Water Supply and Mine Elevations................................................................................. 76
Valved Firehose Outlets.................................................................................................... 76
Firehoses and Connections ............................................................................................... 76
Annual Functional Tests ................................................................................................... 77
Longwall Belt Fire Protection........................................................................................... 77
Conveyor Belt Flame Resistance Testing........................................................................ 78
Area of Fire Origin and Flame Propagation ...................................................................... 79
Observations ....................................................................................................................... 80
Belt Entry Slope and Its Effect on Flame Propagation.................................................. 81
Point of Fire Origin ............................................................................................................ 82
Continuity and Availability of Combustible Materials in the Area of Fire Origin .. 82
Fire Spread Inby the Area of Origin................................................................................ 82
Potential Ignition Sources ..................................................................................................... 83
Sources of Ignition ............................................................................................................. 83
Belt Material Response-to-Fire Considerations ............................................................. 86
Likely Initial Fuel Source .................................................................................................. 87
Additional Information ......................................................................................................... 87
Previous Belt Entry Fires and Other Incidents .............................................................. 87
8 Headgate Longwall Belt Takeup Storage Unit Fire....................................................... 87
October 8, 2005, AMS Response ...................................................................................... 88
December 23, 2005, Fire ................................................................................................... 89

 December 29, 2005, Fire ................................................................................................... 90
Corporate Communications ................................................................................................. 92
ROOT CAUSE ANALYSIS ....................................................................................................... 92
CONCLUSION........................................................................................................................... 97
ENFORCEMENT ACTIONS .................................................................................................... 98
TABLES
Table 1 - Incident Rates for 2005 ................................................................................................ 4
Table 2 - Information on SCSRs for Afternoon Shift 2 Section Personnel ......................... 27
Table 3 - Results of Laboratory Tests on SCSRs .................................................................... 29
Table 4 - Abridged AMS Event Log from January 19, 2006................................................. 50
FIGURES
Figure 1. Evidence of belt misalignment. ................................................................................ 7
Figure 2. Seating arrangement of miners on 2 Section diesel mantrip.............................. 10
Figure 3. Absence of critical ventilation control. .................................................................. 37
Figure 4. Area inby No. 7 Belt tail pulley. ............................................................................. 38
Figure 5. Critical ventilation control removed prior to fire. ............................................... 38
Figure 6. Location where belt structure was installed after removal of a stopping........ 39
Figure 7. Additional critical ventilation control removed prior to fire............................. 40
Figure 8. Former location of stopping at the electrical installation. .................................. 40
Figure 9. Carbon monoxide sensor......................................................................................... 41
Figure 10. Remote alarm unit in headgate area on longwall section. ............................... 42
Figure 11. AMS in dispatcher’s office located in Box Cut on surface................................ 42
Figure 12. Relative CO Sensor Locations on January 19, 2006. .......................................... 51
Figure 13. Grooves cut into the rear frame assembly. ......................................................... 63
Figure 14. 4-inch water valve (found in “off” position) ...................................................... 75
APPENDICES
Appendix A
Appendix B
Appendix C
Appendix D

Appendix E
Appendix F

Mine Map
Active Underground Areas
Management Structure
Mine Map
Area Surrounding 9 Headgate Longwall Section and 2 Section
Mine Map and Drawing
9 Headgate Longwall Belt Takeup Storage Unit - Basic Components and
Operation Description
Mine Map
Affected Area of Mine, Portion of North East Mains
Mine Map
Affected Area of Mine, Detail of Area Surrounding 2 Section Mantrip

 APPENDICES (Continued)
Appendix G

Timeline
Events that Occurred at Aracoma Alma Mine #1 on January 19, 2006
Appendix H List of Mine Rescue Teams and Team Members
Appendix I
Victim Data Sheets
Appendix J
List of Investigation Participants
Appendix K Mine Map
Mine Ventilation Map 1 of 2
Appendix L Mine Map
Mine Ventilation Map 2 of 2
Appendix M Mine Map
Image of Mine Map Identified by Operator Representatives Maintained
as the Map 30 CFR Section 75.1202-1 Required to be Kept up-to-date
with Temporary Notations
Appendix N Mine Map
Atmospheric Monitoring System Carbon Monoxide Sensor Locations
Appendix O Mine Map
Electrical and Freshwater Supply Systems Schematic
Appendix P Mine Map
Electrical and Freshwater Supply Systems Schematic Detail Views
Appendix Q Mine Map
Escapeways for 2 Section and 9 Headgate Longwall Section
Appendix R Mine Map
Primary Escapeways for 2 Section and 9 Headgate Longwall Section to
Box Cut
Appendix S
Mine Map
Image of 2 Section Escapeway Map
Appendix T Mine Map
Image of 9 Headgate Longwall Section Escapeway Map
Appendix U Graph
Hydraulic Elevation Profile
Appendix V Mine Map
9 Headgate Longwall Belt Drive Area Fire Protection
Appendix W Belt Flame Test Results
Appendix X Mine Map
Extent of Fire Spread
Appendix Y Spontaneous Combustion Test Results on Coal Samples
Appendix Z Locations and Responses of CO Sensors for Events on October 8, 2005,
December 23, 2005, and December 29, 2005
Appendix AA Corporate Communications Memos

 ARACOMA ALMA MINE #1
MSHA ID No. 46?08801
ARACOMA COAL COMPANY. INC.

North East Moins Area After Fire
(roof tolls not shown)

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No. 7' Belt

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SCSR top
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Longwoll Belt

OVERVIEW
At approximately 5:14 p.m. on January 19, 2006, a fire occurred at the 9 Headgate
longwall belt takeup storage unit of the Aracoma Alma Mine #1, resulting in the deaths
of two miners. Twenty-nine underground miners were working on this shift. Initial
attempts to extinguish the fire failed, and observations at the scene indicated that smoke
from the fire was traveling further into the mine via the 2 Section intake air course.
Miners in affected areas were neither immediately notified nor withdrawn following
the initial carbon monoxide (CO) alarm signal from the Atmospheric Monitoring
System (AMS).
After the 2 Section foreman was informed that smoke from the fire was traveling
toward the section in the intake air course, he assembled the other 11 miners working
on the section and began an evacuation. The foreman told the miners if they
encountered smoke and were unable to travel all the way out the roadway, they would
move into the adjacent North East Mains (NEM) belt entry through a personnel door.
The 2 Section crew boarded a rubber-tired diesel mantrip and began traveling out the
roadway in the intake air course. After traveling approximately 1,800 feet, the crew
smelled smoke. The crew continued traveling in the mantrip for approximately 400 feet
before they encountered light smoke. Following the roadway, the mantrip turned right
and traveled through a crosscut into an adjacent intake entry, where the crew
encountered dense, black smoke that prevented further travel by mantrip. The crew
immediately exited the mantrip and began traveling outby on foot toward a personnel
door. The miners traveled from 100 to 225 feet in smoke before donning their Self
Contained Self Rescuers (SCSRs). After donning their SCSRs, groups of miners held
onto each other in the dense smoke, feeling their way along the coal rib as they moved
outby. Ten of the miners found the personnel door and entered the clear air in the belt
entry.
Once in the smoke-free air, the miners discovered that Don Bragg and Ellery Hatfield
were missing. Three miners returned to the smoke-filled intake air course to search for
the missing men, but were unable to find them and re-entered the belt entry. The ten
miners continued the evacuation via the alternate escapeway to a safe area outby the
fire. Miners from 2 Section and the longwall section assisted in attempts to reduce the
air flow to the fire before being evacuated to the surface.
Mine management personnel traveled underground in an attempt to locate the missing
miners and extinguish the fire, but were unsuccessful. Meanwhile, mine rescue teams
were called to the mine to continue the rescue and firefighting efforts. Smoke and heat
hampered search and rescue activities as the fire continued burning. On January 21, the
bodies of the two missing miners were discovered approximately 575 feet apart in
NEM, and transported to the surface. The fire was fully extinguished on January 24.

1

 The fire occurred as a result of frictional heating when the longwall belt became
misaligned in the 9 Headgate longwall belt takeup storage unit. Frictional heating
ignited accumulations of combustible materials which served as a readily ignitable fuel.
This further contributed to the ignition of the belt and to the intensity and extent of the
mine fire. The required fire suppression system was not installed and there was no
water available in the area to fight the fire. Airflow carried the smoke from the fire to
the No. 7 Belt entry and then into the primary escapeway for 2 Section because
stoppings that were required to maintain separation between the belt entry and the
primary escapeway for 2 Section had previously been removed.
Examinations of the mine were inadequate and failed to identify the lack of separation
between the primary escapeway and belt air course. Examiners were not always
provided with an anemometer or other means to measure air velocity and airflow
direction during examinations of the belt entries. Not all examiners were provided
adequate gas detection equipment on all shifts. In addition, examinations of safety
systems failed to identify deficiencies which contributed to the severity and extent of
the mine fire.
Mine management did not immediately withdraw miners from the affected areas
(2 Section and the longwall section) when the AMS generated an alarm signal.
Approximately 28 minutes elapsed between the time of the first CO alarm and the time
evacuation of the miners on 2 Section was initiated. Two miners from 2 Section became
separated from the other miners during the evacuation and perished. The remaining
twenty-seven miners working underground escaped safely.
As a result of the investigation, MSHA issued 25 citations and orders for violations
which contributed to the cause or severity of the accident. Of these, 21 were the result
of reckless disregard on the part of the mine operator. Five of the citations and orders
were related to the belt air rule. Had the mine operator been in compliance with the
belt air rule, the fire would not have resulted in the two fatalities. These contributory
violations are listed at the end of this report in the “Enforcement Actions” section.
GENERAL INFORMATION
Aracoma Coal Company, Inc.’s Aracoma Alma Mine #1 is an underground coal mine
located on Bandmill Hollow Road, approximately 1.5 miles off Route 17 North, near
Stollings in Logan County, West Virginia. Production at the mine began on October 1,
1999. The mine has been owned and operated by Massey Energy Company throughout
its history. The active underground areas of the mine are shown in Appendix A.
Principal officers of Aracoma Coal Company, Inc. included Dwayne B. Francisco,
President; Eddie Lester, Vice President of Operations; Gary Goff, General Manager;
Lawrence Lester, Superintendent; and Charles Conn, Safety Director. Information
provided by the mine operator relative to the corporate management structure, as it
existed at the time of the fire, is shown in Appendix B.
2

 At the time of the accident, coal was extracted from the Alma Coal Seam which ranged
from 30 to 60 inches in thickness throughout the mine, with an average cover of 800 feet
and a maximum cover of 1,200 feet. The immediate roof strata consisted of up to 12
inches of gray sandy shale, and 20 to 25 feet of solid sandstone. Coal was produced on
a longwall section and two continuous mining machine sections. Coal was transported
from the working sections to the surface via a series of belt conveyors.
Longwall panels at this mine varied from 3,600 to 6,000 feet in length with faces
approximately 1,000 feet wide. Production on the longwall section, located in
9 Headgate, began in September, 2005. The 9 Headgate longwall section had mined
approximately 3,500 feet. Approximately 1,575 feet remained in the panel. Longwall
section equipment included a shearer and related components, one scoop, and one
shield hauler. The roof along the longwall face was supported by longwall shield units.
The continuous mining machine section designated as 2 Section was developing four
entries in 11 Headgate off NEM. The 2 Section Nos. 1 and 4 Entries were the section
return air courses, and Nos. 2 and 3 Entries were the section intake air courses. The No.
2 Entry was also the belt haulage entry. Development equipment on 2 Section consisted
of two continuous mining machines, three shuttle cars, two roof bolting machines, three
scoops, and a feeder.
The continuous mining machine section designated as 3 Section developed the 3 West
Mains off North West Mains. Nos. 1 and 7 Entries of this seven entry development
were the section return air courses. Nos. 2 and 3 Entries were section intake air courses.
The Nos. 5 and 6 Entries were common with the belt haulage entry, which was located
in the No. 4 Entry. Development equipment on 3 Section included two continuous
mining machines, three shuttle cars, two roof bolting machines, three scoops, and a
feeder.
During the third and fourth quarters of Calendar Year (CY) 2005, coal production at the
mine was reported as 352,242 and 541,413 tons, respectively. Total employment for
these two quarters was reported as 171 and 178 persons, respectively. At the time of the
accident, the mine employee roster listed 173 employees. The miners were not
represented by a labor organization.
Table 1 shows the Non-Fatal Days Lost (NFDL) and overall incidence rates for the
Aracoma Alma Mine #1, along with comparable national rates for all underground coal
mines. The overall incidence rate is a compilation of the Fatal, NFDL, and No Days
Lost incidence rates. Incidence Rates are the number of incidents that occur per 200,000
hours of employee exposure. The table shows the rates for 2005. The accident occurred
during the 1st Quarter of 2006.

3

 Table 1. Incidence Rates for 2005

Incidence Rate
NFDL
Overall

Aracoma Alma Mine #1
7.20
10.59

National Average
3.51
5.10

A Safety and Health Inspection by the Mine Safety and Health Administration (MSHA)
had begun on January 3, 2006, and was in progress at the time of the accident. The
previous Safety and Health Inspection had been completed on December 23, 2005. The
last underground MSHA inspection activity at the Aracoma Alma Mine #1 prior to the
accident was on January 13, 2006.
DESCRIPTION OF THE ACCIDENT
Activities Prior to the Accident
On Thursday, January 19, 2006, at approximately 2:30 p.m., underground miners on the
afternoon shift traveled to their assigned work locations. Production crews traveled to
the longwall section and 2 Section via rubber-tired diesel mantrips. The location of
2 Section and 9 Headgate longwall section are shown in Appendix C.
The 2 Section production crew consisted of Michael Plumley, Foreman; Roof Bolting
Machine Operators Elmer Mayhorn, Randall Crouse, Ellery Hatfield, and Don Bragg;
Shuttle Car Operators Joe Hunt, Pat Kinser, and Gary Baisden; Continuous Mining
Machine Operators Steve Hensley and Billy Mayhorn; Electrician Harold Shull; and
Scoop Operator Thomas Vanover.
The longwall section production crew consisted of Dave Runyon, Foreman; Shearer
Operator Dave Sanders; Shield Operator Arnold Lane; Headgate Operator Gary
Richardson; Utility John Brown; Electrician Joey Duty; and Maintenance Foreman Jamie
Adkins.
Other persons on the afternoon shift were assigned to duties in the belt entries,
roadways, and other outby areas of the mine. Those persons were Belt Walker Bryan
Cabell; Production Foreman Patrick Callaway; Utility Underground Brandon Conley;
Electrician Bryson Ellis; Road Grader Operator Raymond Grimmett; afternoon shift
Chief Electrician Billy Hall; Roof Bolting Machine Operators Brandon Lusk and Joshua
Noe; Outby man Jonah Rose. The afternoon shift Mine Foreman was Fred Horton. In
this capacity, Horton was designated by the Mine Emergency Evacuation and
Firefighting Program of Instruction as the “Responsible Person” to take charge during
mine emergencies involving fires, explosions, or inundations. In all, there were 29
persons assigned to work underground on the afternoon shift.

4

 Production Crews
The 2 Section crew arrived at the 9 Headgate longwall belt drive at approximately 3:30
p.m., and traveled through the outby pair of equipment doors in that location. The
equipment doors were opened by Carl White, Belt Examiner, who was working at the
9 Headgate longwall belt drive area on day shift. The crew traveled under the longwall
belt between the belt drive and takeup storage unit, through the inby pair of equipment
doors, and continued on to 2 Section. Sworn statements indicate the crew did not see,
smell, or notice any unusual conditions as they passed through the equipment doors.
The afternoon shift production crew arrived on 2 Section at approximately 3:48 p.m.
and met with the day shift production crew. They discussed pending changes in the
work schedule at the mine while waiting for dust from rock dusting operations in the
face area to clear. The day shift production crew left 2 Section shortly thereafter. Billy
Mayhorn and Gary Baisden were assigned to build cribs in the 2 Section right return air
course outby the section. The remainder of the 2 Section crew proceeded to their work
stations in the face area. Production began and continued until the time of the accident.
The longwall crew arrived on the longwall section at approximately 3:55 p.m. and
relieved the day shift crew. The longwall belt had been shut off while cutter bits were
replaced on the shearer and longwall belt structure near the tail was removed.
Production resumed after the longwall belt was restarted at approximately 4:20 p.m.
Outby Belt Examiners
Cabell was assigned to examine belts and work at the 9 Headgate longwall belt drive
area. After entering the mine via the Box Cut portal, he walked along Nos. 4, 5, 6 Belts,
and along the No. 7 Belt, up to the longwall belt drive. On his way he shoveled some
coal accumulations. He stopped to answer a call on the mine phone from White who
was at the 9 Headgate longwall belt drive area. White told Cabell he was leaving the
longwall belt drive area because production on the longwall section had ceased for
routine maintenance of the face equipment. Since there would be no production for the
rest of his shift, White told Cabell he intended to walk to the longwall headgate area so
he could ride out with the section crew at the end of the shift. White informed Cabell of
the conditions he had encountered on the day shift in the longwall belt drive and
takeup storage unit area, including electrical problems with the winch motor, rubbing
of the longwall belt that would require realignment, and a haze he had observed. White
asked Cabell to come to the longwall belt drive area so that he could leave. White left
the drive area sometime after 3:30 p.m. and did not see any hazardous conditions as he
passed the belt takeup storage unit. The longwall belt was off at the time White passed
the takeup storage unit because belt structure was being removed to accommodate the
retreating longwall face.

5

 Interview statements revealed White had checked bearing temperatures in the longwall
belt drive and takeup storage unit area four times during his shift, but did not find any
temperatures exceeding the normal operating range. Belt bearing temperatures were
routinely checked using a temperature detecting device. Although White believed the
haze was an indication of a failing belt drive motor, he was unable to determine the
source. His last check of the bearing temperatures was made shortly before he left the
area.
Cabell arrived at the 9 Headgate longwall belt drive before 3:55 p.m. The longwall belt
was not operating when he arrived, but was restarted from the longwall section at
approximately 4:20 p.m. Cabell was working near the longwall belt discharge pulley,
which was approximately 155 feet outby the belt takeup storage unit, when he
observed, as White did, the air around the belt takeup storage unit was hazy and
dustier than normal. He walked to the takeup storage unit to determine the cause of
the haze. Upon arrival at the takeup storage unit, the air did not appear hazy at that
location. Looking back toward the No. 7 Belt, the area around the longwall belt
discharge pulley appeared dusty.
The drop-off carriage assembly did not properly disengage,
causing the conveyor belt to become misaligned.
Examining the takeup storage unit, Cabell discovered only one of the two trip latch
levers on a drop-off carriage assembly had disengaged and caused the drop-off carriage
assembly to become skewed across the center section beams. Appendix D contains
information concerning the longwall belt takeup storage unit and its operation. The
longwall belt was misaligned and rubbing against a pillow block bearing housing
within the pulley carriage assembly (PCA) of the takeup storage unit. Cabell observed
light smoke. Evidence of misalignment of the belt within the takeup storage unit is
shown in Figure 1.
Cabell disengaged the second trip latch lever on the skewed drop-off carriage assembly.
In a further attempt to correct the misalignment, he then adjusted the position of
another drop-off carriage assembly adjacent to the one he had just released. Neither
action corrected the misalignment of the belt. He went to the mine phone located near
the longwall belt drive, which was approximately 110 feet from the belt takeup storage
unit, and called Horton. Cabell explained to Horton that he needed chain ratchets to
align the longwall belt.

6

 Figure 1. Evidence of belt misalignment.

The Fire
Cabell returned to the belt takeup storage unit and noticed the intensity of the smoke in
the air was increasing. Cabell stopped the longwall belt at approximately 5:05 p.m. to
avoid damaging the belt. He went back to the phone near the drive and called Horton
again to see when help would arrive.
When Horton did not immediately answer, Gary Brown, Dispatcher/AMS Operator,
answered the phone. Horton, who was at the North West Mains No. 1 “4-Way,” joined
the conversation. While on the phone, Cabell looked toward the belt takeup storage
unit and observed smoke and glowing embers under the left side of the belt where the
belt had been rubbing. Cabell noticed the intensity of the smoke was increasing, and
told Horton a fire existed at the belt takeup storage unit. Horton told Cabell that
Callaway was on his way into the area, and to keep him there to assist.
When the first CO alarm was indicated at 5:14 p.m., the AMS
operator did not notify the appropriate personnel.
AMS CO Sensor 82 indicated alert and alarm levels of CO at approximately 5:14 p.m.,
during the phone conversation between Cabell and Horton. Brown went to the AMS
computer and acknowledged the alarm. Brown did not notify either person of the
alarm signal because Cabell was already at the scene and had reported seeing smoke to
Horton. Under § 75.1501, Horton, in the capacity of Mine Foreman on the afternoon
shift, had been designated by the mine operator as a responsible person to take charge
during a mine emergency such as a fire. At 5:16 p.m., CO Sensor 81 also indicated alert
and alarm levels of CO.
7

 The phone conversation between Cabell and Horton was ongoing when Callaway and
Rose arrived at the longwall drive equipment doors. Callaway and Rose both observed
smoke as they traveled through the doors and entered the area. After exiting the
mantrip, Rose observed light smoke traveling toward the No. 7 Belt. Then Rose saw
flames along the left side of the takeup storage unit, and observed the coal rib was also
burning. Rose did not know if Cabell could see the flames from his location.
Firehose couplings were not compatible with fire valve outlets
and there was no water in the line.
Cabell obtained a fire extinguisher from Callaway’s mantrip and discharged it, along
with another nearby extinguisher, at the fire. As soon as he had depleted the
extinguishers the flames returned. Rose went to retrieve additional fire extinguishers.
Cabell attempted to connect a firehose, which was lying on the ground alongside the
belt takeup storage unit, to a firehose outlet located within 50 feet of the fire, between
the fire and the longwall belt drive. He was unable to make the connection because the
threads of the firehose coupling and the threads of the firehose outlet were not
compatible. When he opened the firehose outlet valve, in an attempt to direct at least
some water onto the fire, he found there was no water in the line. Cabell then sent
Callaway to find where the water supply had been shut off.
As Rose traveled along the No. 7 Belt, he observed smoke traveling from the fire area
toward the No. 7 Belt drive. Rose returned with another fire extinguisher, which was
immediately discharged at the fire. The dry chemical from the three extinguishers did
not extinguish the fire. Meanwhile, Callaway had reached the shut-off valve in the
waterline that delivered water inby along the No. 7 Belt toward the longwall drive area,
and found it partially closed. This valve was located near the No. 7 Belt discharge
pulley, approximately 1,200 feet from the fire area. He heard water flow through the
waterline as he fully opened the shut-off valve. He then opened a nearby firehose
outlet that was downstream of the shut-off valve and confirmed water was available at
that point in the waterline. Callaway then returned to the fire area. No further
attempts were made to apply water onto the fire because personnel had to evacuate the
fire area due to the growing intensity of the smoke.
The Order to Evacuate
Cabell recognized smoke was traveling toward 2 Section. He called outside and
instructed Brown to call 2 Section and initiate an evacuation. After calling 2 Section and
getting no response, Brown activated the signal light on the section pager phone. Still
receiving no response, he then used the AMS computer to remotely stop the NEM No. 1
Belt. Sequence switches in the belt system stopped the NEM No. 2 and No. 3 Belts at
5:39 p.m. This belt stoppage was automatically recorded on the AMS event log.
8

 Evacuation of the miners on 2 Section was not initiated until
approximately 28 minutes after the first CO alarm signal.
Minutes after the belt was stopped, Plumley called Brown from 2 Section to find out
why the belt had stopped. Brown informed Plumley of the fire and the need to
evacuate. Horton joined the conversation on the pager phone and reinforced to
Plumley the order to evacuate. This was the first time 2 Section personnel were notified
of the fire and the need to evacuate. The order to evacuate the miners on 2 Section was
not given until approximately 28 minutes after the first CO alarm signals from the AMS
occurred and were acknowledged by Brown.
When Horton and Hall arrived at the 9 Headgate longwall belt drive area, Horton
instructed Callaway to account for miners as they arrived from 2 Section. Horton
traveled through the equipment doors and attempted to evaluate the fire but was
unable to approach it due to the dense smoke. Horton and Callaway instructed Rose to
go to the intake outby the equipment doors to watch for the 2 Section miners in case
they were evacuating via the roadway. Rose went to the equipment doors and stayed
there until the area became engulfed in dense smoke. The primary escapeway in the
intake air course outby the equipment doors had also become contaminated with
smoke. Rose donned his SCSR and followed the contour of the rib out of the smoke.
Evacuation of 2 Section
After Brown and Horton told Plumley to evacuate 2 Section, Plumley sent personnel to
bring the rest of the crew to where the mantrip was parked. Shull was standing with
Plumley at the mine phone and overheard Plumley discussing the fire and the need to
evacuate. Crouse and Elmer Mayhorn were bolting in the No. 1 Entry when Kinser told
them about the fire. Hunt went to the No. 2 Entry where Hensley was backing the
continuous mining machine out of the No. 1 Entry and told him about the need to
evacuate.
Hunt then went to notify Bragg and Hatfield, who were bolting roof in the No. 4 Entry.
Vanover was near one of the continuous mining machines when he heard Plumley yell,
telling them about the fire and the need to get out. As Vanover walked toward the
mantrip, he heard the roof bolting machine still operating in the face of No. 4 Entry. He
also told Bragg and Hatfield about the evacuation order.
The locations of all personnel doors along escapeways were not
clearly marked.
Before boarding the mantrip, Plumley told the miners if they were unable to travel all
the way out using the roadway, they would move into the adjacent NEM belt entry.
9

 This belt entry was the alternate escapeway for 2 Section. Plumley instructed them to
use a personnel door located along the roadway, one break outby the crosscut where
several cribs had been installed on both sides of the roadway. The personnel door had
been recently installed to facilitate examination of a seal in NEM, but its location was
not marked. Interview statements indicated all miners on 2 Section were not familiar
with the location of the personnel door. As the crew was boarding the mantrip,
Hensley offered to get some rock dust to use for firefighting, but Plumley declined.
After the 2 Section crew boarded the diesel mantrip, Hensley drove to the area just
outby the section where Billy Mayhorn and Gary Baisden were loading crib blocks to be
used to build cribs onto a scoop. While working outby the 2 Section, Billy Mayhorn
thought he smelled smoke prior to the mantrip arriving to pick them up. He mentioned
it to Gary Baisden, who did not smell the smoke. They continued to work until the
2 Section mantrip stopped near them.
When the mantrip arrived at their work location, Hensley shut off the mantrip. He told
Baisden and Mayhorn there was a fire and they were going to evacuate. As they
prepared to board the mantrip, Plumley again gave instructions regarding the route
they would take out of the mine. Plumley was standing on the side of the mantrip
beside the compartment where Bragg was seated. Billy Mayhorn was standing on the
opposite side of the mantrip from Plumley, next to the compartment where Hatfield
was seated. Billy Mayhorn and Hatfield discussed the evacuation plan.
After boarding the mantrip, the entire 2 Section crew continued their evacuation,
traveling out the No. 5 Entry of NEM. The locations where the miners were seated in
the mantrip are shown in Figure 2.

5

6

7

11
10

14
13

9
2

3

4

1.
2.
3.
4.
5.
6.
7.

12
8

1

Steven Hensley
Elmer Mayhorn
Billy Mayhorn
Ellery Hatfield
Michael Shull
Don Bragg
Joseph Hunt

8.
9.
10.
11.
12.
13.
14.

Thomas Vanover
Unoccupied
Randall Crouse
Patrick Kinser
Unoccupied
Michael Plumley
Gary Baisden

Figure 2. Seating arrangement of miners on 2 Section diesel mantrip

10

 As the miners resumed their evacuation, at least some of them did not fully recognize
the seriousness of the situation. At least one miner believed they would go to assist in
extinguishing a small fire and then return to work on 2 Section.
Plumley instructed the miners in the rear compartment of the mantrip that, if they were
unable to continue traveling out the roadway, they would move into the adjacent NEM
belt entry. After traveling approximately 1,800 feet to a location between 10 Headgate
and 9 Tailgate, some of the crew on the mantrip smelled smoke. The crew continued
traveling in the mantrip for approximately 400 feet before they encountered light
smoke. Some miners covered their noses and mouths with their shirts to filter out the
smoke.
Following the roadway, the mantrip turned right and traveled through a crosscut into
the adjacent intake entry and encountered dense, black smoke that prevented further
travel by mantrip. Hensley was unable to see and was forced to stop the mantrip. As
the crew exited the mantrip, Plumley again reminded them to go to the personnel door
outby the heavily cribbed crosscut. Some of the 2 Section miners indicated they moved
a few steps from the mantrip, in an outby direction, before donning their SCSRs. Others
indicated they were immediately next to the mantrip when they donned their SCSRs.
Some miners reported visibility was so poor they could not see more than one foot.
Others estimated that visibility was 10 to 12 feet when the miners first exited the
mantrip. The smoke at the mine floor was less dense, and miners knelt to begin the
SCSR donning process. Several miners lost their protective goggles when the SCSRs
were opened.
MSHA investigators identified the locations where miners first paused to don their
SCSRs. Appendices E and F show where SCSR top covers, bottom covers, and goggles
were found. The SCSR top and bottom covers are removed and discarded as part of the
donning process. The person to whom a specific SCSR was assigned was determined
using the unique identifying numbers on the SCSR components found during the
investigation and the company’s records of the persons to whom those SCSRs were
assigned. Physical evidence mapped during the investigation revealed the locations
where miners donned their SCSRs were different from the miners’ recollection. This
evidence revealed the miners had traveled from 100 to 225 feet in smoke before donning
their SCSRs. Seven miners donned their SCSRs in a group approximately 100 feet outby
the mantrip. Four miners, including Hatfield, donned their SCSRs in a group
approximately 170 feet outby the mantrip. The SCSR case parts for the SCSR assigned
to Bragg were found approximately 220 feet outby the mantrip.
Mike Shull had been seated next to Bragg on the mantrip, and as they exited Shull told
Bragg to put on his SCSR. This was the last contact anyone had with Bragg. Some of
the 2 Section crew members believed Bragg exited the mantrip immediately and
traveled in an outby direction. In the dense smoke, it is likely other crew members
11

 could not see that Bragg had stopped nearly two crosscuts outby the mantrip to don his
SCSR. The top and bottom covers of Bragg’s SCSR were located near Survey Station
(SS) 3228 in the area where cribs were installed. These cribs were the landmark
identified by Plumley for finding the personnel door to the NEM belt entry. Bragg was
found in a crosscut, near SS 3317, approximately 7 crosscuts outby the spot where he
donned his SCSR.
In the group of miners with Hatfield were Billy Mayhorn, Elmer Mayhorn, and
Hensley. Four pairs of goggles were found along with SCSR covers. One miner had
problems taking his SCSR out of the carrying pouch. He also lost his goggles and had
difficulty finding the lanyard to activate the SCSR. One miner was heard saying his
SCSR was not working, and another miner told him to blow into the unit to start the
oxygen production.
Billy Mayhorn, who was immediately next to Hatfield while donning his SCSR,
assumed Hatfield had donned his rescuer. Hatfield left the group before Mayhorn
completed donning his SCSR. It is not known how Hatfield became separated from the
group. Hatfield’s lunch bucket was found between SS 3308 and SS 3256. Along with
the lunch bucket were a hammer and a shirt with the name “Don” imprinted on the
front. Hatfield was found in a crosscut that was between SS 3267 and SS 3333, one
crosscut inby the 9 Headgate longwall belt drive, 11 ½ crosscuts outby the area where
he donned his SCSR.
The group of seven miners paused near SS 3537, one crosscut outby the mantrip, to don
their SCSRs. This group included Baisden, Hunt, Crouse, Vanover, Shull, Plumley and
Kinser. Three pairs of goggles were found in the area where the SCSR top and bottom
covers were located. One miner stated he had problems locating the activation lanyard.
He grabbed the cord and pulled it using channel locks. Another miner experienced
nausea during the donning process.
As they donned their SCSRs, miners began to move outby. Shull came face-to-face with
Baisden, who was new to the crew. He turned Baisden around and pushed him in the
direction of the door. En route to the personnel door, Shull encountered Elmer
Mayhorn, who was searching for his goggles on the mine floor. Shull directed Mayhorn
into line and the miners held on to one another as they navigated the entry toward the
personnel door. The men used the coal rib to guide themselves outby past the crosscut
where the cribs had been installed.
Kinser was first in the line of men following the rib. He found the door and opened it,
and entered the NEM belt entry. The air in the belt entry was clear of smoke. Nine
other miners followed Kinser through the door. When Billy Mayhorn entered the belt,
he looked for Hatfield, and discovered he was missing. At that time, the men
discovered that Bragg was missing as well.

12

 Plumley, Hunt and Billy Mayhorn re-entered the intake entry for a short time and called
out to the two missing miners but got no response. Smoke was dense, and there were
no responses to their calls. They returned to the NEM belt entry and resumed
evacuation with the other seven miners. As the miners traveled outby in the NEM belt
entry, they observed smoke leaking through the stoppings separating the belt entry
from the intake. The miners from 2 Section traveled approximately 1,900 feet in the
NEM belt entry to a location outby the 9 Headgate longwall belt drive before reentering the primary escapeway in the intake. The crew was met by Callaway, who had
been assigned to account for the miners as they arrived.
It is not known why Bragg and Hatfield did not escape via the alternate escapeway. It
is possible they could not find the personnel door in the smoke. Another possibility is
the two miners intended to remain in the NEM intake air course. This was the route
with which they were most familiar due to their day to day travel to and from 2 Section
and their escapeway drill training.
Longwall Section Activities During the Fire
Soon after Cabell stopped the 9 Headgate longwall belt, at approximately 5:05 p.m.,
Headgate Operator Richardson called the dispatcher from the longwall headgate to
determine the cause of the stoppage. Cabell interrupted his call and told Richardson
that there was smoke at the 9 Headgate longwall belt drive, and he had stopped the
belt. Cabell indicated he would have the belt operating again soon. The longwall crew
never received notification of the AMS alarm signals, nor were they withdrawn from
the section at the time of the alarm signals. Richardson called the miners working on
the longwall face and told them about the smoke. At that time, Richardson did not
believe the situation was serious. Richardson continued to listen on the mine phone
and learned that fire extinguishers had been used in an attempt to extinguish the
flames, but the fire could not be extinguished. Richardson then called the miners on the
longwall face and told them the fire could not be put out.
Richardson again returned to the mine phone. He overheard the dispatcher being
instructed to evacuate 2 Section crew, and to inform the longwall crew to come off the
face and go to the intake if they encountered smoke. Richardson called miners on the
face and told them to come to the headgate.
At approximately 5:50 p.m., Richardson attempted to use the mine phone to call out his
regularly scheduled production report, and discovered the phone was not working.
Runyon and Adkins walked toward the 9 Headgate longwall belt drive to see what the
situation was at the drive area. Within ten minutes, the longwall section lost electrical
power and the remainder of the crew decided to leave the section. As the longwall
crew walked out the longwall intake entry, they met Horton at the No. 2 Cut-Through.

13

 Initial Rescue and Firefighting Attempts
After the section crews were assembled outby the fire, several persons traveled to the
longwall face to obtain rolls of curtain and additional SCSRs. These additional rescuers
were stored on the longwall section in compliance with the mine operator’s tailgate
blockage plan. The plan was implemented when the longwall tailgate entry became
blocked. Some of the miners were instructed to install check curtains in all four
headgate entries in an attempt to reduce the air ventilating the fire. At this time there
was no sign of smoke on the longwall face.
Mine management officials who were away from mine property were contacted and
began to report to the mine. A pager message was sent to Lawrence Lester at 6:21 p.m.,
and mine rescue teams were also contacted. Charles Conn, team captain for the East
Kentucky Massey team, received a call at 7:05 p.m. to mobilize his team.
Five management officials, Edward Ellis, Assistant Longwall Coordinator, Rodney
Morrison, Assistant Superintendent and Longwall Manager, Dustin Dotson, Mine
Foreman, Terry Shadd, Box Superintendent/002 Section, and Robert Massey, Longwall
Chief Electrician, who were on mine property when the fire was reported, entered the
mine together in a single mantrip at approximately 6:20 p.m. Lawrence Lester arrived
at the mine and traveled underground at approximately 6:48 p.m.
Shortly thereafter, Gary Goff, Dwayne Francisco, and J. Christopher Adkins, Chief
Operating Officer for Massey Energy Company, Inc., arrived at the mine and traveled to
the fire area. As they neared 3 West Mains, the men encountered Bryson Ellis and Lusk,
who were tramming a Mobile Roof Support (MRS) into 3 West Mains. Morrison
informed Bryson Ellis and Lusk of the fire in the longwall belt takeup storage unit. As
the five men continued toward the fire, Bryson Ellis and Lusk continued with their
assigned duties. Even though mine management officials knew the fire was not
controllable, they did not evacuate miners who were not needed to fight the fire.
Morrison and Ellis got off their mantrip at 4 Right, went into 4 Right, and opened sets of
equipment doors near the back of 9 Tailgate in an attempt to short-circuit air away from
the fire area. Smoke was visible in the 9 Tailgate area at that time. After waiting 15 to
20 minutes to see if anyone was evacuating in that direction, they returned to North
West Mains. Morrison called Horton, who told him the fire was bad and that two
miners were missing.
The ventilation change at the back of 9 Tailgate was made without knowledge of the
overall effects to the mine ventilation system and without monitoring or evaluating the
changes. Following the ventilation change at the back of 9 Tailgate, miners installing
the check curtain in the 9 Headgate belt entry observed smoke migrating toward them
from the fire. As the smoke increased, Horton directed the miners installing the check

14

 curtains to evacuate to the surface. The crew members walked back to the mantrip
through the number two cut-through and rode out of the mine.
While the miners were installing the check curtain in the longwall belt entry, they
encountered excessive water flowing toward them from the fire area. Believing the fire
had breached the firefighting water supply line in the fire area, Massey directed
Callaway to de-energize the NEM water supply line pump. Massey also directed
Callaway not to de-energize the longwall section water supply line pump so that water
would still be available if needed to fight the fire. However, this would not have
affected firefighting capability because the longwall section water supply line was not
connected to the 2-inch waterline installed along the longwall belt.
Ed Ellis and Morrison obtained a diesel mantrip from Lusk and Bryson Ellis, who were
in 3 West Mains. Morrison told Lusk and Bryson Ellis to leave the mine because of the
fire. Lusk and Bryson Ellis proceeded to walk out of the mine. Ed Ellis and Morrison
then traveled toward the NEM. At the 4-Way intersection, Ed Ellis and Morrison
passed several miners, including the production crews, who were evacuating the mine.
At the No. 2 Cut Through, Ed Ellis and Dotson installed a check curtain over the first set
of longwall roadway equipment doors located near SS 2495 and across the 9 Headgate
intake air course.
Ed Ellis, Goff and Morrison carried firehose down the NEM belt entry and connected
the fire hose to a fire outlet. However, water was not available because the supply line
water pumps had been de-energized. Smoke was observed where these miners were
working in the NEM belt entry.
Vicki Mullins, an MSHA Mine Safety and Health Specialist assigned to the Logan, WV,
field office received a phone call from Sharon Cook, an MSHA employee from the
Madison field office at 7:50 p.m. Cook had learned that a fire had occurred at the
Aracoma Alma Mine #1 from an employee of the West Virginia Office of Miners’
Health, Safety and Training (WVMHS&T). Mullins called other Logan Field Office
personnel, Tim Justice and Minness Justice, and then traveled to the mine.
Mullins arrived at the mine at approximately 8:15 p.m. and was briefed by Frank Foster,
Safety Coordinator for Massey Coal Services. Foster informed Mullins that the first
attempts to notify MSHA Logan Field Office personnel of the fire were unsuccessful. At
7:55 p.m., Eddie Lester notified Richard Kline, Assistant District Manager for MSHA
Coal Mine Safety and Health District 4 at his residence. Although § 50.10 and MSHA’s
Internet Website provided a toll free number for immediate notification purposes, this
was the first time the mine operator notified MSHA of the mine fire.
Kline initiated the emergency response and then called District Manager Jesse Cole.
Additional MSHA personnel were dispatched to the mine. WVMHS&T personnel had
been notified of the fire by the mine operator at 7:33 p.m.
15

 At 8:40 p.m. Mullins issued a 103(k) order to Foster. The order was issued to assure the
safety of all persons at the mine during the rescue and recovery operation. The order
required the mine operator to obtain approval from MSHA of any plan to recover any
person in the mine, or to recover the coal mine, or to return the affected area of the mine
to normal. Twelve management officials remained underground after all other miners,
with the exception of the two victims, had been safely evacuated. These officials
included J. Christopher Adkins, Dewayne Francisco, and Gary Goff. The other officials
remaining underground were all officials of Aracoma Coal Company, Inc, and included
Dotson, Edward Ellis, Hall, Horton, Lawrence Lester, Massey, Morrison, Runyon, and
Shadd. While management personnel continued initial rescue and firefighting
activities, WVMHS&T and other MSHA enforcement personnel began to arrive at the
mine.
Mullins had a discussion with Eddie Lester regarding the twelve miners who were still
underground. Mullins explained that conditions and activities underground required
the attention of trained mine rescue personnel and ordered all remaining personnel to
be removed from the underground areas of the mine, as required by the 103(k) order.
At approximately 9:30 p.m., Lester contacted Billy Hall and ordered the evacuation of
the remaining personnel. All remaining personnel had been evacuated from the mine
by 10:30 p.m.
Mullins received statements from the miners from 2 Section in the Box Cut after they
exited the mine. At that time she learned of the borehole near the location where the
2 Section miners had transferred from the roadway into the alternate escapeway.
Mullins believed the borehole might provide valuable information about the mine
atmosphere because it was located inby the fire area. Mullins sent David Trent, MSHA
Coal Mine Inspector, to monitor mine gases at the borehole. Trent was accompanied by
John McNeely, Airway Walker, and Jeff Perry, Belt Coordinator.
A timeline, shown in Appendix G, was developed to describe the events and
circumstances surrounding the accident. The timeline was developed using interview
statements, MSHA investigation findings, the AMS event log, the dispatcher log book,
production notes and records, and the computer printout of paging reports sent out by
the dispatcher.
MINE RESCUE AND RECOVERY OPERATIONS
A total of 26 teams were contacted to assist in the rescue and recovery operations,
including teams from WVMHS&T and MSHA. Twenty-four of those teams directly
participated in rescue and recovery activities; one team responded to the mine site, but
did not participate in rescue or recovery activities; and one team was placed on
standby, but did not travel to the mine. A list of teams and team members is included
in Appendix H. Teams responding to the emergency also included the Southern West
Virginia and Mountaineer teams, which had been designated by the mine operator, as
16

 required by 30 CFR Part 49, to provide coverage for rescue and recovery availability for
mine emergencies. The mine operator began contacting mine rescue teams at
approximately 7:00 p.m. Team members began to arrive at the mine between 8:30 p.m.
and 9:30 p.m. on the evening of January 19. The first two complete teams, Southern
West Virginia Team and the Massey Energy East Kentucky Team had been assembled
onsite by 10:30 p.m.
At approximately 11:00 p.m., the first two teams were given a briefing concerning the
fire at the 9 Headgate longwall belt drive. The teams were provided with mine maps
and were given instructions regarding advancing into the 4 Right entries to search for
the two missing miners and to determine the direction of the airflow. This systematic
exploration was to be conducted prior to teams traveling inby to the fire area.
Meanwhile, miners had been stationed on the surface to monitor gas concentrations in
airflow exhausting from the mine. The initial evaluation of CO concentrations at the
Ethel fan had been reported to be 865 ppm at approximately 10:00 p.m. The CO levels
in air exhausting from the mine through a borehole, located inby the fire in NEM
between SS 3226 and SS 3233 were 1,300 ppm at about 11:28 p.m. on January 19. The
CO concentration at this borehole reached 1,700 ppm during the initial exploration
stages.
Mine rescue teams first entered the mine at approximately 11:30 p.m. on the night of
January 19. The teams were instructed to establish the first Fresh Air Base (FAB) at SS
1600 in the No. 2 Entry of the North West Mains. This FAB was established and in
communication with the surface command center by approximately 12:01 a.m. on
January 20. The Southern West Virginia and Massey Energy East Kentucky teams then
advanced from FAB 1 to explore the 4 Right entries. FABs 2 through 5 were established
during this sequence of exploration. The command center instructed Foster, who was
traveling with the Southern West Virginia Team, to travel inby to SS 3363, which was
the Furthest Point of Advance (FPA) in 4 Right.
Light to heavy smoke was encountered at the FPA. Concentrations of CO as high as 500
ppm were detected at various locations in the 4 Right entries. It was later determined
that some handheld detectors used by team members to measure the CO concentrations
had a maximum range of 500 ppm. There were no ventilation changes made by the
teams in the 4 Right entries. The teams found no indication that Bragg and Hatfield had
traveled the 4 Right entries attempting to escape from the mine.
The command center instructed the teams to retreat to the North West Mains, and await
the arrival of two additional teams. The four teams advanced to the No. 6 Belt drive to
establish FAB 6 in the North West Mains. Entries from FAB 6 to the No. 1 Cut-Through
were examined and found to be clear of contaminants and smoke. The command center
directed the teams to advance to SS 2492 and establish FAB 7. Teams were instructed to
advance inby FAB 7 and examine the opening into the No. 2 cut-through.
17

 According to command center notes, Foster traveled from the FAB 7 through and into
the No. 2 Cut-Through to SS 3300 in the 9 Headgate entries and encountered thick
smoke, but did not observe a fire. Gas concentrations measured 500 ppm carbon
monoxide, 20.4 percent oxygen, and 0.0 percent methane. At 3:15 a.m., prior to teams
advancing toward the fire area, Robert Ellis was sent to the No. 6 Belt drive area to cut
electrical power inby that point. Permission was granted to re-start the de-watering
pumps near 5 Tailgate.
From FAB 7, four teams advanced to the mouth of NEM and established FAB 8 at SS
2844. The command center instructed the four teams to organize into two separate
groups, two teams per group. The command center gave each group separate goals.
One group was assigned to fight the fire in the 9 Headgate longwall belt drive area. The
other group was directed to explore from the fire area to the location of the abandoned
2 Section crew’s mantrip to search for the two missing miners.
Firefighting and exploration activities continued simultaneously. Two teams advanced
around the gas well barrier and approached the two sets of equipment doors outby the
9 Headgate longwall belt drive. They passed through one set of equipment doors and
observed smoke and flames. The teams retreated to discuss the lack of water and
availability of firehose outlets in the immediate fire area. Teams assigned to extinguish
the fire requested additional water pressure for the firehoses.
At 5:30 a.m., the teams assigned to explore toward 2 Section unexpectedly found
energized electrical circuits around the NEM No. 1 Belt drive. These circuits were to
have been deenergized at 3:15 a.m. This was reported to the command center and
Robert Ellis was again sent to the No. 6 Belt drive area to de-energize electrical power to
the NEM belts and 2 Section. Ellis and the Pinnacle team then traveled to the No. 7 Belt
drive to disconnect the electrical circuit that leads to the longwall section and 10
Headgate. They then restored electrical power to the freshwater pumps near 5 Tailgate.
The water supply could not be re-established until the air was purged from the
waterlines.
The teams advanced and established FAB 9 at SS 3202 in the NEM belt entry. At 5:50
a.m. conditions were reportedly clear at SS 3210 in the NEM intake air course. FAB 10
was established nearby at SS 3234, located in NEM intake air course just outby the
longwall belt entry, as a staging area for firefighting activities.
The NEM intake entries inby FAB 10 was unsafe for travel due to the intense heat and
smoke. Teams searching for the missing miners continued to travel toward 2 Section in
the NEM No. 1 Belt entry, which was the only entry inby 9 Headgate where a fresh air
base could be safely established at that time. FAB 11 was established at SS 3230 in the 9
Tailgate area of the NEM belt entry, adjacent to the same personnel door the miners
from 2 Section had used during their escape. At approximately 7:12 a.m., exploration of
the adjacent intake entries was again attempted from FAB 11. The heat in the NEM
18

 intake entry adjacent to the belt entry was extreme and visibility was 12 inches or less.
A call was made from underground at 7:56 a.m. informing the command center that
SCSR top and bottom covers had been found. A call at 7:59 a.m. indicated the 2 Section
mantrip had been located. Later, it was learned that a team had passed within 10 feet of
the mantrip, but were unable to see it due to the dense smoke.
As the search continued for the missing miners, personnel in the command center
became increasingly concerned for the safety of the teams because of prolonged
exposure to the extreme heat and poor visibility inby the fire area. It had been decided
to withdraw the teams if the missing miners were not found in the immediate area of
the mantrip. At 8:35 a.m., the teams reported to the command center they had found no
evidence of the missing miners and the teams were withdrawn to FAB 9. To safely
continue the search, the fire needed to be controlled sufficiently to reduce the rescue
teams’ exposure to smoke and extreme heat. At this time, water was not yet available to
fight the fire.
By 10:55 a.m. on January 20, water was being directed toward the fire area. After teams
began applying water and foam to the fire, they called to the command center to
request additional water pressure. Shortly thereafter, it was reported that a waterline
had ruptured and the water was shut off at 11:09 a.m. Water flow was re-established, at
a lower pressure, by 11:35 a.m. Later, water pressure was slightly increased following
an additional request from the teams fighting the fire.
As firefighting operations continued, the Consol Energy Buchanan #1 Team and
Federal No. 2 Team checked the phone communications at the previously established
FAB 10 and FAB 11. Exploration continued inby to SS 3548 in the NEM belt entry. The
Federal No. 2 Team continued to advance and explore entries and crosscuts inby in the
direction of 2 Section.
Johnny Robertson, Superintendent of Independence Coal Company’s Justice Mine,
another Massey Energy, Inc. subsidiary, had been assigned to the Massey Energy East
Kentucky team. He helped coordinate underground firefighting efforts for the mine
operator. At 12:40 p.m. on January 20, Robertson reported to the command center that
temperatures surrounding the fire area had decreased, and he believed the major
portion of the fire had been put out. He indicated the largest fire they encountered was
inby the No.7 Belt Conveyor tail pulley.
During the fire and firefighting activities, the roof in the fire area was exposed to
extreme heating and water. The resulting temperature changes created unsafe roof
conditions that hampered firefighting efforts. Metal roof jacks were installed later as
supplemental roof supports for the protection of the team members fighting or
monitoring the fire area.

19

 The NEM intake entries between the fire area and the mantrip were still too hot for
exploration and search for the missing miners. Additional exploration was conducted
in the NEM belt entry inby FAB 11. FABs 12 through 14 were subsequently established
in the belt entry during exploration in NEM. By 2:00 p.m. on January 20, the
exploration of 2 Section by mine rescue teams had begun.
Firefighting efforts had initially reduced the heat and heavy smoke produced by the
fire. However, light to moderate smoke, often mixed with steam, continued to hamper
search efforts. In response to these conditions, rescue crews spent substantial time
installing temporary curtains at various locations to direct fresh air to ventilate areas
inby the fire. “Flare-ups” in the fire area continued to impede rescue efforts. For
example, at 5:58 p.m. on January 20, the command center received a report of “heavy
fire” at the longwall belt transfer point. Later, a large capacity, high-expansion foam
generator, requested earlier in the day, arrived and was placed into service
underground at 7:33 p.m. in an effort to control remaining fires and hot spots.
Firefighting efforts and ventilation changes continued.
By the morning of January 21, additional areas inby 9 Tailgate were able to be explored.
Teams were instructed by the command center to advance and establish FAB 15 to
facilitate exploration of 10 Headgate. FAB 15 was first located at SS 3695 in the 10
Headgate entries at 10:15 a.m. on January 21. The FAB was advanced as exploration in
the 10 Headgate entries continued. No evidence of the two missing miners was found
in 10 Headgate.
Firefighting efforts eventually reduced heat and smoke in the NEM intake entries
immediately inby the longwall belt sufficiently to enable exploration. These entries and
connecting crosscuts could not be explored previously due to the extreme heat and poor
visibility. By 1:32 p.m. on January 21, teams had been directed to explore the entries
and connecting crosscuts from the 9 Headgate longwall belt drive to 9 Tailgate.
On January 21, the two missing miners were found. At 2:40 p.m., the Southern
Coalfields Team found Don Bragg in the crosscut between SS 3321 and SS 3317 in the
NEM. He was tentatively identified by the brass identification tag secured to his
miner’s belt. At 3:20 p.m., the Consol of Kentucky Team found Ellery Hatfield in the
crosscut adjacent to the roadway between SS 3267 and SS 3333 in NEM. He was
tentatively identified by the name on his hard hat. The two victims were found
approximately 575 apart. The location of the victims is shown in Appendix E. The two
victims were subsequently transported to the surface. Victim data sheets are contained
in Appendix I. Teams continued firefighting and monitoring activities. By January 24,
the fire had been extinguished and these activities ceased. Mine rescue team
exploration was completed early in the morning on January 26.

20

 INVESTIGATION OF THE ACCIDENT
The Administrator for Coal Mine Safety and Health (CMS&H) directed that an
investigation be conducted of the fatal mine fire accident that occurred on January 19.
Kenneth A. Murray, District Manager in CMS&H District 6, was assigned as the
accident investigation team leader. An investigation team of MSHA personnel was
selected from CMS&H Districts 2, 6, 8, and 10; CMS&H Headquarters; Technical
Support centers in Pittsburgh, PA, and Triadelphia, WV; and personnel from the Office
of the Solicitor, Department of Labor. Appendix J lists the persons who participated in
the investigation.
MSHA’s accident investigation team members met on January 26, to begin the
investigation by reviewing records and preliminary information obtained by MSHA
CMS&H District 4 personnel. In cooperation with the WVMHS&T, the onsite
investigation began on January 30. Interviews were jointly conducted by MSHA and
WVMHS&T investigation teams. The MSHA accident investigation team conducted a
total of 82 voluntary interviews with personnel who had relevant knowledge of the
circumstances associated with the accident. Miners, contractors, mine rescue personnel,
manufacturer representatives, MSHA personnel, WVMHS&T personnel, and local
authorities were interviewed. Numerous mine management officials declined to
participate in voluntary interviews. MSHA has no legal authority to require persons to
participate in accident investigation interviews.
MSHA investigators obtained and reviewed pertinent mine records; collected,
examined and/or tested physical evidence; examined and mapped underground areas
of the mine; and documented conditions and objects with digital photographs and
videos. Some mine records were not made available to the accident investigation team
by the mine operator, who claimed the records did not exist. After MSHA initiated
legal proceedings to obtain these records, all requested records were either provided to
MSHA or the mine operator formally declared the records did not exist. In addition,
data stored on the AMS computer regarding the AMS event log was found to have been
deleted. The AMS computer was taken into custody by MSHA on March 2, 2006.
A mine ventilation investigation was conducted in conjunction with the accident
investigation. The findings of the ventilation investigation were presented to the mine
operator and to CMS&H District 4 personnel.
DISCUSSION
This section contains a discussion of the pertinent, factual details or factors bearing on
the event. Information concerning the mining method, equipment, plans, and work
procedures believed to have an impact on or contributing to the accident is included.
Areas of concern related to contributory violations are identified.

21

 Training
The training plan for this mine was initially approved on December 7, 1999. On January
4, 2002, the approved training plan was revised to include, among other things, a
petition to allow air coursed through belt entries to be utilized for ventilation of
working places. On April 2, 2004, the final rule on the use of belt air to ventilate
working sections became effective. The result of this regulation was to supersede all
Petitions for Modification for using belt air.
This training plan revision also included the job classification “Dispatcher.” The
“Skills/Knowledge/Abilities” portion, in this revision, required the following skills for
the dispatcher: “Must have a working knowledge of the underground rail system and
be able to direct traffic on the underground rail system. Basic knowledge of computers,
good verbal communications skills, ability to recognize and report alarms to the
appropriate individuals.” The “Training” section of the plan revision required training
in mandatory MSHA standards, safe rail traffic direction, proper use of the CO
computer and Mine Wide Monitoring System. Meanings of alarms and notification
procedures, and CO Monitoring wavier were to be discussed in detail.
During the investigation, training records were reviewed for all underground, surface
miners, and independent contractors who worked the afternoon shift of January 19,
2006. This review was conducted from February 9 through March 28 jointly with Jerry
W. Vance, Mine Safety and Health Specialist (Training), District 3, Morgantown, West
Virginia, and the accident investigation team. The most recent annual refresher training
(part 48 training) for the afternoon shift 2 Section crew was provided on January 14, and
was properly recorded on MSHA forms 5000-23. Training record documentation
consisted of New Miner Training, Experienced Miner Training, Annual Refresher, Part
77, Part 75, and electrical training. There were seven violations and one order issued as
a result of this review relevant to the training plan and training records.
A 104(b) Order of Withdrawal was issued for failure to abate the citation regarding a
record for training of newly employed experienced miner initial training. The operator
had been given reasonable time to conduct the required newly employed miner
training, and complete the relevant records to evidence the training had been completed
for three individuals, and failed to do so.
An additional training related citation was issued on February 23, when information
obtained from witness interviews indicated the AMS operator’s training was
inadequate to respond to carbon monoxide sensor warnings, alarms, fire, or emergency
situations. As a result of this citation, all three dispatchers at the mine were trained
with two of the three dispatcher training sessions observed by MSHA personnel.
Documentation of this training was provided to MSHA by the mine operator before the
citation was terminated.

22

 The AMS operators were not adequately trained in their duties
and responsibilities related to mine emergency situations.
It was also determined during this investigation that the AMS operator on duty on
January 19, did not fully understand the requirements of § 75.352(a). The failure to
properly notify appropriate personnel that the CO system was in alarm status at the
longwall belt head drive, significantly impacted the evacuation time needed for miners
working on the No. 2 Section inby the fire to evacuate in a timely manner. A similar
lack of proper response was demonstrated by the dispatcher/AMS operator on duty on
December 23, 2005, when a fire occurred at the 9 Headgate longwall belt conveyor
takeup storage unit. The dispatcher/AMS operator notified a miner to investigate the
source of the alarms but did not notify appropriate personnel to initiate withdrawal of
miners from affected areas.
In these two fire events, the AMS operator on duty failed to promptly notify
appropriate personnel of alarm signals. This was supported by the fact that miners on
affected sections were not withdrawn to a safe location on these dates.
The electrician assigned by the mine operator to install and maintain the carbon
monoxide mine wide monitoring system was not adequately trained to perform these
tasks. Several deficiencies, such as inadequate calibration of sensors and improper
maintenance of the system (due in part to a lack of training) were found during the
investigation. The electrician, Jesse Jude, admitted that he had received no formal
training from anyone regarding the operation of the system, and relied solely on the
operating manual for the system and experience from occasionally working with a
former employee assigned to maintain the system. Further deficiencies in training
revealed during witness testimony that the miners working underground at this mine
were not trained in the requirements of the CO monitoring system as specified by
§ 75.350(b)(2).
Roof Control Plan
The approved roof control plan, dated September 16, 2005, was a full bolting plan
requiring the installation of one of the following approved roof bolt systems as primary
roof supports: fully grouted resin bolt, mechanical anchor/resin assisted tension bolts,
point anchor-tension rebar roof bolts, or conventional roof bolts. The plan required roof
bolts to be installed on centers no greater than 4 feet across the width of the entry, and
centers no greater than 5 feet along the length of the entry. The plan also permitted the
mining of coal pillars using full or partial pillar recovery, and specified the sequence for
second mining of the coal pillars. The methods for supporting the roof during second
mining were also specified.

23

 The roof control plan required the installation of permanent and supplemental roof
supports in the headgate and tailgate entries of a typical longwall section. Several types
of supplemental roof support and installation patterns were permitted by the plan. The
tailgate entry for Longwall Panel No. 9 was required to be supported with a minimum
of one row of timbers installed on five-foot centers in the entry, and one of the following
support systems to be installed in the opening of the connecting crosscuts to the tailgate
entry prior to longwall mining: four 8-foot cable roof bolts; two timbers; one wooden
crib; or one 50-ton Heintzmann roof jack. On January 19, 2006, a roof fall blocked the
tailgate entry such that safe egress from the longwall face through the tailgate entry was
not provided. Hazardous roof conditions existed in the tailgate entry for at least 14
shifts prior to the accident. As required in the approved roof control plan, the operator
had implemented the tailgate blockage plan which specified five additional safety
precautions. The tailgate blockage plan was to remain in effect until the travelway off
the tailgate side of the longwall had been re-established. Interview statements indicated
that difficult roof conditions in the tailgate entry of this longwall panel were common.
The approved roof control plan also required the tailgate entry for the adjacent longwall
panel to be supported 50 feet in advance of the retreating longwall face. Supplemental
roof supports were not installed in the tailgate entry for Longwall Panel No. 10 as
required. During the investigation, a roof fall was also observed in the adjacent
longwall tailgate entry at SS 2983.
Mine Emergency Evacuation and Firefighting Program of Instruction
The Mine Emergency Evacuation and Firefighting Program of Instruction (Program)
was approved on February 12, 2003. The program assigned duties and responsibilities
of mine personnel in the event of an emergency, including an underground fire and
emergency evacuation of miners.
The program identified Responsible Persons (who would take charge during mine
emergencies involving fires, explosions, or inundations) by job title and shift worked.
Changes to these assignments were to be posted on the mine bulletin board. The Mine
Foreman on duty was the Responsible Person each shift, except on Sundays when the
longwall section foreman was assigned this responsibility. Three other job titles were
identified in the program as other personnel responsible for facilitating the evacuation
from underground: section foremen, chief electrician and belt foreman.
Work locations and anticipated movements of underground miners were to be tracked
by the dispatcher and noted on a log. Dispatchers’ logs obtained by MSHA
investigators for the January 19 shifts indicated the work locations and anticipated
movements of all underground miners were not tracked. Miners were to be rapidly
notified of emergencies through communication systems located underground
including mine phones and the AMS. In the event of a failure of communication
systems during an emergency, the program specified “…all power will be pulled to
24

 alert sections.” For emergency evacuation, assembly locations were identified as the
last permanent stopping on the safest escapeway on sections, and the Box Cut
warehouse in the drift. Each section foreman was responsible for assembling and
accounting for their employees.
The program required that all miners in the same split of air were to be withdrawn
immediately to a safe location when the AMS generated an audible and visual alarm
signal. The safe location identified in the Program was at least one sensor outby the
sensor(s) activating the alarm signal, unless the cause was known not to be a hazard to
miners. Per § 75.352(c), if any sensor indicates an alarm, all personnel in affected areas
not assigned other duties under § 75.1502 must be withdrawn promptly to a safe
location identified in the program. During the fire on January 19, both 2 Section and the
9 Headgate longwall section were affected areas.
In summary, the mine operator failed to comply with the withdrawal requirements of
§ 75.352 and the referenced requirements in the Program of Instruction. The program
also specified the engineering department was to provide the Responsible Person with
up-to-date section prints and mine maps of the ventilation and escape routes. None of
the mine maps provided by the mine operator to MSHA investigators accurately
depicted ventilation and escape routes.
Self-Contained Self-Rescuers
Mine operators are required by § 75.1714 to make available to each miner who goes
underground, and to visitors authorized to enter the mine by the operator, an approved
self-rescue device or devices which is adequate to protect such person for one hour or
longer. This section also requires that miners be trained in the use and location of the
self rescue devices.
The CSE SR-100® Self-Contained Self Rescuer (SCSR) was supplied by the mine
operator to provide respiratory protection to miners in the event of an emergency. The
unit is designed to provide approximately 100 liters of oxygen for a rated duration of 60
minutes by converting potassium superoxide to breathable oxygen. The conversion is
accomplished by chemical reaction between the potassium superoxide and moisture in
exhaled air. Exhaled air is recycled through the unit and the isolated air supply is rebreathed to conserve the oxygen supply. To avoid a buildup of carbon dioxide within
the air circuit, it is removed from the exhaled air by way of a second chemical reaction
between the carbon dioxide and lithium hydroxide. SCSRs are not designed to be used
for mine rescue, firefighting, or underwater breathing.
Once a miner needs to use the SCSR, the unit is first removed from its carrying pouch.
Miners are trained to kneel on the ground and begin the donning process by removing
the security band to release the top and bottom covers of the unit. The covers are
discarded. The unit is then hung over the head, and the mouthpiece is placed in the
25

 mouth. The nose pads are placed on the nose to isolate the miner from the dangerous
atmosphere. At this point the miner pulls a lanyard to activate the unit, which releases
a starting volume of oxygen into the breathing circuit. The miner adjusts straps and
puts on protective goggles and hardhat. The miner is then ready to evacuate.
If the breathing bag does not fill for any reason, such as failure of the compressed
oxygen cylinder or the oxygen vents from the unit, miners are trained to manually start
the SCSR. The miner can start the SCSR by exhaling into the unit three to six times to
begin the chemical reactions within the SCSR. Once the SCSR is donned and activated,
the mouthpiece and nose pads are not to be removed until the miner reaches a safe
atmosphere.
SCSR Training, Testing and Examination Requirements
SCSR training requirements are listed in § 48.8(a)(8). These annual training
requirements include the demonstration, care, use and maintenance of the SCSR unit as
well as hands on donning procedures. Testing requirements for SCSRs are included in
§ 75.1714-3. These testing requirements include a visual inspection for damage to the
exterior case and the integrity of the seal. Additional testing requirements are
contained in PIB No. P99-5, which was issued April 5, 1999. At intervals not to exceed
90 days, the operator is required to further examine each SCSR using an Acoustical
Solids Movement Detector (ASMD).
Required SCSR Training
Interviewed miners and mine records indicated SCSR training was completed for all
2 Section miners on January 14, 2006. The annual retraining program included SCSR
training. Training included donning a training unit in a small, dark room with audible
distractions to simulate donning under stressful conditions and poor visibility, such as
in a smoke-filled environment. Miners were required to complete the donning process
within 2 minutes, repeating the process if necessary. The described training exceeded
the SCSR annual refresher training requirements. Miners evacuating 2 Section
indicated the training was invaluable to escaping the mine. One miner stated donning
the SCSR during the fire was “…just like I was doing it by all my training.”

26

 Table 2. Information on SCSRs for afternoon shift 2 Section personnel

Miner

Don Bragg
Ellery Hatfield
Billy Mayhorn
Elmer Mayhorn
Michael Plumley
Steven Hensley
Patrick Kinser
Harold M Shull
Joseph Hunt
Thomas D Vanover
Randall Crouse
Gary Baisden

SCSR
Serial
Number
122596
107363
101826
104970
107521
100000
122599
114792
104946
102662
100069
109376

SCSR Mfg.
Date

Date Checked

12/05
09/04
01/04
06/04
10/04
10/03
12/05
04/05
06/04
02/04
10/03
10/04

01-03-06(New)
01-04-06
01-04-06
01-04-06
01-04-06
01-04-06
01-03-06(New)
01-04-06
03-30-05
01-04-06
01-04-06
01-04-06

Date SCSR
Training
Received
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06
01-14-06

The oldest SCSRs in use by 2 Section miners were assigned to Hensley and Crouse
(October 2003 manufacture date). All SCSRs used by 2 Section miners were well within
the expected life of the units. New units were assigned to Bragg and Kinser on January
3, 2006.
Required SCSR Examinations and Tests
Accident investigators reviewed the current “90 Day SCSR Examination Record Book”
maintained by the mine operator as required by § 75.1714-3(e). This book included
SCSR tests conducted for the end of 2004, all of 2005 and for tests conducted in 2006 up
to the time of the fire. The record was not completed as required. The book did not
always include the signature of the person making the tests, nor the date on which all
the tests were completed.
The majority of SCSRs were tested on the same dates. Testing dates were identified in
the record book, and included March 29, May 19, and September 6, 2005, and January 2,
3, and 4, 2006. The remaining tests of SCSRs were conducted on other dates when
newly-hired miners were issued SCSRs or defective units were replaced. The periods
between examinations of individual SCSRs exceeded 90 days in many cases. Most
SCSRs tested on May 19 were not tested again until 109 days later on September 6, 2005.
The next date most of these SCSRs were tested was 117 days later, on January 2, 2006.
At the time of the accident on January 19, 2006, approximately 128 SCSRs were
identified in the examination record book. Of these, only 57 had been examined within
the previous 90 day period. SCSR testing frequency did not meet the requirements of
27

 30 CFR. Units were also to be examined on a daily basis by miners to check the
moisture indicators and to check for damage to the case, straps, seal and heat shield.
Investigative Examination and Testing of Recovered SCSRs
All 2 Section crew members donned their SCSR during the evacuation on January 19.
The SCSRs for the two deceased miners and four of the surviving evacuees were
recovered. A seventh opened unit was recovered from the NEM belt entry. It could not
be determined which miner used this unit. Representatives of the mine operator did
not provide the remaining used SCSRs, reportedly because they were no longer in the
mine operator’s possession. An eighth SCSR, found on Cabell’s mining belt, was also
recovered.
The SCSRs that were recovered and supplied by the mine operator were sent to the
National Personal Protective Technology Laboratory (NPPTL) in Pittsburgh,
Pennsylvania, for examination and testing. The laboratory is operated by the National
Institute for Occupational Safety and Health (NIOSH). The units were visually
examined prior to dissecting each unit to determine any damage to the breathing bag
and other external components. After opening the chemical cartridge, the examiners
removed the starter bottle of oxygen and determined if the supply was properly
activated by pulling the lanyard in the donning process. Chemical beds were then
removed and examined to visually estimate the percent of the chemical used in
producing oxygen. The estimates were based on observations during previous
examinations of other used units, including color changes in the chemical bed.
Multiple samples of the chemical bed of individual SCSRs were placed in sealed
containers and retained for chemical analysis to more accurately determine the
remaining oxygen potential and portion of the unit used by each miner during escape.
Samples were analyzed by researchers at the CSE offices in Monroeville, Pennsylvania,
and at an independent laboratory, Alternative Testing Laboratories, Inc. (ATL). A
comprehensive report on the SCSR examination and testing is available from The
National Institute for Occupational Safety and Health (NIOSH).
Laboratory tests indicated the SCSRs functioned properly.
The SCSR used by Hatfield was found in a pool of water, near him. An examination of
the SCSR revealed that exposure to water had fused the chemical bed, and no further
analysis was performed. It could not be determined what percentage of the chemical
was consumed by the use of the SCSR. Statements of interviewed miners indicated the
SCSRs used by them functioned properly. Laboratory examinations and tests indicated
the recovered SCSRs tested functioned properly during the evacuation. The portions of
the chemical consumed in the survivors’ units are included in Table 3 below. The

28

 variation in chemical consumption will depend upon the respiration rate of the person
wearing the unit as well as the length of time the individual units were worn.
Table 3. Results of laboratory tests on SCSRs

Miner

SCSR
Serial No.

Elmer Mayhorn
Patrick Kinser
Thomas Vanover
Randall Crouse
Don Bragg
Unknown
Ellery Hatfield
Bryan Cabell

104970
122599
102662
100069
122596
96103
107363
104948

Percent
Consumed
(Visual Estimate)
30 %
20 %
25 %
35 %
85 %
10 %
*
**

Percent
Consumed
(ATL Tests)
28 %
27 %
30 %
23 %
90 %
29 %
*
**

Percent
Consumed
(CSE Lab Tests)
31 %
18 %
23 %
24 %
85 %
18 %
*
**

* SCSR found submerged in water. Chemical bed was fused, preventing testing.
** SCSR damaged by excessive heat from the fire. SCSR was unable to be tested.
Mine Ventilation Plan
The ventilation plan in effect on January 19, 2006, had been approved on May 6, 2005,
and included the informational map pursuant to § 75.372. The approval letter indicated
there were no items included on the map to be approved under § 75.371. The mine map
was dated February 14, 2005. The map showed 9 Headgate was a development section
that extended from NEM for a distance of 8 crosscuts toward 4 Right. The 9 Tailgate
was shown as a development section that extended from 4 Right into the intersection of
NEM. A single seal isolated the old works of an adjacent abandoned mine that had
been intersected on this development section in the NEM. The entries in NEM between
9 Headgate and 9 Tailgate were not yet connected. The ventilation plan also included
addendums.
The ventilation plan addressed specific requirements for the ventilation of the longwall
section. A minimum air quantity of 45,000 cubic feet per minute (cfm) was required to
be directed to the longwall face. The minimum air velocities required on the longwall
face were 300 feet per minute (fpm) at Shield 17 and 200 fpm at Shield 160.
Typical face ventilation sketches were included in the plan for the development
sections. The sketches included in the ventilation plan indicated air that ventilated the
belt entry was not used to ventilate the development sections. A sketch titled “Typical
Four Entry Face Ventilation Sketch Split Ventilation” included in the ventilation plan
showed the faces of a four entry development section being ventilated with intake air.
The sketch indicated that air was then directed to a return entry on each side of the
29

 section. The direction of the air ventilating the belt entry was shown from the section
belt tailpiece outby. The sketch indicated air that ventilated the belt entry was not used
to ventilate the working section. A sketch titled “Face Ventilation Typical Advance –
Sweep Ventilation” included in the ventilation plan showed the faces of a seven entry
development section being ventilated with intake air and that air then being directed to
a return entry on the side of the section opposite the intake. The direction of the air
ventilating the belt entry was shown from the section belt tailpiece outby. The sketch
indicated air that ventilated the belt entry was not used to ventilate the working section.
No text was found in the ventilation plan that further described the ventilation scenario
for development sections.
The most recent addendum to the plan, approved on November 4, 2005, indicated
additions to the list of diesel-powered equipment used in the mine. No mine
ventilation system changes were submitted or approved in this addendum.
The most recent addendum regarding changes to the ventilation system was approved
on August 30, 2005. This revision was shown on a portion of the mine map, dated
August 11, 2005, which was submitted with the revision request. The revision included
a narrative description of the Longwall Bleeder Plan for Panel No. 9 that established the
means for evaluating the Panel No. 9 bleeder system. A sketch titled “Typical Longwall
Face Ventilation for Panel No. 9 Longwall System” was included in the revision. The
sketch showed three of the four 9 Headgate entries, including the belt entry, were
common. The fourth entry was designated as a separate intake air course. The sketch
showed the direction of air in the 9 Headgate longwall belt entry was toward the
longwall face. The sketch indicated air ventilating the longwall belt entry was to be
used to ventilate the longwall section. The mine map included in the addendum
approved on August 30, 2005, showed the same headgate airflow patterns and
established air courses as on the sketch.
Nothing in the ventilation plan indicated air that ventilated the 9 Headgate longwall
belt entry would be directed outby and not used to ventilate the 9 Headgate longwall
section. The approved ventilation plan revision that showed the bleeder system for the
mining of longwall Panel No. 9 stated “The attached maps identify all directions of
airflow, locations of proposed controls and the locations of all Evaluation and
Measuring Points.” The airflow direction shown on the map approved on August 30,
2005, in the NEM belt entry and the 10 Headgate belt entry was in an outby direction in
10 Headgate and through the NEM to the North West Mains. No other development
section in NEM was shown on the map. The airflow direction shown on the map
indicated air that ventilated the NEM belt and the 10 Headgate belt entry was not used
to ventilate the 10 Headgate section.
The July 13, 2005, revision contained two mine maps, both dated June 20, 2005. One
map showed the portion of the mine surrounding the recovery face of 8 Headgate
longwall section, including the inby end of the North West Mains and the intersection
30

 of the NEM and 9 Headgate. The ventilation controls shown on the map indicated the
No. 7 Belt entry in NEM did not extend to the Panel No. 9 longwall belt area. The other
map showed the portion of the mine surrounding the set-up entry for 9 Headgate
longwall section. The ventilation controls shown on the map indicated the four
9 Headgate entries were ventilated as shown in the August 30, 2005, revision for the
Panel No. 9 bleeder system: three common adjacent entries formed the belt entry air
course and one entry was a separate intake air course. The direction of the airflow in
the belt entry was shown to be inby toward the longwall set-up face and indicated air
that ventilated the longwall belt entry was to be used to ventilate the area where
mechanized mining equipment for the 9 Headgate longwall section was being installed.
The revision submittal letter stated the maps identified the ventilation to be used while
setting up Longwall Panel No. 9 and during the recovery of Longwall Panel No. 8.
The ventilation plan, pursuant to § 75.371(hh), stated the ambient level of carbon
monoxide was 0 ppm in the areas of the mine where carbon monoxide sensors were
installed.
The ventilation plan, pursuant to § 75.371(kk), stated the locations where air quantities
are measured as set forth in § 75.350(b)(6) were to be one crosscut outby the last set of
permanent controls or belt tailpiece. These air quantity measurements were intended to
determine that no more than 50 percent of the total intake air delivered to the working
section, or to areas where mechanized mining equipment were being installed or
removed, could be supplied from the belt air course. This regulation applied only to
mines in which belt air is used to ventilate working sections and areas where equipment
is installed or removed.
To use air from a belt air course to ventilate a working section or an area where
mechanized mining equipment is being installed or removed, certain additional
requirements must be met. Among other requirements, § 75.350(b)(3) mandates that a
permanent designated area (DA) for dust measurements be established at a point no
greater than 50 feet upwind from the section loading point in the belt entry when the
belt air flows over the loading point or no greater than 50 feet upwind from the point
where the belt air is mixed with air from another intake air course near the loading
point. The DA must be specified and approved in the ventilation plan. The ventilation
plan, pursuant to § 75.371(t), contained a line diagram of the mine that showed the
location of the DAs where samples for respirable dust were to be collected. No DA for
dust measurements were shown near the section loading points on 2 Section or
3 Section. The direction of air movement depicted in the diagram for 2 Section and
3 Section belts was shown in a direction away from the section.
Mine Ventilation
The mine was ventilated with a combination blowing and exhausting system. Mine
ventilation information is shown in Appendices K and L. Airflow entered the mine
31

 through one intake shaft and exited the mine through two return shafts and several
drift openings. Intake air was forced into the mine by the Melville Fan, installed in a
blowing ventilation configuration at the surface of the 148 feet deep, 15-foot diameter,
Melville Airshaft. Some of this intake air exited the mine through drift openings: the
four drift openings of the Rum Creek belt entry air course and the three drift openings
in the Box Cut. The remainder of the air exited the mine through the two exhaust fans.
The Mecca Fan was installed in an exhausting ventilation configuration at the surface of
the 75 feet deep, 8-foot diameter, Mecca Airshaft. Return air exhausted through the
Mecca Fan ventilated 3 Section and the worked-out areas of longwall Panel Nos. 1, 2, 5,
6, 7, and 8. The Ethel Fan was installed in an exhausting ventilation configuration at the
surface of the 225 feet deep, 14-foot diameter, Ethel Airshaft. Return air exhausted
through the Ethel Fan ventilated 2 Section, 10 Headgate, 9 Tailgate, 9 Headgate, the
worked-out area of longwall Panel No. 9, and 4 Right.
The average of the airflow quantities measured in the intake air course identified as
“Box Cut Mains Intake” during the five weekly examinations conducted prior to the
accident was 472,004 cfm. This airflow entered the mine through the Melville Fan.
Mine records (Daily and Monthly Examination of Ventilation Equipment record books)
showed the average operating pressure of the Jeffrey 108-inch Aerodyne Melville Fan
during the five week period of time prior to the accident was 4.7 inches of water gauge.
The operating pressure of the Melville Fan on January 19, 2006, was 5.4 inches of water
gauge. The average of the airflow quantities measured at the Mecca Fan during the
four weekly examinations conducted prior to the accident was 143,191 cfm. Mine
records show the average operating pressure of the I.W. Buffalo 72-inch Axivane Mecca
Fan during the five week period of time prior to the accident was 4.7 inches of water
gauge. The operating pressure of the Mecca Fan on January 19 was 4.5 inches of water
gauge. The average of the airflow quantities measured at the Ethel Fan during the four
weekly examinations conducted prior to the accident was 301,690 cfm. Mine records
show the average operating pressure of the Jeffrey 96-inch Aerodyne Ethel Fan during
the five week period of time prior to the accident was 4.7 inches of water gauge. The
operating pressure of the Ethel Fan on January 19 was 4.5 inches of water gauge. No
worked-out areas of the Aracoma Alma Mine #1 were sealed from active workings.
Development Sections
Two continuous mining machine units developed mine entries. The four entries
developed off the NEM, known as 2 Section, were to be the headgate entries for
longwall Panel No. 11 (11 Headgate). The 2 Section was ventilated with dual section
return air courses, one on the left side and the other on the right side of the section.
Interview statements, AMS data, and MSHA inspection history revealed air that
ventilated the NEM belt entry was used to ventilate the working 2 Section. No revision
to the ventilation plan had been submitted and subsequently approved to indicate the
use of air that ventilated a belt entry was being used to ventilate the working 2 Section.
32

 The seven entries developed off North West Mains were 3 Mains, known as 3 Section.
The 3 Section was developed to second mine coal pillars in that area after the
establishment of a bleeder system. The 3 Section was ventilated with dual section
return air courses, one on the left side and the other on the right side of the section.
Interview statements revealed air from the 3 Section intake air course was directed into
the 3 Section belt air course through the check curtains located outby the section belt
tailpiece. The air that ventilated the 3 Section belt air course traveled outby into the
North West Mains belt air course.
Mine records indicated the air quantities in the left and right return splits of 2 Section
on the day shift preceding the accident were 12,267 cfm and 13,475 cfm, respectively.
Mine records indicated the air quantities in the left and right return splits of 2 Section
on the midnight shift preceding the accident were 12,210 cfm and 13,460 cfm,
respectively. The 3 Section was idle on the day shift preceding the accident. Mine
records indicated the air quantities in the left and right return splits of 3 Section on the
midnight shift preceding the accident were 10,000 cfm and 14,600 cfm, respectively.
Longwall Section and Bleeder System
Longwall Panel No. 9 was the first of several longwall panels projected to be mined in
the active longwall district located between NEM and 4 Right. Three of the four
9 Headgate entries were common belt air course entries. The fourth entry was the
intake air course, designated as the primary section escapeway.
Mine management officials knew the proper direction for air ventilating the longwall
belt air course was from NEM toward the longwall face and air that ventilated the
longwall belt air course was to be used to ventilate the longwall section. However,
interview statements, mine records, inspection history, and AMS data, indicated that
the direction of the air ventilating the longwall belt air course was different from what
was required during, and at times prior to, the accident. On December 23, 2005,
December 29, 2005, and January 18, 2006, the direction of the air ventilating the
longwall belt air course was moving toward the No. 7 Belt.
AMS CO sensor alert and alarm signals and interview statements revealed that the
direction of the airflow in the longwall belt air course carried contaminants from the
belt takeup storage unit toward the No. 7 Belt during the fire on January 19. However,
because of the fire’s effect on the ventilation in the area, the direction of the airflow
between the longwall belt takeup storage unit and drive on the afternoon shift prior to
the fire could not be definitively concluded.
On January 19, the longwall face was located between crosscuts 17 and 18 of
9 Headgate. The configuration of the check curtains in 9 Headgate at the approaches to
the worked-out area of longwall Panel No. 9 caused air that ventilated the inby portion
of the longwall belt (crosscut 15 through crosscut 17) to ventilate the longwall section.
33

 No information was available concerning the direction of airflow in the longwall belt air
course between crosscut 15 and the takeup storage unit.
The worked-out area of longwall Panel No. 9 was ventilated with a flow-through
bleeder system with bleeder entries. Air was directed from 9 Headgate, the longwall
face, and 9 Tailgate through the worked-out area of longwall Panel No. 9 to entries in 4
Right. Air from the 10 Headgate set-up split also entered the worked-out area of
longwall Panel No. 9 in 9 Tailgate. The bleeder split was coursed through entries in 4
Right to the North West Mains before it joined another split of air.
Mine records indicated the air quantity directed to the longwall Panel No. 9 face was
46,780 cfm and the air velocities at Shield Nos. 17 and 160 were 311 fpm and 220 fpm,
respectively, on the day shift preceding the accident.
Methane Liberation
Vacuum bottle air samples and air quantity measurements were collected in airflow
that exhausted from the mine by MSHA coal mine inspectors during 2005 and 2006.
Based on the results of those samples, the average liberation from the mine was less
than 500,000 cubic feet of methane during a 24-hour period.
Ventilation System Maintenance and Stability
MSHA Accident Investigators found indications of inadequate maintenance of the mine
ventilation system. Numerous necessary ventilation controls were in disrepair or
incompletely constructed. Portions of concrete block stoppings were not coated with
sealant. Some stoppings and equipment doors were damaged. Holes existed in several
stoppings located between adjacent air courses, including belt entries and primary
escapeways, and some had water pipes and electrical cables passing through the
opening.
Not all of the numerous sets of equipment doors that separated adjacent air courses or
functioned as a regulator were installed in pairs to form airlocks. Pairs of equipment
doors are required to be installed to form an airlock to maintain separation between
adjacent air courses. One set of equipment doors in the pair can be opened while the
other set remains closed to enable miners and equipment to pass through each set of
equipment doors sequentially without interrupting ventilation.
There were also indications that portions of the ventilation system may have been
susceptible to inadvertent changes in airflow distribution due to opening of, or failure
to close, equipment doors. Statements revealed miners thought leaving equipment
doors open could have affected airflow in the longwall section. On two of the three
production shifts preceding the accident, miners found problems with the ventilation of

34

 the longwall face and/or longwall belt entry. Time study records revealed one of those
instances occurred during the day shift on January 18.
On the day shift of January 18, production was stopped on the 9 Headgate longwall
section when a state mine inspector for the WVMHS&T measured approximately 25,000
cfm of airflow being directed to the longwall face, less than the minimum required by
the approved mine ventilation plan. The inspector also found intake air from the
9 Headgate entered the longwall belt air course and flowed toward the longwall belt
drive. This airflow direction was opposite the direction required by the approved mine
ventilation plan. Interview statements indicated someone suspected a door might have
been opened. Edward Ellis, who was on the longwall section, called someone who was
not located on the longwall section to investigate the situation. Persons working on the
longwall section relocated check curtains at the approaches to the worked-out area in
9 Headgate, removed a stopping, and installed additional check curtains to re-route
intake airflow in 9 Headgate. However, interview statements indicated ventilation
changes were made somewhere other than on the longwall section that sufficiently
increased the quantity of air directed to the longwall face and corrected the direction of
air ventilating the longwall belt air course. Interview statements indicated the
conditions were corrected within about an hour. Statements from those persons
interviewed who were on the longwall section at the time revealed they were not
certain of the cause of the problem or of the corrective actions taken. However, records
from a time study conducted on the longwall section during the shift revealed
additional information.
Sixty-eight minutes of production delays were attributed to the loss of air on the
longwall face when the state mine inspector stopped production on the longwall section
until the airflow was at the required level for production. The reason for the loss of air
noted in the time study report shift observations was that someone had left the
equipment doors at 10 Headgate open and caused the airflow to short circuit.
Sometime after the start of the day shift of January 19, a decrease in the airflow
ventilating the 9 Headgate longwall panel face was noticed by the longwall section
foreman. He instructed the headgate operator to call to “…see if someone might have
something open.” He indicated the airflow was restored within about 15 minutes.
MSHA accident investigators could not determine the cause and correction of the
change in ventilation.
Changes in Ventilation
Physical evidence, interview statements, and mine records and mine history revealed
several ventilation changes were completed in the months prior to the accident for
which no MSHA approval was found in the approved ventilation plan. Revisions to the
ventilation plan were required to be approved by MSHA prior to implementing the
following ventilation changes:
35

 •

Although the air that ventilated a belt air course was used to ventilate the
working 2 Section, the approved ventilation plan did not reflect this change. On
November 28, and December 20, 2005, an MSHA inspector found the velocity of
the air ventilating the NEM belt entry to be less than 50 feet per minute, and that
the air in that belt air course was being used to ventilate the working 2 Section.

•

The No. 1 Entry of 10 Headgate was changed from a section return to a main
return and the direction of airflow in that entry reversed to course air from the
NEM to 4 Right.

•

The Nos. 6 and 7 Entries of NEM between 9 Tailgate and 10 Headgate were
changed from a return air course to an intake air course and the direction of
airflow in those entries was reversed.

•

A separate split of air was established to ventilate the seal located across from 9
Tailgate in NEM. Several stoppings and a regulator were constructed to
establish that split of air during the weeks prior to the accident. Material for the
construction of the stoppings was supplied to the necessary locations using a
scoop by repeatedly removing a large portion of a permanent stopping that
separated the left return of 2 Section from the NEM belt air course. A check
curtain was reportedly installed each time the stopping was breached. Although
concrete blocks were re-stacked in the stopping following each breach, the blocks
were not coated with sealant until the project was completed. A coal production
crew was reportedly working in 2 Section during shifts on which the work was
conducted. The ventilation change was completed by January 12, 2006.

•

On the midnight shift preceding the day shift of January 18, a planned
ventilation change was conducted in the 9 Tailgate - 4 Right area to ventilate the
10 Headgate set-up face with intake air from 10 Headgate in preparation for setup activities. Interview statements indicated the ventilation change was
coordinated by the assistant superintendent/longwall manager. Reportedly, the
foreman supervising the ventilation change contacted a foreman on the longwall
section by telephone to confirm the ventilation change had no effect on the
ventilation of the longwall.
Ventilation controls necessary to maintain separation between
the No. 7 Belt air course and the intake air course for 2 Section
(primary escapeway) had not been installed or were removed.

Several stoppings and sets of equipment doors were needed to maintain separation
between the No. 7 Belt air course and the adjacent intake air course in NEM. The
primary escapeway for 2 Section was within that intake air course. The absence of one
36

 or more of those stoppings resulted in a lack of separation between those air courses on
January 19.
The absence of necessary stoppings affected ventilation in the area in two ways: air
ventilating the No. 7 Belt air course could have flowed into the adjacent intake air
course; and the direction of airflow in the longwall belt air course could have reversed.
The locations of individual stoppings involved have been identified. Information
concerning their absence is detailed below.
Physical evidence and interview statements indicated that no stopping existed across
the No. 7 Belt entry inby the belt tail between SS 3249 and SS 3266 on January 19
(Figures 3 and 4).
A stopping was depicted at this location on maps posted in mine offices, including the
map that was identified by the mine operator representative as the map that § 75.1202-1
required to be kept up-to-date with temporary notations showing permanent
ventilation controls constructed or removed. An image of that map is provided in
Appendix M. Additional discrepancies existed between the ventilation controls
mapped by the investigation team and those depicted on the required map(s).

72” Belt Structure
Being Installed

No. 7 Belt
Tail Roller

No Evidence of Stopping at
Tail Roller of No. 7 Belt

Figure 3. Absence of critical ventilation control.

37

 Figure 4. Area inby No. 7 Belt tail pulley.
(Roof support was installed post-accident.)

Physical evidence and interview statements revealed a stopping had been constructed
in the No. 7 Belt entry between SS 3266 and the intersection with the next inby crosscut.
However, there was no stopping in that location on January 19 (Figures 5 and 6). This
stopping was removed by a construction crew to facilitate installation of a dual switch
house (“splitter box”) during the last week of October 2005. Belt structure was later
installed so that the structure extended from near SS 3266 to just outby the intersection
at SS 3223. Interview statements revealed the framed curtain had been removed prior to
December 29, 2005.

Stopping Removed to Install 72”
Belt Structure Prior to Fire

72” Belt Structure
Installed

Figure 5. Critical ventilation control removed prior to fire.

38

 Figure 6. Location where belt structure was installed after removal of a stopping.

Pairs of equipment doors were constructed to facilitate passage of men and equipment
along the NEM roadway to pass under the longwall belt. The configuration of the
ventilation controls and mine layout necessitated the construction of at least two
stoppings for the pair of equipment doors installed between SS 3267 and SS 3333 to
form an airlock, as required by § 75.333(d)(3). The stoppings which would have been
necessary to form this airlock would also have separated the two air courses. Although
it was not concluded whether an airlock was ever established at this location, it was
determined that no airlock was established between SS 3267 and SS 3333 on January 19.
•

One of the stoppings had been constructed between SS 3266 and the travel
roadway, in the crosscut where the electrical installations for 9 Headgate
longwall belt drive and takeup storage unit were located. The stopping was
reportedly removed to reduce the accumulation of heat in the crosscut where the
electrical installations were located. Two midnight shift electricians were
observed removing the stopping. Physical evidence and interview statements
indicated this stopping was removed prior to the fire (Figures 7 and 8).

•

The installation of another single stopping could have completed the airlock
between SS 3267 and SS 3333. The location of that single stopping was in the
crosscut on the side of the roadway opposite the longwall belt electrical
installations. Alternatively, a series of stoppings in NEM between 9 Headgate
and 9 Tailgate could have completed the airlock. Physical evidence and mine
rescue and recovery logs and maps revealed neither the single stopping nor
several of the individual stoppings in this alternative series were in place on
January 19.

39

 Stopping Removed
Prior to Fire

72” Belt Structure
Installed

Figure 7. Additional critical ventilation control removed prior to fire.

Figure 8. Former location of stopping at the electrical installation.

Compliance with the existing Belt Air Rule would have
prevented the two fatalities.

Belt Air Regulations
On April 2, 2004, the final Belt Air Rule was published in the Federal Register. The rule
was promulgated after many years of experience under the petition for modification
process. On January 21, 2000, Aracoma Coal Company filed a petition for modification
of § 75.350. The petition, granted by MSHA on May 3, 2000, allowed air coursed
through belt entries to be used to ventilate working places, conditioned upon
40

 compliance with seventeen specific terms and conditions of the petition. At that time,
use of belt air to ventilate working places was prohibited except under petition for
modification, approved petitions which were determined to have provided equal
protection to the applicable regulation. The final rule superseded all granted petitions.
The final rule included a number of conditions the mine operator is required to
maintain to use belt air to ventilate working sections and areas where mechanized
mining equipment is being installed or removed.
The mine operator failed to comply with more than 25 regulatory provisions of the final
Belt Air Rule at the Aracoma Alma Mine #1 on January 19. Most of these regulatory
provisions had been included in the terms and conditions of the petition that was
superseded by the Belt Air Rule. Two of the provisions were related to the approved
mine ventilation plan.
Several of the regulatory provisions, such as failure to separate the belt air course from
other air courses, failure to provide an alarm unit for 2 Section, failure to withdraw
miners in the event of a CO alarm signal, failure to report alert and alarm signals to
appropriate personnel, and failure to adequately train AMS operators, had significant
impact on the outcome of the January 19 fire. Had the mine operator been in
compliance with the Belt Air Rule, the fire would not have resulted in the two fatalities.
Atmospheric Monitoring System
A Pyott-Boone AMS, Model 9500, was installed at the mine to measure carbon
monoxide concentrations along the entire underground belt system. Approximately 44
carbon monoxide sensors were installed in the belt entries to provide early warning of a
fire (Figure 9).

Figure 9. Carbon monoxide sensor.

41

 The locations of the CO sensors are shown in Appendix N. An alarm unit was installed
underground at the longwall headgate to provide visual and audible signals in the
event of a single CO alarm signal or alert signals from two consecutive CO sensors
(Figure 10).

Figure 10. Remote alarm unit in headgate area on longwall section.

To function properly, the mine operator was required to program the AMS computer to
respond to individual CO sensor signals so that specific CO sensors would
automatically activate the appropriate alarm unit. The AMS computer, printer, visual
display, and means of communication with underground locations were located in the
dispatcher’s office (Figure 11).

Figure 11. AMS in dispatcher’s office located in Box Cut on surface.

42

 The dispatcher’s office was located on the surface in the shop area of the Box Cut,
adjacent to the warehouse and the lamp room. AMS alert, alarm, and malfunction
signals were received on the surface in the dispatcher’s office. The AMS computer
automatically generated a printed record of all alert, alarm, and malfunction signals.
This printed record was identified as the AMS event log. Visual and audible AMS alert,
alarm, and malfunction signals were provided through the AMS computer for the AMS
operator in the dispatcher’s office. As an additional means of providing audible and
visual notification on the surface, a strobe light and horn were also installed in the open
area of the Box Cut shop.
Section 75.351(e)(3) did not permit CO sensor spacing to exceed 1,000 feet in belt entries
where air was used to ventilate working sections. As noted previously, alert and alarm
levels of CO were 5 and 10 ppm, respectively. The minimum air velocity permitted in
the belt entry was 50 fpm. The mine operator used the term “warning” in place of
“alert” in approved plans, documentation, and computer programming to identify
when 5 ppm CO was detected by a CO sensor. Required responses to signals from the
system were specified in § 75.352, as well as in the approved mine emergency
evacuation and firefighting program of instruction.
In response to AMS alert, alarm, and malfunction signals received at the surface,
dispatchers reportedly contacted mine foremen, supervisors, electricians, belt
examiners, and/or beltmen to investigate causes of the signals. Alert, alarm, and
malfunction signals were received on the surface in the dispatcher’s office. All alert,
alarm, and malfunction signals were required to be recorded in a properly identified
record book. The required record of alert, alarm, and malfunction signals generated by
the AMS was maintained by the dispatchers in a mine record book identified as the CO
Log Book. The recordkeeping requirements for alert and alarm signals specified in
§ 75.351(o) included the date, time, location, type of sensor and the cause for the
activation of the signal(s). Similar records were required for malfunction signals. The
format of the first page of the CO Log Book consisted of columns labeled as “Date,”
“CO #,” “Down On,” “Who Notified,” and “Action Taken.” The first entry in the book
is dated December 2, 2004, and the last entry is dated January 19, 2006.
Functional tests of alert and alarm signals were required to be conducted every 7 days.
Each CO sensor was required to be calibrated at intervals not to exceed 31 days. These
tests and calibrations were required to be recorded and the records retained at a surface
location for at least one year.
To utilize belt air to ventilate the working sections per § 75.350, the AMS was to be
installed and maintained as specified in § 75.351. The mine operator was also required
to designate an AMS operator to monitor and properly respond to all AMS signals. At
Aracoma Alma Mine #1, the dispatcher was the AMS Operator. The dispatcher also
issued supplies from the warehouse, and cap lamps and hand-held detectors from the
lamp room. The regularly scheduled work hours for dispatchers provided for an
43

 overlap so that two dispatchers were on duty at the beginning of each shift. This
overlap enabled one dispatcher to remain on duty in the dispatcher’s office while the
other worked in the warehouse or lamp room during that time. Dispatchers were
occasionally required to perform duties outside the dispatcher’s office during their shift.
Three schematic diagrams that were visible on the AMS computer display were used to
identify the locations of AMS CO sensors along the belts. A mine map posted on the
wall behind the dispatcher’s desk was intended to indicate sensor locations and air
directions.
As part of the investigation, the AMS was tested to determine if the system would
respond as intended to alert and alarm levels of CO applied to properly calibrated CO
sensors in communication with the AMS computer. The CO sensors responded as
designed. The alert and alarm signals activated the visual and audible alarm in the
dispatcher’s office and were seen and heard by the AMS operator on the surface. The
alarm unit on the longwall headgate, installed as a replacement for the unit removed
after the fire, also responded properly and was seen and heard by persons in the
longwall section headgate area. The alert and alarm signals, as well as calibration of the
sensors, were recorded on the AMS event log as expected.
AMS Event Log
A printout of the AMS event log was reviewed for the period from December 31, 2004
to January 20, 2006. The AMS event log included dates and times for AMS alert, alarm,
and malfunction signals, CO sensor calibrations, and belt functions for the NEM and
2 Section belts. Much of the information contained in the AMS event log was not
related to the fire that occurred on January 19.
The dates and times shown on the AMS event log were based on the AMS computer
time clock. The AMS computer time clock was not synchronized with the actual time.
The National Institute of Standards and Technology (NIST) is a non-regulatory agency
of the US Department of Commerce that maintains the official time for the United
States. On February 6, comparisons were made to correlate the time shown on the AMS
computer with the actual time maintained by NIST. It was determined the AMS
computer clock was approximately 23 minutes fast. All references to AMS event log
times made in this report contain the subtracted 23 minutes to correct the AMS
computer time to the approximate actual time. On January 25, CMS&H District 4
personnel noted similar differences.
AMS Sensor Calibration Records
Records of CO sensor calibrations were entered in the Examinations of Electrical
Equipment record book. No other records identified as being used for AMS tests and
calibrations were provided by the mine operator. The record of CO sensor calibrations
44

 was incomplete and not maintained in a record book separate from records other than
those required by § 75.351(o). Mine records and statements revealed calibrations of CO
sensors were not conducted as required and were not properly recorded. Mine records
and the AMS event log revealed that all CO sensors were not calibrated within the 31day period prior to the fire.
The record book indicated that CO sensor calibrations were conducted on only three
days. Calibrated sensors were identified by groups rather than by individual sensor
number. The calibration record book indicated “calibrated CO’s from 2 Section #2 Belt
to #1 Belt Head” on January 5, 2006; “calibrated longwall CO’s” on January 9, 2006; and
“Calibrated Rum Creek CO’s” on January 10, 2006.
The AMS event log indicated calibrations of CO sensors along with other information.
Representatives from the AMS manufacturer indicated that all sensor calibrations
should have been automatically recorded in the AMS event log if the event log was
running during calibrations. It was not determined if the AMS event log was running
during all calibrations. The AMS event log revealed only 8 of approximately 45 CO
sensors in the AMS were calibrated within the 31 day period prior to the fire. The AMS
event log data also indicated the CO sensor calibrations were not always properly
conducted. The mine record book also indicated all CO sensors in the AMS were not
calibrated within the 31-day period prior to the fire. Discrepancies existed between
calibrations noted in the record book and those in the AMS event log. Calibrations of
CO sensors listed in the Examination of Electrical Equipment record book were not
shown in the AMS event log. In addition, the AMS event log indicated calibrations
were conducted that were not recorded in the record book.
The AMS event log indicated CO Sensors 81 and 82, which first responded to the fire on
January 19, 2006, were last calibrated on December 2, 2005, 49 days prior to the fire.
Those calibrations were not included in the Examination of Electrical Equipment record
book.
Laboratory Testing
The section alarm and CO sensor located at the longwall headgate were removed from
the mine. On May 23, 2006, the units were examined and tested at MSHA’s Approval
and Certification Center in Triadelphia, WV, to determine their operational status.
Tests were conducted to evaluate the condition of the equipment, assess the response of
the sensor and alarm to application of CO to the sensor, and determine the operation of
test buttons on the units. During the initial examination, the internal battery of the
alarm unit was found to be disconnected. Tests were conducted on the LED warning
signals and audible alarm signals. On June 1, additional tests were completed at
MSHA’s Pittsburgh Safety and Health Technology Center to fully evaluate the sound
levels of the alarm unit.

45

 The visual warning and audible alarm signals were significantly diminished because
the battery was disconnected. The unit was originally shipped from the manufacturer
with the battery disconnected. The instruction manual for this unit indicated the
battery was to be connected prior to use. It was not determined if the battery had been
connected during initial installation, or if the battery had been disconnected some time
after installation. Laboratory tests revealed the LED illuminance was reduced by over
98 percent and the sound level was reduced by 68 percent, as compared to tests with the
internal battery properly connected.
The CO sensor, Pyott-Boone Electronics Model 1711 CO Monitor, had not been
evaluated by MSHA for use in areas where electrical equipment was required to be
permissible. On January 19, this CO sensor was located in an area where permissible
electric equipment was required. A complete report of these tests is available from the
Electrical Safety Division of the MSHA Approval and Certification Center.
There was no CO alarm unit provided for 2 Section, where 12
miners were working on January 19, 2006.
AMS Installation and Maintenance Related Deficiencies
Basic AMS requirements are included in § 75.351. The mine operator did not comply
with the following provisions of this Section:
•

The map and these schematics provided in the dispatcher’s office did not show
the intended airflow direction at each CO sensor location as required.

•

Sensor spacing exceeded the 1,000-foot maximum distance at multiple locations.
Air ventilating the belt entries where these CO sensors were located was used to
ventilate 2 Section and was intended to be used to ventilate the longwall section.

•

Although § 75.351(e)(4) required CO sensors to be installed within 100 feet
downwind of belt transfer points, no CO sensor was installed within 100 feet
downwind of the transfer point from the No. 7 Belt to the No. 6 Belt.

•

The mine operator failed to provide a two-way voice communication system in
an entry separate from an entry containing the AMS as required by § 75.351(r).
The pager mine phone system utilized two wires within the AMS cable bundle.
The AMS cable bundle for the CO sensors along the longwall belt was installed
in the longwall belt entry. During the fire that occurred in the longwall belt
entry on January 19, 2006, AMS communication with CO sensors located in the
9 Headgate longwall belt entry and mine phone communication with the
longwall section failed.

46

 •

§ 75.351(c) required visual and audible signals to be automatically provided at all
affected working sections when the CO concentration at any sensor reached the
alarm level.
o The alarm unit on the longwall section was not activated automatically
when the CO concentrations at the CO sensors located near the longwall
belt drive reached the alarm level. Statements revealed the AMS
computer was not properly programmed to automatically provide alarm
signals for the longwall section.
o The longwall section alarm unit was located where it could not be readily
seen and heard by miners working on the longwall section.
o The longwall section alarm unit was not maintained in proper operating
condition because the internal battery was not connected to the alarm
circuit. The manufacturer’s instruction manual specified the internal
battery must be connected. The absence of power from an internal battery
significantly diminished the visual display (LED) and also reduced
audible sound levels.
o No AMS alarm unit was installed on 2 Section. An AMS alarm unit
should have been properly installed and maintained at a location where it
could be seen or heard by miners working on 2 Section. A properly
installed and maintained alarm unit on 2 Section would have
automatically provided visual and audible notification to the miners on
that section at the time of the first CO alarm signal. Automatic
notification of the miners on 2 Section would have expedited their
withdrawal and evacuation on January 19.

•

The weekly functional tests of alarms were not properly conducted. These tests
were required for all alarm units installed both underground and on the surface.
The mine operator failed to provide a record of the weekly functional tests
required to be maintained by § 75.351(n)(2). At least one longwall headgate
operator was unaware that an alarm unit was installed in the headgate area. The
strobe light and horn installed in the open area of the Box Cut shop was not
functioning properly at the time of the fire. According to interview statements, the
AMS signals could not be seen or heard from the warehouse, lamp room, and at
other locations in the Box Cut area. Deficiencies in the performance of the alarm
units should have been identified and corrected during properly conducted
functional tests.

•

Not all CO sensors were properly located in the belt entry. CO sensors must be
located near the center of the entry in locations where airflow patterns permit
products of combustion to be carried to the sensors to comply with § 75.351(d)(2).
47

 CO sensors were installed against the rib in at least two locations in the belt entries
(Sensor 50, located near the No. 6 Belt drive, and Sensor 70, located in the NEM
belt entry). The longwall headgate Sensor 102 was attached to the rear of a metal
plate used to support the emulsion valves, facing the rib and not located in the
center of the entry.
•

As discussed previously a permanent DA was required to be established to
monitor respirable dust levels in the belt entries used to ventilate the working
sections. While a DA was established for the longwall section, there was not a DA
established for 2 Section. The mine ventilation plan had not been amended to
include the required information prior to using air from a belt air course to
ventilate 2 Section.

•

No CO or smoke sensors were installed in the primary escapeway for the longwall
section and 2 Section as required.

•

The CO sensor installed at the longwall headgate (Sensor 102) did not meet the
requirements of § 75.1002(a).

•

Mine records and interview statements indicated all CO Sensors were not properly
calibrated.

Alert, Alarm, and Malfunction Signal Response Deficiencies
A comparison of the mine operator’s AMS Log Book with the printed AMS event log
revealed that all the alert, alarm and malfunction signals received on the surface were
not recorded as required in the CO Log Book. The record book did not include all of the
information required by § 75.351(o), including the cause of many alert and alarm
signals. In addition, interview statements and mine records revealed improper
responses to AMS alert, alarm, and malfunction signals. Multiple alarm signals
recorded in the AMS event log required notification and prompt withdrawal of miners
in affected areas to a safe location.
Mine records and interview statements indicated that miners on the working section in
the affected area were not withdrawn promptly when a fire occurred on December 29,
2005. During that fire, alarm signals from six different CO sensors were received on the
surface. The dispatcher initiated an investigation of the alarm signals. The AMS event
log revealed the AMS alarm unit on the longwall section, which was an affected area,
was not automatically activated as required.
On January 19, the AMS event log indicated numerous communication failures
occurred with Sensor 75 which were not recorded in the AMS Log Book. Beginning at
approximately 8:34 a.m., a total of 38 communication failures, indicated as
“Communications Dead” on the AMS event log, were recorded for Sensor 75 prior to
48

 the fire being detected. There was no record of an investigation of the cause of the
malfunction signal and the condition was not corrected.
As further evidence of AMS malfunction, the AMS event log did not indicate a response
was received from Sensor 75 to CO produced by the fire. During the fire, sensors
located both inby and outby Sensor 75 in the same belt entry responded properly and
indicated alarm levels of CO. Continued operation of the belt would have required the
immediate repair of the sensor and patrolling of the affected area by miners using
equivalent hand-held gas monitors, as required by § 75.352(e), until repairs were
completed. Although the malfunction continued and the belt was operated on the
afternoon shift, no person was assigned to patrol the affected area.
AMS Response on January 19, 2006
The AMS event log was used to develop the following summary of alert and alarm
signals, specific malfunction signals, and belt stoppages occurring on January 19. On
that day, there were two AMS alert signals recorded in the AMS event log prior to the
fire; both were at Sensor 82, and occurred hours prior to the fire. At approximately 2:13
a.m. and 11:16 a.m., alert levels of CO were detected by Sensor 82, with a duration of
approximately 1 minute and 6 seconds and 1 minute and 25 seconds, respectively.
Interview statements and the CO log book indicated the dispatcher on duty did not
notify the appropriate personnel nor properly document the events. There was no
record of an investigation to determine the cause of the alert signals. It is not known
whether these alert signals were related to any events or conditions that caused the fire.
The day shift belt examiner first observed haze at the longwall belt takeup storage unit
and drive around 10:00 a.m. Repeated attempts to identify the source of the haze were
unsuccessful. Reportedly, the air cleared without further incident by the end of his
shift.

49

 Table 4 - Abridged AMS Event Log from January 19, 2006

Time
02:12:43
11:16:23
17:13:34
17:13:55
17:15:44
17:16:05
17:39:22
17:39:26
17:39:34
17:59:37
17:59:38
18:10:50
18:11:05
18:15:30
18:16:17
18:16:19
18:16:50
18:30:19
18:31:35
18:40:21
19:07:30
19:08:22
19:08:35
19:08:35
19:09:40
19:10:23
19:13:33
19:15:18

Sensor
82
82
82
82
81
81

82
83
71
71
81
80
73
73
74
74
72
76
77
76
76
76
77
79
79

Signal
Warning
Warning
Warning
Alarm
Warning
Alarm
6 Belt Boss – STOP –Remote (from Master Station)
8 Belt Boss – STOP –Sequence
7 Belt Boss – STOP –Sequence
Communications Dead
Communications Dead
Warning
Alarm
Communications Dead
Communications Dead
Warning
Alarm
Warning
Alarm
Warning
Communications Dead
Warning
Gained Communications
Warning
Alarm
Alarm
Warning
Alarm

“Communications Dead” indicates a loss of communication between the AMS computer and CO sensors.
“Gained Communications” indicates communication between the AMS computer and CO sensors was
restored. “Warning” is the term the mine operator used to indicate alert levels of CO.

Figure 12 illustrates the location of CO Sensors 82 and 83, which were in the area where
the fire originated. According to the AMS event log, the first sensor to detect an alert
level of CO was Sensor 82. This indicated the direction of airflow was from the belt
takeup storage unit toward Sensor 82 at the time the CO was detected. An alarm level
of CO was detected at Sensor 82 at approximately 5:14 p.m., 21 seconds after the alert
level. An alarm level of CO was detected at Sensor 81 at approximately 5:16 p.m., also
21 seconds after the alert level.

50

 Figure 12. Relative CO Sensor Locations on January 19, 2006.

The “Belt Boss” entries in the AMS event log indicated the time the NEM and 2 Section
belts were stopped. The 2 Section belt was stopped 25 minutes after the first CO alarm
signal was indicated by the AMS.
As the fire continued to burn, additional alert and alarm signals were recorded for CO
sensors located along the NEM and 2 Section belts. These signals indicated CO from the
fire contaminated not only the intake air being coursed toward 2 Section, but also the
NEM belt air course. With the exception of Sensor 75, sensors along the 48-inch No.
2 Section belt inby the longwall headgate indicate contaminants from the fire were
entering the 48-inch belt. The contaminants traveled from the point of entering the belt
51

 to the No. 2 Section loading point. Communication problems between the AMS
computer and Sensor 75 occurred throughout the day. There was no record in the AMS
event log of alert or alarm conditions for Sensor 75. CO sensors properly
communicating with the AMS computer appeared to respond as designed. Since CO
Sensors 81 and 82 were destroyed by the fire, it could not be determined if the sensors
had been properly positioned within the entry. Based upon mine records and
interviews with miners it could not be determined if sensors 81 and 82 were maintained
in a manner which provided proper detection of CO produced by the developing fire.
Electrical System
The Aracoma Alma Mine #1 was supplied power by American Electric Power. The
incoming power at the Box Cut portal was supplied at 138,000 volts and was
transformed to 12,470 volts at a surface substation. Two separate 12,470 volt circuits
supplied power to the underground portion of the mine north of the Box Cut.
One circuit (longwall circuit) provided power to the 9 Headgate longwall section, the
9 Headgate longwall belt drive power center/belt starter, and to the future 10 Headgate
longwall section. The longwall circuit entered the mine through the No. 1 Entry of the
Box Cut portal.
The other circuit (miner circuit) supplied high-voltage power to the Nos. 4, 5, 6, and 7
belts, the 2 Section belts, and the 3 Section belts, the continuous mining machine
sections, the dewatering pumps, and the freshwater pumps. The miner circuit entered
the mine from the surface through a bore-hole located two crosscuts inby the Box Cut
portal in the No. 2 Entry. The #20 KVA transformer, between SS 1640 and SS 1639 in
the North West Mains, supplied 480 volt three phase AC power to the freshwater
pumps. The freshwater pumps were located in the crosscuts on both sides of SS 1649
intersection in the North West Mains. The longwall and miner circuits are shown in
Appendices O and P.
The 12,470 high voltage power circuit entering the mine from the Rum Creek Portal
supplied electrical power to the Nos. 1, 2, and 3 Belts, and other electrical circuits.
The longwall circuit provided high-voltage power to the 9 Headgate longwall belt drive
area. The high-voltage power came to a dual switch house located at the old 8
Headgate panel at the end of the North West Mains. The circuit continued as a branch
into the NEM to the dual switch house for the 9 Headgate longwall section, located in
the crosscut adjacent to SS 3266. Power then fed through the dual switch house to the
2,500 KVA longwall belt power center/belt starter. The longwall belt power center/belt
starter provided power to the 9 Headgate longwall belt drive dual 750 HP, 500 VDC
belt controllers and motors, and the 150 HP Constant Tension Vector Winch Controller
located in the same crosscut.

52

 Electrical Examinations and Tests
Sections 75.512 and 75.512-2 require that at least weekly, all electrical equipment must
be examined, tested, and maintained to assure safe operating condition. A record of
such examinations was required to be maintained. Section 75.900-3 requires all lowvoltage and medium-voltage circuit breakers and their auxiliary devices to be tested
and examined at least monthly.
The record of examinations and tests required by § 75.512 were maintained by the mine
operator in the Examination of Electrical Equipment record books. Individual record
books were used to record the examinations and tests of electrical equipment in various
areas of the mine. Specific electrical equipment components were not identified
individually in the record book. The 9 Headgate longwall belt takeup storage unit was
not specifically identified in any of the record books. It could not be determined if the
belt takeup storage unit was examined at the same time as the longwall belt drive.
There was no record to indicate all required examinations and tests were conducted.
The last record of examinations and tests of the 9 Headgate longwall belt electrical
equipment was made on January 18. Interview statements indicated the examinations
and tests were actually conducted on the midnight shift on January 19. The
examination was inadequate because the following dangerous conditions, which
existed at the time of the fire, were not identified in the examination record:
•

The electrical control switch cable for the water sprinkler water flow valve was
not secured with a proper fitting where it entered the metallic frame of the
9 Headgate longwall belt deluge control box.

•

The ground monitor was intentionally disabled for the cooling fan on the
9 Headgate longwall belt winch motor. It was not determined if the ground
monitor was disabled at the time of the examination.

The record of tests and examinations required by § 75.900-3 were maintained by the
mine operator in the Examination of Electrical Equipment record books. There was no
record to indicate all required tests and examinations were conducted. The last record
of examinations and tests of the 9 Headgate longwall belt electrical equipment was
made on January 18. Interview statements indicated the examinations and tests were
actually conducted on the midnight shift on January 19.
Inspection of the 9 Headgate Longwall Belt Drive Electrical Components
During the investigation of the accident all the electrical controls installed at the
9 Headgate longwall belt drive were inspected. The inspection of the electrical controls
did not reveal any conditions that could be attributed to the source of ignition for the
fire.

53

 Inspection of the 2,500 KVA 9 Headgate longwall belt drive power center/belt starter
revealed that the ground monitor for the #1 750 HP motor was observed with a short
length of wire attached to the No. 4 terminal. This wire was in close proximity to the
No. 3 terminal, but was not connected to it. Although it appeared the wire may have
previously been used to defeat the ground monitor, it was not connected to both
terminals at the time of the inspection.
The inspection of the longwall belt takeup storage unit winch control box indicated the
ground monitor was intentionally disabled for the cooling fan on the 9 Headgate
longwall belt winch motor. A short length of wire was connected to the No. 3 and No. 4
terminals.
The deluge control box attached to the 2,500 KVA power center/belt starter was also
examined during the inspection of the electrical components. The unit was installed to
provide an audible alarm, and to stop the belt in the event water flowed through the
water sprinkler system. The control box was not wired in a functional method because
the cable entering the box was not entered through a proper fitting. In addition, one of
the conductors (white wire) of the Number 14 AWG, three conductor, cable from the
flow sensor, was not attached to the proper terminal. This cable provided power
through the flow sensor normally open interlock installed in the water sprinkler system
installed at the 9 Headgate longwall belt drive. It could not be determined if the wire
had become disconnected during the fire, firefighting and recovery efforts, or during
the accident investigation inspection. The unattached wire would prevent the belt from
stopping and the activation of the audible alarm during operation of the water sprinkler
system.
Water Sprinkler System for the 9 Headgate Longwall Belt
Section 75.1101-11 requires, in part, that each water sprinkler system be examined
weekly and a functional test of the complete system be conducted at least once a year.
The record book labeled “Mother Drive Examination of Electrical Equipment”
contained results of examinations of the water sprinkler system for the belt drive,
takeup storage unit, electrical control, and gear-reducing unit for the 9 Headgate
longwall belt.
Records indicated the water sprinkler system was examined on November 6, 2005,
November 25, 2005, and visually examined on January 18, 2006. A review of the record
book revealed not all the required weekly examinations of the water sprinkler system
were conducted. An adequate weekly examination of the water sprinkler system for
the 9 Headgate longwall belt drive and takeup storage unit was not being made, and no
record of the yearly functional test was found.

54

 There was no fire suppression system installed on the longwall
belt takeup storage unit, where the fire originated.
The electrical components and belt takeup storage unit were not provided with any
type of fire suppression system that would actuate in the event a rise in temperature
occurred at this location as required by § 75.1101-8(a). This hazardous condition was
not identified and recorded at the time of the examination. Proper examinations would
have revealed the absence of an adequate and complete water sprinkler system.
Escapeways, Escapeway Maps and Drills
Section 75.380 requires at least two separate and distinct travelable passageways
designated as escapeways from each working section, continuous to the surface drift
opening or to the escape shaft or slope opening to the surface. Further, each escapeway
is required to be maintained in a safe condition to always assure passage of anyone,
including disabled persons. Each escapeway must be clearly marked to show the route
and direction of travel to the surface, and must be located to follow the most direct, safe,
and practical route to the nearest mine opening suitable for the safe evacuation of
miners.
Sections 75.380(f) and (g) address primary escapeways specifically. Section 75.380(f)
requires one escapeway that is ventilated with intake air to be designated as the
primary escapeway. As stated in § 75.380(g), except where separation of belt and
trolley haulage entries from designated escapeways did not exist before November 15,
1992, and except as provided in § 75.350(c), the primary escapeway must be separated
from the belt and trolley haulage entries for its entire length, to and including the first
connecting crosscut outby each loading point except when a greater or lesser distance
for this separation is specified and approved in the mine ventilation plan and does not
pose a hazard to miners. The mine entries in the NEM were developed after 1992.
Section 75.350(c) requires approval in the mine ventilation plan for additional intake air
to be added to the belt air course through a point-feed regulator. The location and use
of point-feed regulators must be approved in the mine ventilation plan. On January 19,
2006, no point-feed regulator was approved in the mine ventilation plan at Aracoma
Alma Mine #1. Section 75.350(c) does not permit air from the belt air course to enter an
intake air course that is a designated primary escapeway. Further, § 75.333(b)(4)
requires permanent stoppings or other permanent ventilation control devices be built
and maintained to separate the primary escapeway from belt and trolley haulage
entries, as required by § 75.380(g).
Section 75.383 lists requirements for escapeway maps and drills. § 75.383(a) requires a
map is to be posted or readily accessible to all miners in each working section, and in
each section where mechanized mining equipment is being installed or removed. The
55

 map shall show the designated escapeways from the working section to the location to
where miners must travel to satisfy the escapeway drill specified in § 75.383(b)(1). A
map showing the main escapeways is required to be posted at a surface location of the
mine where miners congregate, such as at the mine bulletin board, bathhouse, or
waiting room. All maps are required to be kept up-to-date, and any changes in route of
travel, locations of doors, or directions of airflow shall be shown on the maps by the end
of the shift on which the changes are made, and affected miners informed of the
changes before entering the underground areas of the mine. Miners underground on a
shift when any such change is made are to be immediately notified of the change. The
routes of the primary and alternate escapeways for 2 Section and the 9 Headgate
longwall section shown on the map posted at the surface location where miners
congregated are depicted in Appendix Q.
Section 75.1202-1(b)(4) requires temporary notations for escapeways designated by
means of symbols to keep up-to-date the map(s) required by § 75.1202-1. The
escapeways marked on the map identified by mine operator representatives as the map
that § 75.1202-1 required to be kept up-to-date with temporary notations showing
escapeways did not reflect the route of the underground markings. No alternate
escapeway routes were marked on the § 75.1202-1 map for 2 Section and the 9 Headgate
longwall section. Further, the primary escapeway routes marked on the § 75.1202-1
map for 2 Section and the 9 Headgate longwall section did not accurately reflect the
actual routes marked underground by reflective tags.
Section 75.383(b)(1) requires practice escapeway drills to be conducted at least once
every 90 days for all miners. Each miner on a working section is required to travel the
primary or alternate escapeway from the working section to an area where the split of
air ventilating the working section intersects a main air course, or 2,000 feet outby the
section loading point, whichever distance is greater. An escapeway drill shall not be
conducted in the same escapeway as the immediately preceding drill.
Section 75.383(b)(2) requires practice escapeway drills to be conducted at least once
every 6-weeks. At least two miners on each coal producing working section who work
on that section, accompanied by the section supervisor, shall travel the primary or
alternate escapeway from the section to the surface, to mechanical escape facilities, or to
an underground entrance to a shaft or slope to the surface. Systematic rotation of
section personnel shall be used so that all miners working on that section participates in
a 6-week drill. An escapeway drill shall not be conducted in the same escapeway as the
immediately preceding drill. An escapeway drill conducted to fulfill the requirements
of the 6-week drill may also fulfill the requirements of the 90-day drill.
Underground Escapeways
The mine operator used reflective tags hung from the mine roof to mark the routes of
the underground escapeways. Green colored reflective tags were used to indicate the
56

 primary escapeway route and amber colored reflective tags were used to indicate the
alternate escapeway route. Both types of reflective tags were red colored on the back
side. The markers were to be hung such that a miner following either the green or
amber color would travel in the proper escape direction to the surface of the mine. The
red-colored sides of both the green or amber reflective tags were to indicate that the
miner was traveling in the wrong direction for escape when following the red color.
The green reflective tags that were visible in the primary escapeway were mapped by
MSHA investigators. The escapeways were intended to lead miners from the sections
in escape routes that exited the mine through drift openings in the Box Cut. The
locations of the tags marking the primary escapeways for 2 Section and 9 Headgate
longwall section are shown in Appendix R.
Mine maps located on the surface and underground did not
accurately depict permanent ventilation controls or escapeways.
Main Escapeways
The main escapeways for the underground working sections were located in the North
West Mains. A map showing the main escapeways was posted under a clear plastic
cover on a wooden table at a surface location where miners congregated in the waiting
area prior to the beginning of the shift. The routes of the main primary and alternate
escapeways for 2 Section and 9 Headgate longwall section shown on this map are
depicted in Appendix Q. The main primary and alternate escapeways terminated on
the surface at the Box Cut openings. The underground primary and alternate
escapeway routes marked by reflective tags were not accurately depicted on the map
maintained on the surface map.
Escapeways from 2 Section
The primary escapeway for 2 Section was marked with green reflective tags in the
intake air course of NEM. The route of the primary escapeway was not clearly marked.
Although the regulation requires a distinct, clearly marked, escapeway to be
designated, green reflective tags between 2 Section and the North West Mains were
located in multiple parallel mine entries, indicating multiple escapeway routes. All
changes in the direction of the multiple routes were not clearly marked. The escapeway
maps required by § 75.383(a) did not reflect the underground route that was marked
with the greatest number of green reflective tags. The underground route marked with
the greatest number of green reflective tags followed the roadway from 2 Section to the
equipment doors located inby the longwall belt. The primary escapeway reflective tags
did not follow the roadway through the equipment doors, but diverted from the
roadway through a crosscut at SS 3333 in a northwest direction. Visible reflective tags
marking this route were not observed shortly after making the turn to the northwest
without making another turn. A miner traveling this route and continuing in the
57

 direction indicated by the reflective tags would have encountered the 72-inch belt
structure installed in the entry adjacent to the roadway. This belt structure was an
obstruction to a miner traveling this route. The route marked with reflective tags
continued across the overcast at SS 3221 and then rejoined the roadway on the
southwest side of the outby equipment doors at the longwall belt drive. The primary
escapeway route marked by green reflective tags continued to the North West Mains
and then on to the surface at the Box Cut.
The alternate escapeway for 2 Section was not clearly marked to show the route and
direction of travel to the surface. The escapeway map on 2 Section was readily
accessible to all miners and showed the alternate escapeway to be in the NEM belt entry
to the North West Mains.
The escapeway map that was readily accessible to miners on 2 Section was inaccurate.
An image of the escapeway map is shown in Appendix S. The mine workings shown
on the map were not up-to-date. Although 2 Section was developed into 11 Headgate,
the 2 Section faces shown on the map were just inby 10 Headgate in NEM. Mine entry
projections shown on the map did not extend to 11 Headgate where the 2 Section
mining operations were being conducted. The primary and alternate escapeways were
not shown extending into 11 Headgate.
Section 75.333(c)(2) requires all personnel doors in stoppings along escapeways to be
clearly marked so that the doors may be easily identified by anyone traveling in the
escapeway and in the entries on either side of the doors. Reflective “mandoor” signs
were hung from the mine roof in the intake entry adjacent to the NEM belt entry. These
signs identified locations of some personnel doors in stoppings that separated the
primary escapeway in the NEM intake air course from the NEM belt entry. Not all
personnel door locations were marked with the reflective signs. No sign was found to
identify the location of the personnel door installed in the crosscut between the primary
escapeway and the alternate escapeway in the NEM belt entry at SS 3230. This is the
personnel door through which miners evacuating from 2 Section crossed from the
primary escapeway to the alternate escapeway.
Removal of permanent stoppings located inby SS 3249 eliminated the separation
between the No. 7 Belt entry and the primary escapeway for 2 Section. Holes existed in
numerous stoppings located between the 2 Section primary escapeway and the NEM
No. 1 Belt entry. These missing stoppings and holes compromised the separation
between the No. 7 Belt entry and the primary escapeway for 2 Section.
9 Headgate Longwall Section Escapeways
The primary escapeway route for the longwall section was clearly marked with green
reflective tags in the No. 1 Entry intake air course of 9 Headgate, through the cut
through at SS 3305, and into the North West Mains.
58

 On January 19, 2006, there was no alternate escapeway route marked or maintained
underground to show the route and direction of travel from the longwall section to the
surface. On the escapeway map posted at the surface location where miners
congregated, the alternate escapeway route was shown in the No. 3 Entry of
9 Headgate, continuing in a direct line across the NEM entries to the NEM belt entry.
This had been the 9 Headgate belt entry during the development of 9 Headgate. The
alternate escapeway was shown on the map posted at the surface location to be routed
through solid permanent stoppings at the junction of 9 Headgate and NEM. The
depicted escapeway then intersected and crossed the primary escapeway for 2 Section.
The two depicted escapeways were not separated by an overcast. An image of the
escapeway map that was readily accessible to all miners on the longwall section is
shown in Appendix T. On the escapeway map maintained on the longwall section that
was readily accessible to the miners, the alternate escapeway route was also shown in
the No. 3 Entry of 9 Headgate, but terminated at the intersection with the entries in
NEM. An escapeway route was depicted as a primary escapeway from the point of
termination in 9 Headgate to the NEM belt entry. Amber reflective tags were not found
in the 9 Headgate entries to show the route and direction of travel. The escapeway
routes depicted on the escapeway maps to serve as the alternate escapeway for the
9 Headgate longwall section did not meet the regulatory requirements for an
escapeway.
Escapeway drills were not conducted at proper intervals, were
not rotated between the primary and alternate escapeway, and
did not follow the designated routes.
Escapeway Drills
Records of fire drills and escapeway drills for miners at Aracoma Alma Mine #1 were
maintained in Fire Drill and Escapeway Record Books. A review of the records
revealed the frequency of the practice escapeway drills did not always meet the 90-day
maximum interval requirement during the 12-months prior to January 19, 2006. In
addition, practice escapeway drills conducted during the 12 months prior to January 19,
were not always rotated between the primary and alternate escapeways. Mine records
indicated that some of the miners working on 2 Section (2 Section miners) on the
afternoon shift of January 19, had participated in 6-week practice escapeway drills in
the alternate escapeway during the 90-day period preceding the accident. However,
these same records indicated that not all of the 2 Section miners were afforded the
opportunity to participate in a practice escapeway drill during that 90-day period.
Interview statements from 2 Section miners revealed information about escapeway
drills in which they participated. Some 2 Section miners indicated participation by the
entire 2 Section crew in an escapeway drill sometime during the weeks prior to the
59

 January 19, 2006, fire. The escapeway drill described was held in the primary
escapeway and included riding a mantrip in the NEM roadway from 2 Section, through
the sets of equipment doors at the 9 Headgate longwall belt drive area, to the 3-Way in
North West Mains. The remainder of the primary escapeway to the surface was
traveled on foot. Interview statements of some 2 Section miners indicated they
recognized the route traveled during that escapeway drill diverted from the primary
escapeway when they rode on the mantrip through the sets of equipment doors at the
longwall belt. These miners stated they knew the primary escapeway passed over the
overcast located outby the equipment doors. A proper practice escape drill should have
followed the actual designated escapeway which diverted from the roadway north of
the equipment doors and continued in the NEM intake. If the drill had been conducted
properly, the miners would have then been required to exit the mantrip and walk over
the overcast at SS 3221.
Mine Examinations
The regulations require preshift and on-shift examinations (§ 75.360 and § 75.362) and
weekly examinations (§ 75.364) and provides for supplemental examinations (§ 75.361).
Requirements regarding hazardous conditions are specified in § 75.363. The regulations
address posting, correcting, and recording hazardous conditions and recording
corrective actions. All hazardous conditions, regardless of when detected or by whom,
must be adequately addressed. Proper examinations and records serve as a history of
the types of conditions that can be expected in the mine. When properly reviewed,
mine management can determine if the same hazardous conditions are of a recurring
nature and whether or not corrective actions have been effective. The mine foreman
must be fully aware of the information contained in records of examinations so as to be
able to allocate resources to correct safety problems as they develop.
Some examples of hazardous conditions that would be expected to be observed,
recorded, and corrected include but are not limited to: loose roof and ribs; excessive
levels of methane; oxygen deficiency; damaged or improperly installed ventilation
controls; a lack of proper separation between air courses where required; accumulations
of loose coal, coal dust or other combustible materials; inadequate rock dust; misaligned
belts causing damage to belt structure or other belt system components; damaged
and/or hot belt rollers and bearings; smoldering embers; hot materials producing
smoke and/or open flames; and a change in air direction that could materially affect the
safety and health of the miners. If a determination is made by the mine examiner that
air is not moving in its proper direction, the results of that determination must be
recorded and corrective action must be taken. Certified persons conducting
examinations that required a determination of whether or not air was moving in its
proper direction must know the proper direction of the airflow in the area examined.
Section 75.360(b) requires persons to examine for hazardous conditions, test for
methane and oxygen deficiency, and determine if the air is moving in its proper
60

 direction. The locations where the preshift examinations are to be conducted are also
specified in the regulations and include roadways, travelways, working sections, areas
where mechanized mining equipment is being installed or removed, underground
electrical installations, and other areas where work or travel during the oncoming shift
is scheduled prior to the beginning of the preshift examination.
Section 75.362(b) requires during each shift that coal is produced, a certified person
examine for hazardous conditions along each belt haulageway where a belt is operated.
This examination may be conducted at the same time as the preshift examination of
belts and belt haulageways.
Section 75.361 requires an examination within 3 hours before anyone enters an area in
which a preshift examination has not been made for that shift. The certified person
conducting the examination is to examine for hazardous conditions, determine whether
the air is traveling in its proper direction and at its normal volume, and test for methane
and oxygen deficiency.
Section 75.364(b) requires at least every 7 days, among other specifics, an examination
for hazardous conditions be made at the following locations: in at least one entry of
each intake air course and return air course, so that each entire air course is traveled in
its entirety; and in each escapeway so that the entire escapeway is traveled. The weekly
examination may be conducted at the same time as preshift or on-shift examinations
conducted for the same area. No separate record of the concurrently conducted weekly
examination is required.
Section 75.351(n) requires at least once each shift when belts are operated as part of a
production shift, sensors used to detect carbon monoxide or smoke in accordance with
§ 75.350(b), and § 75.350(d), and alarms installed in accordance with § 75.350(b) must be
visually examined. MSHA explains in the preamble of the final rule this examination
would typically be made during preshift or on-shift examinations, although a separate
examination is permitted.
Section 75.512 requires that electrical equipment is to be examined, tested, and properly
maintained by a qualified person to assure safe operating conditions. Section 75.512-2
requires these examinations and tests to be made at least weekly.
Mine examiners failed to identify obvious hazards in the mine
and deficiencies in safety systems which contributed to the
severity and extent of the mine fire.
The purpose of examinations is to identify hazardous conditions and make corrections
to maintain a safe working environment. The preamble to the final rule for § 75.364
explained that the weekly examination is directed at hazards that develop in the more
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 remote and less frequently visited areas of a mine, including intake and return air
courses. Because of the confined nature of the underground mining environment, loss
of life can result in other areas of the mine outside the immediate location of the hazard.
The weekly examination assures these hazards are located and corrected.
MSHA investigators reviewed mine records to determine if required examinations were
conducted, the types of hazards identified during those examinations, and corrective
actions taken to correct hazards. The results of examinations were recorded in
designated mine record books. Not all mine examination records requested by MSHA
investigators were available for review. A representative of the mine operator
responded to the requests by stating the record books that were not provided did not
exist.
Accumulations of combustible materials along the longwall
belt were not identified and corrected, nor properly recorded in
mine record books.
Preshift and On-shift Examinations
9 Headgate Longwall Belt
MSHA investigators recorded the conditions found in the longwall belt entry during
the investigation. The following hazardous conditions, which were determined to be
present at the time of the January 19, 2006, mine fire, were not identified by the mine
examiners:
•

Accumulations of combustible material were present in the form of grease, oil,
coal dust, coal fines, and loose coal spillage at numerous locations along the
approximate 2,000 feet length of the 9 Headgate longwall belt;

•

Damaged bottom rollers, bottom rollers on the ground with indications they had
been rotating in combustible material on the mine floor, and damaged top
rollers;

•

Damaged and missing trip latch lever posts and damaged drop-off carriage
assembly trip latch levers that affected positioning of the drop-off carriage within
the 9 Headgate longwall belt takeup storage unit;

•

Air in the 9 Headgate longwall belt entry was not traveling in the direction
specified in the approved mine ventilation plan;

62

 •

No fire suppression system of any type, which would actuate in the event of a
rise in temperature, was provided for the belt takeup storage unit and electrical
components; and

•

Fire hose outlet valves near the longwall belt tailpiece were not provided with
handles to actuate.

There were also several indications of prolonged operation of the longwall belt system
while the belt was misaligned, including:
•

Damaged belt hangers, some partially cut through and others severed from
prolonged rubbing from the misaligned belt;

•

Damaged belt takeup storage unit frame components, partially cut through from
prolonged rubbing of the misaligned belt (See Figure 13);

•

Severed strips of belt on the mine floor and hanging on belt structure;

•

Lengths of partially severed strips of belt;

•

Shavings of belt on the mine floor;

•

Belt cord fibers wrapped around belt roller components; and

•

Extended lengths of belt with frayed edges.

Figure 13. Grooves cut into the rear frame assembly.

The last record of an examination of the longwall belt was for the preshift examination
conducted by the belt examiner on the day shift of January 19, 2006. The belt examiner
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 did not sign or initial the record book by or at the end of the shift for the examinations
listed in that report. Physical evidence and interview statements revealed the
examination was inadequate: the examination was not complete and hazardous
conditions that were determined to have existed at the time of the examination were not
recorded. Although the examination record indicated air was moving in the right
direction with a velocity of greater than 50 fpm, the belt examiner revealed he did not
make airflow direction determinations, nor air velocity measurements (he was not
provided with an anemometer or other means to measure the air velocity) during his
examinations of the belt entries and was not able to identify the proper airflow direction
in the longwall belt entry. In addition, interview statements revealed that not all
examiners were provided adequate gas detection equipment on all shifts.
Dual Switch House Installation Project
Physical evidence and interview statements revealed a stopping had been constructed
in the No. 7 Belt entry between SS 3266 and the next inby crosscut intersection.
However, there was no stopping in that location on January 19, 2006. This stopping
was removed during the last week of October 2005, by a construction crew to facilitate
installation of a dual switch house in the crosscut where the electrical installation for the
longwall belt drive and takeup storage unit near SS 3266 was located.
Construction reports were prepared for mine superintendent Lawrence Lester by Don
Hagy, outby construction foreman, to report work completed by the construction crew
Hagy supervised. A construction report revealed that a scoop was used to take the dual
switch house from the No. 2 “4-Way” to 9 Headgate on October 26, 2005. The report
also revealed the high voltage cable for the dual switch house was installed and two
ends connected.
To facilitate installation of belt structure through the entry at a later date, a framed
curtain was installed instead of re-constructing the removed stopping. Interview
statements indicated other mine officials were aware the stopping had been removed
and needed to be reconstructed.
Interview statements from Hagy indicated there was no production inby that location at
the time the stopping was removed. Mine records revealed 2 Section had completed
mining in 10 Headgate and was being moved to the NEM on October 25, 2005. No
entries for preshift or on-shift examinations conducted on 2 Section were found for the
period from October 26 through November 5, 2005. Mine records showed that preshift
examinations for 2 Section resumed on the afternoon shift of November 6, 2005. The
section had been moved to NEM and ventilation was being established. Preshift and
on-shift examination records indicate production on 2 Section resumed in the NEM on
November 7, 2005.

64

 An entry in the Examination of Electrical Equipment record book for 2 Section revealed
the section had been moved from October 25 through October 28, 2005. Another entry
in the record book indicated the 2 Section feeder and center shuttle car were located in
the NEM when it was examined on November 1, 2005.
Mine production records revealed 2 Section equipment in 10 Headgate was being
moved on the afternoon shift of October 24, 2005. The first mine production records for
2 Section in NEM indicate production began on day shift November 7, 2005.
Results of pre-shift and onshift examinations for construction work were entered into
the Pre-shift – Onshift and Daily Report record books maintained for that purpose.
Record books for the period prior to November 9, 2005, were not provided by the mine
operator.
Mine records indicated that mechanized mining equipment was being removed from 10
Headgate and installed in a new location in NEM inby 10 Headgate. Both areas were
inby the No. 7 Belt tail pulley at the time the stopping was removed. Two separate and
distinct escapeways were required for both 10 Headgate and the projected new section
in NEM. These escapeways were required to be separated from the No. 7 Belt entry.
No. 7 Belt and Underground Electrical Installations for the
9 Headgate Longwall Belt Drive and Takeup Storage Unit
The last record of an examination by the belt examiner of the No. 7 Belt was for the
preshift examination conducted on the day shift of January 19, 2006. Observations
made underground by the MSHA accident investigation team and interview statements
from the miners established the examination was inadequate; the examination was not
complete; hazardous conditions that were determined to have existed at the time of the
examination were not recorded; and the examination was not conducted during the
required time period.
The belt examiner who conducted the examination stated he was aware no stopping
existed immediately inby the No. 7 Belt tail roller to separate the No. 7 Belt entry from
the belt structure that had been installed in preparation for the extension of that belt.
He knew the stopping across that entry, approximately 150 feet inby the No. 7 Belt tail
pulley, had been removed. The belt examiner was also aware a stopping had been
removed from the crosscut inby the No. 7 Belt tail roller in which the longwall belt
electrical installations were located. As previously stated, the stoppings the examiner
knew were missing were necessary to provide separation between the 2 Section primary
escapeway and the No. 7 Belt entry.
Further, the last record of an examination of the No. 7 Belt was not signed or initialed
by the examiner. The examination was not complete, and hazardous conditions that
were determined to have existed at the time of the examination were not recorded. The
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 examination record indicated air was moving in the right direction with a velocity of
greater than 50 fpm. However, the belt examiner stated he did not make airflow
direction determinations or air velocity measurements, and was unable to identify the
proper airflow direction in the No. 7 Belt entry. Interview statements revealed the air
that ventilated the No. 7 Belt entry traveled beyond the belt tail and into the intake air
course, continuing toward 2 Section, on the afternoon shift of December 29, 2005, the
date on which another fire occurred.
The record book indicated an examination of underground electrical installations for
the 9 Headgate longwall belt drive and takeup storage unit was conducted as part of
the preshift and on-shift belt examination for January 19, 2006.
No. 7 Belt Structure Extension Project
The NEM roadway passed through the intersection at SS 3223. Belt structure for the
No. 7 Belt extension was installed from the SS 3223 intersection outby toward
9 Headgate and inby toward 10 Headgate. The specific work locations and components
installed depended on the materials available at the time. The exact date on which the
belt structure for the extension of the No. 7 Belt between SS 3266 and the intersection
with the next crosscut was installed could not be determined. However, observations
made during the investigation, mine construction reports, and interview statements
provided relevant information. The framed curtain was removed and belt structure
installed from the point between SS 3266 and the next inby crosscut.
Hagy, who supervised the construction crew that removed the stopping, observed its
removal. Two additional mine management officials, Shadd and Herndon, reportedly
were also aware the stopping had been removed. Reportedly, Shadd discussed the
need to rebuild the stopping with Hagy in the presence of Herndon. These
conversations reportedly occurred soon after the stopping was removed and prior to
Hagy voluntarily terminating his employment at the Aracoma Alma Mine #1 the last
week of October 2005.
The last construction report prepared in October 2005 by Hagy was dated October 27,
2005. That construction report revealed six crosscuts of waterline were laid out in the
entry where the No. 7 Belt was being extended, 12 crosscuts of belt chains were hung,
and one load of top belt structure was brought in, among other work. That report
contained no record of the installation of the belt structure, nor a specific location where
this work was done.
Hagy returned to employment at Aracoma Alma Mine #1 approximately one week
later, in November 2005. In interview statements, Hagy recalled he had asked about the
installation of the belt structure in that area while riding into the mine with the
construction crew on the day he returned to work. He was informed by members of the

66

 construction crew riding with him the work had been completed in that area and to
continue work in the 10 Headgate area.
Hagy stated he conducted on-shift examinations only in the areas where his
construction crew worked. Preshift examinations for the day shift construction crew
were conducted during the preceding shift in areas where the crew was scheduled to
work. Hagy stated he did not conduct examinations in the area where the stopping was
removed after returning to Aracoma Alma Mine #1 in November 2005. The first
construction report, dated in November 2005, was prepared by Hagy for work
performed on November 5, 2005. No construction reports were provided by the mine
operator for October 28 through November 4, 2005. Correspondence between MSHA
and the mine operator’s representative indicated that no other construction related
reports were in the possession of the mine operator.
Construction reports indicated 72-inch belt structure was installed on several days
during November and December 2005. However, the reports lacked sufficient detail as
to enable determination of the exact location of the installed structure. The extent of the
72-inch belt structure installed prior to the accident on January 19, 2006, is shown in
Appendix C.
The results of the pre-shift and on-shift examinations conducted for construction work
were entered into the Pre-shift – Onshift and Daily Report mine record books
maintained for that purpose. Records of the pre-shift and onshift examinations
conducted for construction work from November 9, 2005, through January 19, 2006,
were reviewed by MSHA accident investigators. Construction work reports were not
provided to MSHA for all of the dates on which records indicated that pre-shift and
onshift examinations were conducted in this area. Some of the examinations recorded
in the Pre-shift – Onshift and Daily Report mine record books maintained for the
construction work were made during timeframes that indicate they were supplemental
examinations. Preshift–onshift examination mine record books for the period prior to
November 9, 2005, were not provided by the mine operator. Correspondence between
MSHA and the mine operator’s representative indicated that no other construction
related record books were in the possession of the mine operator.
The preshift or supplemental examinations required before allowing miners to work in
this area were inadequate. Corrective actions were not taken for the hazardous
condition created by the absence of the stopping necessary to provide separation
between the primary escapeway for 2 Section and the No. 7 Belt Entry.
Roadway from NEM to 2 Section
The pre-shift and on-shift examinations of the NEM roadway were recorded in the Preshift – Onshift and Daily Report record book identified as “Travelways.” The record
book indicates the last examination of the NEM roadway prior to the accident was
67

 conducted on the day shift of January 19, 2006. The record book indicates that no
hazards were observed. The record book also indicates Shadd and Edward Ellis
phoned the examination outside to Plumley and Runyon. The person(s) who examined
individual areas identified in the record book did not initial or sign the record book.
The examination of the NEM roadway was inadequate. Hazardous conditions that
existed at the time of the examination were not identified in the record book. The
location of all personnel doors along the primary escapeway were not clearly marked so
that the doors could be easily identified by anyone traveling in the escapeway and in
the entries on either side of the doors. The lack of separation between the No. 7 Belt
entry and the 2 Section primary escapeway was not identified, and the sets of
equipment doors located between SS 3267 and SS 3333 were not installed to form an
airlock.
Weekly Examinations
A mine map identified as “Air-Way Map Weekly Fireboss,” which depicted the weekly
examination routes, was obtained from the mine superintendent’s office. The map
showed the route of travel for air course examinations and was color coded indicating
which routes were traveled each day of the week, Monday through Friday. Some of the
evaluation points approved in the mine ventilation plan for the evaluation of the
bleeder systems in the mine were also color coded. Interview statements revealed John
McNeely, airway walker, conducted weekly examinations of air courses on the day
shift. McNeely stated the air courses he examined did not include the belt air courses.
He also stated he observed the ventilation controls along his route of travel.
Results of the weekly examinations were entered into the Weekly Examinations for
Methane and Hazardous Conditions mine record books maintained for that purpose.
Records of the weekly examinations conducted between the week ending November 12,
2005, and the week ending January 21, 2006, were reviewed by MSHA accident
investigators. Initials of the examiners were entered beside air courses listed in the
record books. The initials indicated McNeely conducted most of the recorded
examinations. The weekly examination records were inadequate because dates for each
specific air course examination were not recorded. It could not be determined from the
mine record books whether or not the examinations were conducted in the listed air
courses and at the listed evaluation points every seven days as required.
Not all air courses were listed in the weekly examination record book. Some of these air
courses were routinely examined during preshift examinations. The air courses listed
in the weekly examination record books were not all clearly described. Not all
approved evaluation points were listed as examined in the weekly examination record
books, nor were all the missing examinations of evaluation points found in any other
mine examination record books. Some of the required weekly examinations of air

68

 courses and evaluation points had not been conducted for an extended period of time
prior to the accident.
Intake Air Courses and Primary Escapeway for 2 Section
There were no examination records that specifically identified the area examined as the
2 Section primary escapeway. The primary escapeway for 2 Section extended from
2 Section through the multiple-entry intake air course in NEM and North West Mains to
the intersection of the No. 2 Cut-Through, where it met the primary escapeway for the
longwall section. An examination of the primary escapeway for 2 Section could have
been conducted during the examinations of the intake air course in NEM and in the
North West Mains from the inby No 2 Cut-Through to NEM, or in combination with
preshift examinations of the roadway in this area. Mine records and interview
statements revealed examinations of the primary escapeway for 2 Section were
inadequate.
Multiple primary escapeway routes in NEM were marked with green reflective tags.
The primary escapeway route marked with the greatest number of green reflective tags
in NEM followed the roadway from 2 Section to the equipment doors located inby the
longwall belt. The primary escapeway reflective tags did not follow the roadway
through the equipment doors, but diverted from the roadway through a crosscut at SS
3333 in a northwest direction. A miner evacuating via this route and continuing in the
direction indicated by the reflective tags would have encountered the 72-inch belt
structure installed in the entry adjacent to the roadway. This belt structure was an
obstruction to a miner evacuating via this route. The route marked with green
reflective tags continued across the overcast at SS 3221 and then rejoined the roadway
on the southwest side of the pair of equipment doors located outby the longwall belt
drive. There was no documentation or indication the portion of the primary escapeway
for 2 Section, from the roadway intersection at SS 3333 for a distance of two crosscuts
toward SS 3262, was examined weekly.
The primary escapeway route marked by green reflective tags continued into the North
West Mains and on to the surface at the Box Cut Portal. Two routes were marked with
green reflective tags as the primary escapeway in North West Mains from NEM to the
No. 2 Cut-Through. Based on interview statements of the mine examiner, it was
determined not all routes marked with green reflective tags as escapeways were
traveled during the weekly examinations of the intake air course.

69

 Weekly examinations did not identify the lack of separation
between the No. 7 Belt air course and the 2 Section primary
escapeway.
The examinations failed to identify the following hazards: the lack of separation
between the No. 7 Belt and the 2 Section primary escapeway; holes that existed in
stoppings that separated the NEM belt entry from the 2 Section primary escapeway; the
lack of a clearly marked alternate escapeway for 2 Section; and the location of all
personnel doors along the escapeway were not clearly marked so that the doors could
be easily identified by anyone traveling in the escapeway.
No. 7 Belt Air Course
Because the No. 7 Belt Air Course (BAC) is an intake air course, a weekly examination
for hazardous conditions was required by § 75.364(b)(1). This section requires
examination of the air course in its entirety. Pre-shift and on-shift examinations of the
belt would not typically cover the entire BAC, but only the portion along the belt
conveyor or belt conveyor haulageway. There were no weekly examination records
that specifically identified the area examined as the No. 7 BAC. It is likely that the
weekly examination of portions of this BAC was conducted concurrently with the preshift and on-shift examinations of No. 7 Belt conveyor.
In § 75.301, the belt air course is defined as “The entry in which a belt is located and any
adjacent entry(ies) not separated from the belt entry by permanent ventilation controls,
including any entries in series with the belt entry, including any entries in series with
the belt entry, terminating at a return regulator, a section loading point, or the surface.”
At the time of the fire, and for weeks prior to the fire, the air passing through the No. 7
Belt entry was moving either into the longwall belt entry, or past the No. 7 Belt tail into
the 2 Section intake and on to 2 Section. The No. 7 Belt air course would have
terminated at the 2 Section loading point by definition.
It could not be determined from mine records if the No. 7 BAC was examined in its
entirety. If the mine operator used pre-shift and on-shift examinations to comply with
weekly examination requirements, which covered only the portion of the BAC
containing the belt conveyor, the examinations were inadequate because the BAC was
not examined in its entirety. If the No. 7 BAC was examined in its entirety, the
examinations were inadequate because the examiner failed to identify the hazardous
condition of the lack of separation between the No. 7 Belt air course and the 2 Section
primary escapeway in NEM. This condition existed from November 2005, to the time of
the fire on January 19, 2006.

70

 Intake Air Course and Primary Escapeway for 9 Headgate Longwall Section
There were no records of examinations that specifically identified the area examined as
the longwall section primary escapeway. The primary escapeway for the longwall
section was located in the single entry intake air course through which intake air was
directed to the longwall section. The escapeway would have been traveled to the North
West Mains intake air course during an examination of the longwall section intake air
course.
The last record in the weekly examination record book of an examination of the
longwall intake air course was for the week ending January 14, 2006. No specific date
was noted on which the examination was conducted. The map labeled “Air-Way Map
Weekly Fireboss” indicated the longwall intake air course was to be examined on
Thursdays. Interview statements of the mine examiner along with entries in the weekly
examination record book revealed the longwall intake air course had not been
examined on Thursday, January 19, 2006. The examiner stated the examination was not
conducted because he spent most of the shift repairing his personnel carrier. No record
indicated an examination of the longwall intake air course occurred during the week
ending January 21, 2006.
Alternate Escapeways for 2 Section and 9 Headgate Longwall Section
There were no records of examinations that specifically identified the area examined as
either the 2 Section alternate escapeway or the 9 Headgate alternate escapeway. The
map labeled as “Air-Way Map Weekly Fireboss” did not show a weekly examination
was to be conducted in either of the alternate escapeway routes depicted on the
escapeway maps. The escapeway maps for 2 Section depicted the portion of the
alternate escapeway route in NEM to be in the 2 Section and NEM belt entries. The
only recorded examinations in which the weekly examination for the 2 Section alternate
escapeway could have been conducted were the pre-shift and onshift examinations of
the NEM and 2 Section belts.
Preshift/Onshift Daily Reports record books from January 1 through January 19, 2006,
for the NEM belt entry were reviewed. The Preshift record indicated the belt entry
routinely needed to be cleaned and dusted. There were no additional violations or
hazardous conditions recorded. Holes that existed in stoppings that separated the NEM
belt entry from the 2 Section primary escapeway were not identified as hazardous
conditions. No notations were found in mine examination records that indicated
examiners identified the lack of a clearly marked alternate escapeway for 2 Section nor
that the location of all personnel doors along the escapeway were not clearly marked so
that the doors could be easily identified by anyone traveling in the escapeway.
No amber reflective tags were observed in 9 Headgate to mark any route as the
alternate escapeway from the 9 Headgate longwall section. No examination records
71

 indicated an examination had been conducted in the route identified on escapeway
maps as the alternate escapeway for 9 Headgate longwall section. Underground
observations made by the accident investigation team, revealed no separate and distinct
alternate escapeway had been provided for the 9 Headgate longwall section.
9 Tailgate Air Course
The 9 Tailgate multiple entry intake air course, ventilated with intake air from the NEM,
was located between the NEM and 4 Right. The longwall tailgate entry in this air
course, from the NEM to the longwall face at 17 crosscut, was identified on the Airway
Map for Weekly Fireboss as a route examined on Tuesday. At the time of the fire, the
longwall section tailgate entry could not be safely accessed from the longwall face due
to adverse roof conditions.
Results of the examinations at EP-3 and EP-20 evaluation points, located in the 9
Tailgate entries were recorded in the weekly examination record book dated December
24, 2005 through January 21, 2006. There were no hazardous conditions recorded as
being observed for this period of time. A notation indicated air moved in the right
direction. It was determined air entered the 9 Tailgate intake air course from the NEM
thru a small hole in a stopping located between SS 3208 and SS 3268 and as leakage thru
the set of equipment doors located between SS 3193 and SS 3182 and an uncoated
stopping located near SS 3197. Pieces of curtain were hung over the set of equipment
doors and uncoated stopping to reduce the amount of air leakage through those
ventilation controls. The equipment doors were not installed in pairs to form an airlock.
These hazardous conditions were not identified by the mine examiners.
Fire Protection
Fire protection at the Aracoma Alma Mine #1 consisted of a freshwater supply and
associated distribution piping, valved firehose outlets (VFOs), firehoses, and various
fire suppression systems on equipment and in specific areas. For the belt drive areas,
the mine operator installed automatic fire (water) sprinklers as the fire suppression
system.
Water Supply System
The Aracoma Alma Mine #1 freshwater supply provided water for fire protection, dust
control, and other related water needs. The system was gravity-fed with the pressure
head supplemented by freshwater pumps. The water supply tank was located on the
surface above the Box Cut and the freshwater pumps were located underground. The
underground freshwater supply system is depicted in Appendices O and P.

72

 Freshwater Supply Tank
The freshwater supply tank was constructed of steel and had a nominal capacity of
100,000 gallons. This tank was a vertical cone roof tank with a circumference of
approximately 85 feet. The sides were constructed of three 8-foot high steel rings
stacked and welded on top of each other to form the cylindrical portion of the tank. The
total vertical height of the side was 24 feet, with approximately two additional feet of
height for the cone roof.
The tank was provided with a 12-inch diameter steel outlet pipe connected to the side of
the tank approximately two feet above the tank bottom. This piping included welded
steel joints and supplied water to the underground workings through the Box Cut. The
tank was also provided with a 6-inch overflow pipe connected to the side of the tank
approximately three feet below the top of the tank. The overflow discharged to
atmosphere near tank grade level. The combined effect of the outlet pipe and overflow
pipe limited the usable storage volume of the tank to approximately 80,000 gallons.
Freshwater Distribution Piping
The outlet pipe from the tank was provided with an outside screw and yoke shutoff
valve (OS&Y) near the tank. From the OS&Y valve, the line was buried and exited the
ground at the top of the Box Cut. It was supported vertically down the side of the Box
Cut.
At the bottom of the Box Cut, the steel freshwater pipe was reduced to an 8-inch Polyvinyl Chloride (PVC) plastic pipe and equipped with a sliding gate shutoff valve. The
PVC piping was standard dimensional ratio (SDR) piping. The SDR number identified
the wall thickness, and thus the pipe pressure rating and friction loss characteristics.
The higher the SDR number, the thinner the wall thickness and the lower the pressure
rating.
All PVC piping examined at this mine during the investigation was SDR pipe. The
majority of piping was blue colored “Aquamine™”, SDR 12.4, with a pressure rating of
350 pounds per squire inch gage (psig). However, there were also a number of sections
of “Yellow Mine™”, SDR 13.5, with a rating of 315 psig. Aquamine is a product of the
Victaulic Corporation, while Yellow Mine is a product of the CertainTeed Company.
The 8-inch PVC waterline in the Box Cut entered the mine through the No. 2 Entry of
the Box Cut Portal. From the portal, the waterline extended approximately 1,700 feet
before entering the North West Mains roadway at SS 737 (No. 2 Entry in the North West
Mains). This waterline extended along the roadway approximately 3,400 feet to SS
1640, where a 4-inch PVC waterline branched off of the 8-inch line and extended to SS
1639 in the North West Mains belt entry. All underground waterlines were laid on the
mine floor except where they crossed roadway entries or roadway crosscuts. At these
73

 locations, the waterline was chained to the mine roof to provide clearance for vehicle
travel.
From SS 1639, the 4-inch PVC waterline split and extended both inby and outby in the
North West Mains belt entry. In the outby direction, the waterline extended all the way
to the Rum Creek portal. This waterline was equipped with VFOs and also supplied
water to automatic fire sprinkler systems installed at the No. 1 through No. 5 Belt
drives. In the inby direction, the waterline extended to SS 1647 where it supplied the
skid-mounted electric pump (No. 2 freshwater pump) located in the crosscut between
SS 1647 and SS 1649.
The 8-inch PVC waterline continued along the roadway approximately 200 feet to SS
1649, where it supplied the skid-mounted electric pump (No.1 freshwater pump)
located in the crosscut between SS 1649 and SS 1654. This pump was provided with an
8-inch bypass line. The 8-inch PVC waterline continued from this pump approximately
1,100 feet along the roadway to SS 1716, where a 6-inch PVC waterline branched off to
supply water to the 9 Headgate longwall section. The 8-inch PVC waterline continued
to SS 2007, near 8 Headgate, where it was connected to the 4-inch PVC waterline in the
North West Mains belt entry. These two waterlines were connected by a shut-off valve
and a check valve. The shut-off valve was found in the closed position and the
orientation of the check valve prevented water flow from the 8-inch waterline to the 4inch waterline. Near SS 1716, a shut-off valve in the 8-inch PVC waterline was found in
the closed position. Due to these conditions, the No. 1 freshwater pump did not supply
water to the area of the mine where the fire occurred.
The No. 2 freshwater pump discharged into a 4-inch PVC waterline that extended along
the North West Mains belt entry from SS 1647 to SS 2885, where it was connected to the
previously discussed 8-inch PVC waterline near SS 2007. At SS 2828, a 4-inch PVC
waterline branched off and extended in the No. 7 Belt entry to 10 Headgate. A 4-inch
butterfly shut-off valve near SS 2828 controlled water flow in this waterline. Near SS
2857, a 4-inch PVC waterline branched off and transitioned to an 8-inch PVC waterline.
A 4-inch butterfly shut-off valve was installed just prior to the transition from 4-inch to
8-inch piping. This 8-inch PVC waterline extended the entire length of the NEM belt
entry, into 11 Headgate where it ended near the 2 Section belt tailpiece.
Water for the 9 Headgate longwall belt was supplied from the 4-inch PVC waterline
that extended along the No. 7 Belt entry. A 4-inch tee near SS 3249 supplied water
through a 4-inch butterfly shut-off valve to a 2-inch PVC waterline that ended near
SS 3320 in the 9 Headgate longwall belt entry (Figure 14). This waterline terminated at
a 2-inch ball valve and was not connected to the longwall section freshwater supply.

74

 Figure 14. 4-inch water valve (found in “off” position)

After the fire, MSHA investigators examined the area of the 4-inch butterfly valve
where it connected to the 2-inch PVC waterline (SS 3249). This valve was visually
examined and found in the closed position. It could not be determined when, or by
whom, the valve had been closed. If this valve was closed at the time the fire started,
water would not have been available in the 2-inch PVC waterline. This is the line Cabell
initially attempted to use to fight the fire.
After the fire, MSHA investigators found that much of the 2-inch PVC waterline along
the 9 Headgate belt drive and takeup storage unit had been destroyed by the fire.
Portions of the 4-inch PVC waterline along the No. 7 Belt in the immediate fire area had
also been destroyed or severely damaged by the fire. Since this destruction occurred
after the fire had become well established, it did not impact the initial efforts to fight the
fire. However, it would have been necessary for mine rescue personnel to isolate this
damaged piping prior to re-establishing the underground water supply to a usable
condition for firefighting.
Underground Freshwater Pumps
Both underground freshwater pumps were constant-speed (3550 rpm), multi-stage
centrifugal pumps driven by 60 hp, 3-phase electric motors. Both pumps were
equipped with pressure-relief valves and check valves on the discharge side of the
pumps, along with shut-off valves on both the suction and discharge sides. The relief
valves were used to adjust the pump discharge pressure by re-circulating some of the
water back to the suction side of the pump piping. The nameplates on both pumps
indicated a rating of 450 gallons per minute (gpm) at a net discharge head of 422 feet
(183 psi). The maximum discharge pressure was listed as 365 psi (843 feet of head).

75

 Both pumps were powered by the underground electrical distribution system that also
supplied power to the continuous mining machine sections (miner circuit). When
power was shut off to the miner circuit, these pumps were de-energized and rendered
inoperable.
Water Supply and Mine Elevations
Waterline elevations play an important role in the performance capability of any water
system, especially for fire protection. Underground mine elevations were shown on
mine maps. The elevation of the freshwater tank was provided by a representative of
the mine operator. Based upon a comparison of the elevation of the freshwater tank
with surface elevation contour lines shown on United States Geological Survey
topographical maps (Logan Quadrangle), it was concluded that coal seam elevations
shown on the mine maps were referenced to mean sea level (MSL).
Information provided by the mine indicated that the bottom of the freshwater tank was
at 814.8 feet MSL. The water level in the freshwater tank, when full, was approximately
836 feet MSL. With the pumps at an elevation of approximately 595 feet MSL, this
would result in a maximum static head pressure underground of approximately 103 psi
on the suction side of the pumps. In the North West Mains, the 4-inch PVC waterline
reached an elevation of 836 feet MSL approximately one crosscut outby of SS 2826.
Operation of the No. 2 freshwater pump was necessary to force water beyond this
location because inby locations were above the freshwater tank elevation. A hydraulic
elevation profile diagram of the water system is provided in Appendix U.
Valved Firehose Outlets
The valved firehose outlets (VFOs) typically consisted of 1-1/2-inch diameter steel pipe
threaded into PVC couplings in the waterlines. The valves on these outlets were 1-1/2
inch brass ball valves with a short pipe nipple threaded into the discharge side of the
valve. Each pipe nipple ended with an exposed male National Pipe Tapered (NPT)
thread. Without special thread adapters, only firehoses equipped with National Pipe
Straight Hose (NPSH) threaded couplings were compatible with these outlets. The
VFOs in the 9 Headgate longwall belt drive and takeup storage unit area were not
equipped with these adapters. Plastic caps or other methods of protecting the pipe
threads were generally not provided on the open end of the VFOs. The spacing
between some VFOs outside the fire area exceeded the 300-foot maximum allowed by
§ 75.1100-2(b).
Firehoses and Connections
Statements of two miners indicated that on separate occasions, they were not able to
connect firehoses to the VFOs near the 9 Headgate longwall belt takeup storage unit.

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 Both a male and female hose coupling were recovered in the longwall belt drive area
near the location of fire origin. These couplings were removed from a fire-damaged red
polymeric coated firehose that was lying on the mine floor. The female coupling was
found to be incompatible with the male 1-1/2 inch NPT threads of the VFO. However,
this same female hose coupling readily connected to a male hose coupling cut with
National Hose (NH) threads. The firehose Cabell attempted to use during the fire was
red in color. However, it could not be determined if the couplings recovered during the
investigation were from the same firehose Cabell attempted to use.
Male NPT threads are the threads normally provided on mine water supply VFOs. In
order to be compatible with the NPT threads on the outlets, each female firehose
coupling must be cut with National Pipe Straight Hose threads (NPSH). The NH
threads found on the recovered couplers are the threads normally used by local fire
departments and are not compatible with mine firehose connections unless special
adapters are used.
Annual Functional Tests
Annual functional tests of fire hydrants (referred to as valved firehose outlets in this
report) and firehoses are required by § 75.1103-11. A record of these tests must be
maintained by the mine operator for at least one year. Though requested, the mine
operator did not produce records to document the required annual functional tests of
fire hydrants and fire hoses. Adequate functional tests would have revealed the threads
of the female coupling on the fire hose were not compatible with the male threads on
the VFO.
Longwall Belt Fire Protection
Primary and secondary belt drives are required to be provided with automatic fire
suppression systems as specified in § 75.1101. This protection can take the form of
deluge-type water spray systems, high expansion foam systems, water sprinklers (a.k.a.
fire sprinklers), or dry chemical systems. The areas requiring protection include at least
50 feet of upper and lower belt (i.e., 50 feet of belt-entry length) for fire resistant belt, the
belt takeup, the belt discharge pulley, gear reducing unit, and electrical controls.
Although § 75.1101-7(b) does not define the location of the 50 feet of belt required to be
protected, guidance is provided in the MSHA Program Policy Manual.
On September 30, 2004, MSHA issued Program Policy Letter (PPL) P04-V-05 indicating
that MSHA considers belt takeup storage units to be a form of takeup and therefore
were required to have automatic fire suppression by virtue of § 75.1101. Storage type
takeup units are commonly found in longwall belt systems. PPL P04-V-05 was reissued
as P06-V-05 on June 21, 2006.

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 At the Aracoma Alma Mine #1, wet pipe sprinkler systems protected the various belt
drives. Pendent sprinklers were installed on threaded cast-iron pipe tees and spaced
approximately seven to eight feet apart. The pipe tees were connected together
utilizing ¾-inch diameter hydraulic hoses in lieu of rigid steel pipe. These hoses were
rubber covered with internal steel braiding and an internal rubber liner. Each sprinkler
system was typically provided with a shut-off valve, strainer, and flow switch.
The extent of sprinkler protection for the longwall belt drive on the No. 9 Headgate
panel is shown in Appendix V. These sprinklers only protected the immediate area of
the belt drive and discharge pulley. The sprinklers for the drive area were connected to
the 4-inch PVC waterline in the No. 7 Belt entry. This connection point was just inby
the longwall belt discharge pulley near SS 3249, and consisted of a reducing tee to
connect the 4-inch PVC waterline to a 1 ½ -inch ball valve controlling water supply to
the ¾-inch sprinkler system hoses.
After the fire, the 1-1/2-inch ball valve controlling water flow to the longwall belt drive
sprinkler system was under debris from a roof fall. Because of this debris, along with
the instability of the overhead mine roof, it could not be visually examined by MSHA
investigators. Later, on May 17, 2006, during the recovery of this area, investigators
from the WVMHS&T recovered this valve and took it into custody. On May 23, 2006,
the investigators transferred custody of the valve over to MSHA. This valve was in the
closed position at that time. The investigators from WVMHS&T reported that this was
the position they had found the valve in when they initially recovered it.
Although the outer jackets over the metal braiding of the hydraulic hoses on the system
had been completely burned away, the remainder of the hose assembly components,
including the steel braiding, pipe fittings, and remnants of the sprinklers were still
visible. It could not be determined whether or not the system was operational prior to
the fire. The majority of the sprinklers on the system were visible during the
investigation. All of those observed had missing thermal elements, probably melted by
the fire. Many also had the frames themselves partially eroded or melted away.
An examination of the fire area also revealed that neither automatic fire sprinklers nor
any other form of fixed fire suppression had been installed over the belt takeup storage
unit. There was no evidence of sprinklers, hoses, pipes, or fittings anywhere along the
belt takeup storage unit, including the end of the unit nearest the longwall section (Rear
Frame Assembly). Interview statements also indicated that no fire suppression system
was installed on the belt takeup storage unit as required.
Conveyor Belt Flame Resistance Testing
Flame testing of conveyor belting is conducted in accordance with § 18.65. Conveyor
belt materials meeting the requirements of § 18.65 are accepted by MSHA as flame

78

 resistant. All conveyor belts used in underground coal mines are required by § 75.1108
and § 75.1108-1 to meet these requirements.
Two belt samples were obtained during the mine fire investigation. One belt sample
was collected from the 72-inch wide No. 7 Belt and the second sample was collected
from the 60-inch wide longwall belt. The longwall belt sample was collected near the
belt takeup storage unit. Both samples were collected as close to the fire area as
practical, but far enough away from the fire area that the samples had no visible signs
of fire or heat damage
On June 13, 2006, the two belt samples were visually examined and then subjected to
flammability tests. Samples from both belts passed the criteria established for the flame
test. Information relative to the belt and flame tests is included in Appendix W.
Area of Fire Origin and Flame Propagation
Fire is a destructive process that often damages or destroys vital clues and evidence that
would otherwise simplify determination of the fire cause. Hose streams and other fire
fighting efforts can also sometimes destroy vital clues. Therefore, many factors must be
considered in determining the cause of a fire.
The fire at the Aracoma Alma Mine #1 on January 19, 2006, started in the 9 Headgate
belt takeup storage unit area, specifically in the vicinity of the pulley carriage assembly
(PCA). This conclusion was based upon both eyewitness interview statements and was
confirmed by the accident investigation team.
Determining the point of origin of any fire requires taking into account a number of
factors. These factors include, but are not limited to, the following: 1) the dynamics of
fire plumes and hot gas layers; 2) the physical arrangement and response-to-fire
properties of all materials in the area; 3) the arrangement, or lack thereof, of any
enclosure or construction features capable of impeding or encouraging fire spread; and
4) the extent and direction to which heat and smoke spread.
In general, the established and proven practice for determining the origin of a fire is to
start at the outer extent of fire damage and smoke spread, and follow the increasing
intensity of fire damage toward the area or point of origin. This approach is applicable
because the observed effects of fire intensify as one gets closer to the origin. Examples
of where this approach requires modification include incendiary fires with multiple
points of origin, and in fires that burn to completion where all combustibles are
completely consumed. Although the fire was intense, not all combustibles were
consumed, as evidenced by remnants of unburned and partially burned belt in the fire
area.

79

 Under conditions where a fire is beneath a level mine roof, and where there is 1) limited
air movement from mechanical ventilation, 2) a lack of obstructions or barriers that
would impede fire-driven air movement due to buoyancy effects, and 3) sufficient
availability of combustible materials, fire spread would be expected to occur equally in
all directions. However, in the area of the 9 Headgate longwall belt drive and takeup
storage unit, a number of factors strongly influenced fire spread. These factors included
the slope of the entry where the fire occurred, the effects of the missing stoppings, and
the continuity of readily available combustibles along the longwall belt entry. These
conditions significantly influenced the direction of fire spread. When combined with
other specific observations, including damage to the belt structure, these conditions
provided “vectors” that helped track the fire spread back to the area of origin.
Observations
Appendix X identifies the approximate extent of observed heavy soot deposits and the
approximate extent of heavy thermal damage, much of it attributed to direct flame
exposure and burning. Heavy soot deposits are the result of exposure to smoke for
extended periods of time. However, smoke traveled beyond areas with heavy soot
deposits, continuing downwind until it exited the mine. The most severe areas of fire
damage occurred within the 9 Headgate longwall belt drive and takeup storage unit
area and the adjacent area of the No. 7 Belt entry. Heavy soot deposits are the results of
exposure to smoke for extended periods of time. However, smoke traveled beyond
areas of heavy soot deposits downwind until it exited the mine.
The suspended longwall belt structure between the PCA and the drive structurally
failed and collapsed during the fire. The collapsed belt structure fell onto the mine floor
or onto other materials below, including the mantrip parked in the roadway by
Callaway. Heat from the fire caused the steel chains suspending this belt structure from
the roof to stretch and break.
Observations indicated the longwall belt entry from the PCA to the No. 7 Belt entry was
exposed to intense flame. Inby the PCA, a nearly level soot line was visible, beginning
at the mine floor, rising along the ribs of the sloped entry until it reached the mine roof
near the Rear Frame Assembly (RFA) at the back of the takeup storage unit. Soot was
not visible on the ribs below the level soot line. The soot line indicated the fire traveling
toward the RFA was of limited intensity and did not travel toward the longwall section
beyond the RFA.
Fluorescent light fixtures vertically mounted on the upper portion of the rib along the
takeup storage unit intersected this soot line. Above the soot line, damage to these
fixtures indicated they had been exposed to substantial heat. The plastic lens portion of
the fixtures above the soot line were melted or burned, and the metal cases had paint
burned off or blistered. These observations provided strong evidence this soot layer

80

 was part of a hot gas layer typically associated with a well established nearby flaming
fire.
Belt Entry Slope and Its Effect on Flame Propagation
Two forms of combustion are recognized in the field of fire science. These are
smoldering combustion, also known as surface burning, and flaming combustion.
Flames are referred to as gas-phase combustion because the fuel participating in
combustion is in the gas phase. This can be due either to the fuel’s natural gaseous
state, or because the fuel was converted from a solid or liquid to the gas phase prior to
entering the combustion zone. For liquids, this conversion process is normally
vaporization; for solids, the process is normally pyrolysis.
Flames represent the more efficient of the two forms of combustion and are readily
capable of providing rapid rates of heat release. The very hot gases exiting the top of a
flame are known as the fire plume. These hot gases travel upward due to their strong
buoyant nature. The greater the heat release rate of the fire, the higher the velocities of
the fire plume gases.
The upward flow of the plume will continue until the plume is either cooled sufficiently
by cooler surrounding air entrained in the plume as it rises, or until it hits a barrier to
the upward movement, such as the mine roof in this instance. Generally, except for
very small fires, fire plumes would have to travel many tens or even hundreds of feet
vertically before sufficient air entrainment would cause sufficient plume cooling to
prevent further upward travel. For practical purposes, cooling of the fire plume by air
entrainment only stops plumes from rising in fires in open areas or in enclosures with
very high ceilings.
When upward plume flow is stopped because of barriers such as a mine roof, the hot
gases turn and travel under the barrier. If the barrier is level, these gases tend to
disperse in all directions equally. However, if the barrier is inclined, the buoyancy of
the hot plume gases will drive the gases uphill under the barrier. Even a few degrees of
incline can have a measurable effect on driving the plume uphill. At the Aracoma Alma
Mine #1, the longwall belt entry inclined at approximately 7 degrees, from the PCA
toward the longwall belt transfer point. This incline was sufficient to drive the plume
and fire in this direction, including most of the hot gases.
The incline of the belt entry strongly influenced the direction of fire gas travel and
caused the fire to spread uphill and into the No. 7 Belt entry. A stopping, located
between SS 3249 and SS 3236, prevented further spread uphill. The fire and smoke
spread both inby and outby in the No. 7 Belt entry away from SS 3249.
Although the No. 7 Belt entry, from SS 3249 toward 2 Section, was only slightly
inclined, the missing stopping inby SS 3266 permitted the rising plume to enter the
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 2 Section primary escapeway. The No. 7 Belt entry from SS 3249 outby toward the No. 7
Belt drive was nearly level. Interview statements indicated airflow in the No. 7 Belt
entry was limited and normally traveled from the drive toward the tail pulley. The
level nature of the entry along with the direction of airflow caused most of the smoke to
travel toward the 2 Section rather than toward the North West Mains.
Point of Fire Origin
Eyewitness interview statements placed the location where the fire was first observed
near the mine floor, beneath the northeast side of the PCA. Expended portable fire
extinguishers were found on the mine floor, on the side of the belt opposite from the
location of first visible fire.
Physical evidence indicated the point of fire origin was in the immediate area of the
PCA, consistent with eyewitness interviews. The most intense burning occurred in the
longwall belt entry between the PCA and the No. 7 Belt.
Had the longwall drive entry been level, the point of fire origin would be expected to be
located somewhere near the center of the intense burning area. However, the incline of
the entry shifted the expected point of origin down hill, in the vicinity of the PCA.
Continuity and Availability of Combustible Materials in the Area of Fire Origin
In order for a fire to travel an extended distance between two points, combustible
material must form a contiguous path between those points. In the longwall belt entry,
a number of combustible materials existed to support and spread a well established fire.
These included the coal rib and conveyor belt material, particularly the troughed belt
loaded with coal and the return belt directly below. These two layers of belt extended
the entire length of the longwall belt entry from the stage loader to the transfer point at
SS 3249.
In the belt drive and takeup storage unit area, these two belt layers were located in the
upper portion of the entry. The entry had been mined to a height of about 12 feet in this
area. The layers of belt near the roof became engulfed by hot gases from the fire plume,
preheating the upper layers of belt ahead of the fire. This aided in the uphill fire spread
and the growing intensity of the fire. A side view of the drive/takeup storage unit area
is shown in Appendix D.
Fire Spread Inby the Area of Origin
Even though the two layers of upper belt extended inby to the longwall stage loader,
fire travel in this direction was very slow compared to the uphill direction. As the fire
burned and the fire plume drove the heat and smoke up hill, fresh air was needed to
maintain the fire. This fresh air, which intensified air movement uphill into the fire,
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 came from lower elevations in 9 Headgate. Flame spread along the belt toward the
longwall section against this uphill air movement resulted in what is known as
opposed-flow flame spread. One indicator of opposed-flow flame spread is a sharp
demarcation between burned and unburned material. This type of demarcation was
observed on the belt between the PCA and the RFA. Opposed-flow flame spread
impeded fire travel toward the longwall section.
Once the fire in the area of the PCA had burned through the belt, the belt layers inby
the PCA lost tension and fell into piles onto the takeup storage unit or onto the mine
floor. This reduced the amount of belt surface exposed to burning, further impeding
fire spread toward the longwall section.
Potential Ignition Sources
Determining the cause of the fire is a multi-step process. The first step is to combine
knowledge of fire dynamics with observed patterns of fire damage and smoke travel to
locate the immediate area of fire origin. Next, this area of origin is examined for all
possible ignition sources. Types of ignition sources not found in the area can be
eliminated as possible causes. By combining this process of elimination with an
understanding of the response-to-fire characteristics of the combustible materials in the
area of origin, the investigation can often reveal the most likely source of ignition and
the chain of events leading to ignition.
This investigation revealed the area of fire origin to be in the immediate vicinity of the
PCA of the 9 Headgate longwall belt takeup storage unit. Physical evidence was
consistent with interview statements. Both formed the basis for this conclusion.
Heat created by belt rubbing against the belt structure in the
takeup storage unit was the ignition source for this fire.
Sources of Ignition
Common sources of ignition considered in a fire investigation include cutting and
welding operations, electrical related events, smoking, spontaneous ignition, and
frictional heat. These potential ignition sources were evaluated in the area of fire origin
during the investigation.
•

Cutting and welding operations – Ignition sources in this category include open
flames or molten sparks generated by torches or welders. Such flames or sparks
can ignite nearby combustible materials, especially those of a lightweight nature
such as paper, cardboard, coal dust, coal fines, or loose coal. These lightweight
materials, when contaminated with grease or oil, become even more readily
ignitable.
83

 No equipment typically used for cutting or welding was found within the belt
entry. Neither the interview statements nor the records of work assignments for
January 19, 2006, indicated cutting or welding operations were conducted in the
area during any shift on the day of the fire. Cutting and welding operations
were determined not to be a likely source of the ignition.
•

Electrical Circuits – Electrical related ignition sources include overloaded wiring
or equipment, short circuits, and loose or arcing connections. Such conditions
can generate sufficient heat to ignite wire insulation or adjacent combustibles.
Electrical circuits were examined in the area of fire origin. The only circuits
found were for light fixtures on the upper portion of the rib on the southwest
side of the entry, and the cable bundle that contained the AMS and mine-wide
telephone circuits. These circuits were damaged during the fire but were too far
away from the area of fire initially observed by witnesses to have played a role in
the ignition process. The fire was initially observed in the vicinity of the PCA on
the opposite side of the entry from the lights and CO system cable. Electrical
circuits were determined not to be the likely ignition source.

•

Smoking– Discarded smoldering cigarettes or burning matches have been known
to result in ignition of combustible materials. Section 75.1702 prohibits the use or
possession of smoking materials, including matches and lighters, inside an
underground coal mine at any time. Mine operators are required to have a
program in place to insure that smoking materials, matches, and lighters are not
carried underground. This enforcement includes weekly searches on an
irregular basis.
During this investigation, no evidence was found, nor was any statement made
by miners during interviews, implying any violation of these provisions.
Smoking was determined not to be the likely ignition source.

•

Spontaneous ignition – Some materials and/or chemicals are known to undergo
self-heating reactions that can, under some conditions, result in self-sustained
heating and subsequent ignition of the materials or chemicals. This process is
sometimes referred to as “spontaneous combustion.” This self-heating process is
attributed to the exothermic oxidation of the material at elevated temperature.
The lower the temperature at which the onset of oxidation occurs, the greater the
propensity of the material is to self heat.
Some coals have shown a tendency to self-heat under certain conditions.
Conditions affecting this tendency include the type of coal, its physical
arrangement, and the amount of ventilation surrounding the coal. In terms of
arrangement, small piles of coal, especially in ventilated areas, are far less likely
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 to undergo self-heating than larger, more extensive collections of coal, especially
in poorly ventilated areas such as a gob.
The results of laboratory analyses on coal samples collected from the Aracoma
Alma Mine #1 strongly suggest that spontaneous ignition of coal accumulations
in the No. 9 Headgate longwall takeup storage unit area was not the likely source
of ignition for the fire on January 19, 2006. Details of the test results are provided
in Appendix Y.
Lubricating oils and greases were also present in the fire area. These greases and
oils can be exposed to heat generated as part of their lubricating mission. Any
tendency to oxidize at elevated temperatures would degrade their lubricating
properties. Hence, these materials are chemically designed to resist oxidation
under conditions of intended use and do not tend to undergo self-heating.
•

Frictional heat – Two surfaces in contact with one another with at least one being
in motion, can create sufficient heat to ignite combustible materials in contact or
in close proximity to one or both surfaces. Either surface may be combustible. In
addition to generating heat, friction can also cause physical damage to one or
both surfaces, resulting in generation of small fragments of the rubbed material.
For example, a conveyor belt rubbing against another surface can create shavings
and/or dust-like particles of belt material that could be more readily ignited due
to the material’s high surface-area-to-mass ratio. When these rubbing conditions
exist for a sufficient time, friction-generated shavings or particles can accumulate
into a quantity of fuel easily ignited by sufficient friction generated heat.
A special case of frictional heating can occur when bearings on rotating shafts
fail, causing metal to metal friction within the bearing. This can result in
sufficient heat to cause the bearing materials to glow or even melt. Grease can
boil out of the bearing housing and ignite upon contact with air. Burning grease
may drop onto nearby easily ignitable materials. In some cases, molten metal
from the bearing can also drip or fly from the bearing and come in contact with
ignitable materials.
Observations by MSHA accident investigators, reviews of the belt maintenance
records, and interview statements indicated bearing failure was not a likely
ignition source. Due to the roof fall that occurred in this area, prior to
completing an examination of all belt takeup storage unit components, it was not
possible to determine whether or not bearing failure on equipment had occurred
on the PCA or adjacent drop-off carriage assemblies. It was not possible to
recover this equipment for post-accident evaluations. Prior to the roof fall,
MSHA investigators had not observed any indications of bearing failure in the
fire area.

85

 Interview statements revealed bearing temperatures in the longwall belt drive
and takeup storage unit area had been checked four times during the shift prior
to the accident. No temperatures were found that exceeded the normal
operating range.
The investigation uncovered substantial evidence that belt friction was a chronic
problem within the belt takeup storage unit. This was indicated by piles of belt
shavings found near the belt takeup storage unit, along with cuts and frayed
edges of the conveyor belt itself. Notches cut into the structural steel of the belt
takeup storage unit also indicated belt misalignment was a problem.
Additionally, interview statements indicated that greasing of bearings was
conducted frequently.
Interview statements of the eyewitness who discovered the fire indicated the
ignition source was friction between the belt and another surface. The friction
created sufficient heat to ignite the initial fuel for the fire. A skewed drop-off
carriage assembly moved the belt toward one side of the takeup storage unit.
This caused frictional heating when the misaligned belt rubbed against any or all
of the following: the bearing housing of the PCA; the frame of the PCA; or the
frame of one of the drop-off carriage assemblies. Frictional heat caused by the
belt rubbing against the structure of the takeup storage unit was determined to
be the ignition source of this fire.
Belt Material Response-to-Fire Considerations
Combustible materials have at least two separate and important response-to-fire
characteristics frequently known as flame resistance and fire resistance. Flame
resistance usually refers to the ease of ignition of a material, while fire resistance usually
refers to a material’s burning characteristics after ignition occurs. Currently published
fire science theories indicate that no correlation exists between these two properties.
Materials difficult to ignite may burn intensely after ignition occurs, while materials
easily ignited may continue to burn with difficulty.
Because the longwall belt material passed the MSHA flame resistance test, it is very
unlikely that frictional heating alone directly ignited this belt material into the observed
rapidly growing flaming fire. This is because the frictional heating that occurred would
have been a less intense heat source than the Bunsen burner flame used in the test.
Because of the flame resistant nature of the belt, a stronger ignition source would have
been necessary. This stronger ignition source most likely existed in the form of a larger
fire impinging on the belt material. During the investigation, witness statements and
observations revealed loose coal, coal dust, float coal dust, excessive grease build up,
and belt shavings were present at various locations along the 9 Headgate longwall belt,
beginning at the drive and continuing its entire length. These conditions were also
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 noted along other belts in the mine. Such easily ignitable combustible materials
accumulating along the belt take up storage unit, once ignited, would have created a
flaming fire capable of igniting the belt.
Likely Initial Fuel Source
Tests, observations, and interview statements indicated the ignition sequence involved
frictional heat, developed between the belt and PCA structure, which ignited
accumulations of combustibles, such as grease, loose coal, and coal dust, located on and
below the PCA. These easily ignited accumulations quickly grew into the strong
flaming fire needed to ignite the flame resistant belt. Once ignited, this belt quickly
grew into an intense fire that resulted in generation of copious quantities of hot, dense,
toxic smoke.
Additional Information
The investigation revealed belt fires and other events that occurred in the weeks and
months prior to January 19, 2006. Details surrounding these events indicated recurring
problems. In addition, corporate communications regarding responsibilities and work
assignments of miners were issued in October, 2005.
Previous Belt Entry Fires and Other Incidents
Interview statements revealed fires, hot belt rollers and bearings had previously been
found in belt entries at Aracoma Alma Mine #1. At least two events developed into
fires that required application of water and/or rock dust by miners to extinguish flames
and/or glowing embers. Mine record books and a printout of the AMS event log
provided additional information relative to these incidents. Fires occurred on
December 23, 2005 at the 9 Headgate longwall belt takeup storage unit, and a second
incident occurred on December 29, 2005, near the No. 5 Belt tailpiece. Mine officials
either observed or were made aware of these two fires. A third fire reportedly occurred
on 8 Headgate longwall belt, but the precise date could not be determined. It was not
determined if mine management was aware of this event.
An incident was identified in a review of the AMS event log in which multiple CO
sensors sequentially indicated alert and alarm conditions on October 8, 2005. The cause
of the alert and alarm conditions could not be determined, but the event seems to have
occurred near the No. 4 Belt tailpiece. It was not determined if mine management was
aware of this event.
8 Headgate Longwall Belt Takeup Storage Unit Fire
One interviewed miner described an incident involving a fire that occurred while
mining the No. 8 longwall panel. The incident reportedly occurred when a bearing in
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 the 8 Headgate longwall belt takeup storage unit caught fire. He heard the flames had
reached the roof before the fire was extinguished using fire extinguishers. Miners were
reportedly stationed in the area to monitor for rekindling after the fire was
extinguished. While the miner did not remember the exact date on which the incident
occurred, he estimated it to be during June or July of 2005, near the completion of
mining in the No. 8 longwall panel. The CO Log book revealed numerous CO sensors
indicated alert and alarm levels of CO during this period of time. However, it could not
be determined if these CO sensors were located in the 8 Headgate longwall belt entry.
The AMS event log provided by the mine operator did not include any information for
the period between 14:30:25 on July 9, 2005, and 14:54:50 on July 22, 2005. No additional
information concerning this incident was discovered by MSHA investigators.
October 8, 2005, AMS Response
A review of the AMS event log revealed a series of CO alert and alarm signals occurred
at eleven CO sensor locations on October 8, 2005. This incident was not recorded in the
CO Log Book. Interview statements indicated there was a heated tail roller which
needed replaced at the No. 4 Belt tailpiece in the past, but there was no other testimony
to support that a fire had occurred. Appendix Z shows the underground locations of
the CO sensors involved. The information in the event log revealed the sequencing of
the alert and alarm signals when the condition cleared at each sensor, and the
maximum carbon monoxide concentration recorded by each CO sensor in an alert or
alarm condition.
Carbon monoxide was first measured at Sensor 90, located near the No.5 Belt drive.
The CO levels at Sensor 90 reached the warning and alarm levels before other sensors
detected sufficient concentrations to initiate warning and alarm signals. Warning
and/or alarm conditions were recorded for consecutive CO sensors both inby and
outby CO Sensor 90. Although CO Sensor 93 was located between Sensors 91 and 92 at
the time of the accident, no alert or alarm signals were recorded for the sensor during
the incident. However, no record of monitoring system communication with CO Sensor
93 was found in the AMS event log from October 3, 2005, thru October 28, 2005.
The pattern of sensor alert and alarm signals is consistent with airflow carrying
contaminants both inby and outby the source. The maximum CO concentration
recorded during the event, 107 ppm, was at CO Sensor 90. The full-scale response for
the CO sensors used in this AMS was 107 ppm. The maximum CO concentration
recorded at each sensor decreased as the distance from CO sensor 90 increased. The
pattern of CO concentrations at the sensors was consistent with dilution of
contaminants caused by the mixing with air from adjacent common entries in the same
air course and/or by mixing with air leaking into the belt air course from the adjacent
intake air course.

88

 The alert and alarm signals recorded in the printout of the AMS event log were not
recorded in the CO Log Book. No record of this event was found in the Pre-shift Onshift and Daily Report record book maintained for the belt examinations. Entries in
the Pre-shift - Onshift and Daily Report record book maintained for the longwall section
and mine production reports revealed coal was produced on day shift, the shift on
which the incident was recorded, on the 9 Headgate longwall section. The 9 Headgate
longwall section was located inby the sensors in which the alert and alarm signals
occurred. Miners were working on the section at the time of the incident. No reference
relative to the incident was made in the delays and remarks section of the longwall
production report. The longwall production report indicated coal was being produced
between 12:17 p.m. and 1:20 p.m. This was the period of time when the alert and alarm
signals were generated by the AMS. This incident was not reported to MSHA. No
additional information regarding this incident was discovered by MSHA accident
investigators. It was not determined whether or not this incident was a fire.
Two other fires occurred in December of 2005, one of which
was at the 9 Headgate takeup storage unit.
December 23, 2005, Fire
Interview statements revealed the cause of an incident that occurred at the 9 Headgate
longwall belt takeup storage unit on December 23, 2005, was similar to that which
occurred on January 19, 2006. During the afternoon shift, dispatcher/AMS operator
Brown observed alert and alarm signals from a CO sensor located near the 9 Headgate
longwall belt drive. Brown contacted Conley, and asked him to investigate. Conley
encountered smoke and found reddish-yellow colored embers in a pile of belt shavings
on the mine floor beneath the belt in the 9 Headgate longwall belt takeup storage unit.
Conley also found a drop-off carriage assembly in the belt takeup storage unit was
skewed and had caused the belt to become misaligned. The misaligned belt appeared
to have rubbed against the bearing housing and possibly something else. He believed
the rubbing had caused shavings from the edge of the belt to accumulate and ignite.
The belt was not operating at the time he arrived at the fire. He estimated the time
required to extinguish the fire with water was approximately 30 minutes. During the
incident, Conley noted there was insufficient water pressure to the area where the fire
occurred. He also noted that the firehose he attempted to use was incompatible with
the VFO in the fire area. Conley reported the event to Horton, who told him not to say
the word “fire” over the mine phone, so that other miners would not be alarmed.
Although Conley also reported the incident to his supervisor, it is uncertain whether
mine management officials were made aware of these deficiencies.
A review of the AMS event log for December 23, 2005, revealed a series of alert and
alarm signals occurred at CO sensor locations during this incident. Alert and alarm
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 conditions were recorded for CO sensors located near the longwall belt takeup storage
unit: first at CO Sensor 82, then at CO Sensor 81. CO Sensor 82 was located in the
longwall belt entry between the belt takeup storage unit and the belt drive. CO Sensor
81 was located in the No. 7 Belt entry near the No. 7 Belt tail pulley. CO sensor
locations are identified on the map in Appendix Z. The AMS event log indicated alarm
conditions of CO Sensor 82 caused activation of the alarm unit on the longwall
headgate.
The pattern of sensor alert and alarm signals is consistent with airflow carrying
contaminants from the belt takeup storage unit area outby to the No. 7 Belt entry and
then inby past the No. 7 Belt tail pulley. The maximum CO concentration recorded
during the event, 46 ppm, was at CO Sensor 82. The maximum CO concentration
recorded at CO Sensor 81 was 11 ppm. The AMS event log indicated alert and alarm
conditions lasted 41 minutes at Sensor 82.
Entries in the Preshift-Onshift and Daily Report record book maintained for the
longwall section and mine production reports revealed coal was produced on afternoon
shift, the shift on which the incident occurred, on the 9 Headgate longwall section. The
longwall production report for the afternoon shift on December 23, 2005, revealed the
section crew departed from the longwall section at 9:35 p.m., before the time the AMS
alarm was activated. As there were no miners on the longwall section, the performance
of the activated alarm unit at the longwall headgate could not be verified.
Entries in the Preshift-Onshift and Daily Report record book maintained for 2 Section
revealed coal was produced on that section on the afternoon shift of December 23, 2005.
The 2 Section was located inby the area where the sensors in which the alert and alarm
signals occurred were located. Interview statements revealed the 2 Section crew was
inby the area where the sensors in which the alert and alarm signals occurred during
the incident were located.
There was no entry in the Preshift - Onshift and Daily Report record book maintained
for the belt examinations for an examination of the longwall belt during the day shift
and afternoon shift on which the fire occurred. Although an entry was recorded in the
CO Log Book regarding the fire, the record was not complete as required by § 75.351(o).
December 29, 2005, Fire
Interview statements and mine records revealed a fire occurred near the tailpiece of the
No. 5 Belt on December 29, 2005. Brown contacted White and beltman Wyatt Robinson,
who were both at the longwall belt electrical installation, and notified them that alarm
signals had occurred at CO sensors located along the Nos. 5 and 6 Belts. The two
miners traveled on foot to investigate the cause of the alarms.

90

 Upon arriving at the No. 6 Belt drive area approximately 15 minutes later, the miners
encountered smoke. The miners approached the fire through the smoke without
donning SCSRs and found belt shavings, accumulated coal, and the adjacent coal rib
burning near a bottom belt roller. The smoke was traveling inby toward the working
sections. A bearing in the bottom roller, located a short distance outby the No. 5 Belt
tailpiece, was believed to have been failing. One fire extinguisher and one bag of rock
dust were used to extinguish the flames. However, one of the miners fighting the fire
checked the visual display of a nearby CO sensor and found the carbon monoxide
concentration was still above the warning level. Water was applied to the mine floor in
the area to extinguish the remaining burning material. The failed bottom roller was
removed and dropped into the wet material under the belt. White estimated the time
required to fully extinguish the fire to be 30 minutes after discovery. Robinson
estimated the time required to fully extinguish the fire to be 45 minutes after discovery.
The alert and alarm levels were recorded for a period of 100 minutes during the fire.
The belt was not stopped during the incident. David Meade, 003 Section foreman, was
identified as also having assisted the two miners in extinguishing the fire. White
informed Perry of the fire and that the hose clamps which secured the hose to the
connector, failed during the application of water on the fire. Evidence of this fire was
visible to MSHA personnel investigating the January 19, 2006, accident. Interview
statements also indicated evacuation of the mine was considered by Meade before he
spoke with Robinson.
A review of the AMS event log for December 29, 2005, revealed a series of alert and
alarm signals occurred at CO sensor locations during this fire. Alert and alarm
conditions were recorded for CO sensors located in the North West Mains and the No. 7
Belt entries. The first alert signal occurred at CO Sensor 94, located in the No. 5 Belt
entry outby the No. 5 Belt tailpiece. Signals were then recorded at CO Sensors 50, 51,
53, 80 and 81, which were inby the No. 5 Belt tailpiece. The AMS event log did not
indicate an alert or alarm signal from Sensor 52, which was located between CO Sensors
51 and 53. Information in the AMS event log indicated communication problems with
CO Sensor 52 during the incident. CO sensor locations are identified on the map in
Appendix Z. There was no record in the AMS event log that indicated the alarm
conditions of the six CO sensors caused activation of the alarm unit on the longwall
headgate.
The pattern of sensor alert and alarm signals is consistent with airflow carrying
contaminants from outby the No. 5 Belt tailpiece to the end of the No. 6 Belt tailpiece
and also from the No. 6 Belt entry along the No. 7 Belt to beyond the No. 7 Belt tail
pulley. The maximum CO concentrations recorded during the fire were 107 ppm at CO
Sensor 94, 107 ppm at CO Sensor 50, 68 ppm at CO Sensor 51, 56 ppm at CO Sensor 53,
42 ppm at CO Sensor 80, and 32 ppm at CO Sensor 81. No other CO sensors in the
NEM belt entries detected alert or alarm levels of CO. No CO sensors located along the

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 longwall belt detected alert or alarm levels of CO. The indicated pattern of response
and likely air flow direction is consistent with the response to the January 19, 2006, fire.
Entries in the Pre-shift - Onshift and Daily Report record book maintained for the
longwall section and mine production reports revealed coal was produced on afternoon
shift, the shift on which the fire occurred, on the 9 Headgate longwall section. The
longwall production report for the afternoon shift on December 29, 2005, also revealed
coal was produced on the longwall section during the fire. The 9 Headgate longwall
section was located inby the location of the fire.
The lack of a record in the Pre-shift - Onshift and Daily Report record book maintained
for 2 Section indicated coal was not produced on the afternoon shift on 2 Section.
Although all mine record books for the time period in which the fire occurred were
requested, the Pre-shift - Onshift and Daily Report record book maintained for the belt
examinations was among the record books not provided to MSHA investigators by the
mine operator. Although an entry was recorded in the CO Log Book regarding the fire,
the record was not complete as required by § 75.351(o). This fire was not reported to
MSHA.
Corporate Communications
The investigation revealed that on October 19, 2005, a memorandum was sent to all
deep mine superintendents from Massey Energy, Inc. Chief Executive Officer (CEO),
indicating that if they were asked “…to do anything other than run coal, (i.e. – build
overcasts, do construction jobs, or whatever) you need to ignore them and run coal.”
The first memo was addressed in a subsequent memo on October 26, 2005, in which the
CEO clarified the company position that “…safety and S-1 is our first responsibility.”
The latter memo stated that outby construction jobs needed to keep the mine safe and
productive should be done, but every effort should be made to do them without taking
people and equipment off of production sections. A copy of these memoranda can be
found in Appendix AA. Lawrence Lester, Superintendent for Aracoma Alma Mine #1,
declined to participate in a voluntary interview and, therefore, could not be questioned
regarding these memos.
ROOT CAUSE ANALYSIS
An analysis was conducted to identify the root causes that contributed to the accident.
Removing or correcting these root causes would have averted the accident entirely or
preventing the loss of life. Listed below are the causes identified during this analysis
and their corresponding corrective actions to prevent a recurrence of the accident. In
each case, no effective management system, policy or procedure was in place to assure
compliance with the underlying regulations and safe mining practices.

92

 Root Cause: The dispatcher/AMS operator who was on duty on the afternoon shift of
January 19, 2006, was not properly trained.
Corrective Action: The dispatcher/AMS operator received proper training on February
24, 2006, regarding firefighting procedures, emergency evacuation procedures, and the
mine ventilations system, and proper responses to alert and alarm signals generated by
the AMS.
Root Cause: The location of all personnel doors in stoppings along the 2 Section
escapeways were not clearly marked so the doors could be easily identified by anyone
traveling in those escapeways.
Corrective Action: The location of all personnel doors were clearly marked to identify all
personnel doors in stoppings along primary and alternate escapeways such that doors
can be easily identified by anyone traveling in the escapeways. Management developed
a program to inform miners of the location of new doors installed or changes to existing
doors along their respective escape routes.
Root Cause: No CO alarm unit was installed on 2 Section to provide miners with
automatic notification of CO alarm signals from outby sensor locations.
Corrective Action: A CO alarm unit was installed on 2 Section to provide miners with
automatic notification. Mine management must properly install and maintain the AMS
in compliance with the requirements § 75.351.
Root Cause: The mine operator failed to identify the absence of an alarm unit on
2 Section during visual examinations of the AMS on each production shift.
Corrective Action: The mine operator retrained persons responsible for the examinations
of the AMS to assure they are properly trained and familiar with the requirements
of § 75.350, § 75.351, and § 75.352.
Root Cause: The AMS operator on duty on the afternoon shift of January 19, 2006, failed
to promptly notify the appropriate personnel that an alarm signal had been generated.
Corrective Action: The dispatcher/AMS operator received proper training on February
24, 2006, regarding firefighting procedures, emergency evacuation procedures, and the
mine ventilations system, and proper responses to alert and alarm signals generated by
the AMS.
Root Cause: Mine examiners did not identify existing hazardous conditions.
Corrective Action: Miners and examiners were retrained to ensure that all hazardous
conditions are addressed and appropriate corrective actions taken, regardless of when
93

 the hazards are detected or by whom. Mine examiners must be equipped with and use
equipment, including anemometers, chemical smoke, and gas detectors necessary to
properly conduct examinations. Examiners must be properly trained to conduct these
critical mine examinations and properly record the results of the examinations into the
appropriate record books.
Root Cause: The primary escapeway provided for 2 Section was not separated from the
No. 7 Belt entry in the NEM inby the No. 7 Belt tail pulley.
Corrective Action: Ventilation controls were constructed to separate the primary
escapeway for 2 Section from the No. 7 Belt entry in the NEM inby the No. 7 Belt tail
pulley. Mine management must ensure that permanent ventilation controls are properly
installed and maintained to provide separation between belt entries and primary
escapeways.
Root Cause: Adequate escapeway drills were not conducted as required.
Corrective Action: Management initiated a program to ensure that escapeway drills are
conducted as required. Management must ensure that all miners have proper training
at the required intervals and are familiar with escapeways from each working section to
the surface. Mine management must also ensure escapeway drills are properly rotated
between primary and alternate escapeways.
Root Cause: Combustible materials, in the form of grease, oil, coal dust, float coal dust,
coal fines, and loose coal spillage, were allowed to accumulate in the area of the
9 Headgate belt takeup storage unit.
Corrective Action: The materials that remained after the fire were cleaned. Mine
management must ensure that accumulations of combustible materials in underground
belt entries are removed promptly. A program for regular cleanup and removal of
accumulations of combustible materials must be established and maintained.
Root Cause: A shut off valve was in the closed position, preventing water flow into the 2inch diameter water supply line installed parallel to the 9 Headgate longwall belt.
Corrective Action: Mine management has repaired the water supply system. Mine management
must ensure that an adequate water supply is provided at all times.
Root Cause: Threads of female couplings on the firehose first obtained for firefighting at
the 9 Headgate longwall belt drive area were not compatible with the threads of male
pipe of the valved firehose outlet.
Corrective Action: Mine management has installed firehoses and firehose outlets that
have compatible fittings. Mine management must ensure that adequate firefighting
94

 equipment is provided along the belt. The threads of couplings and nipples must be
compatible so that firehoses can be quickly connected to valved firehose outlets.
Root Cause: The operator failed to install a fire suppression system that provided
coverage over the electrical motors, belt takeup storage unit, gear reducing unit, and the
electrical controls at the No. 9 Headgate longwall belt takeup storage unit.
Corrective Action: Mine management expanded the fire suppression system to provide
coverage over the electrical motors, belt takeup storage unit, gear reducing unit, and the
electrical controls at the No. 9 Headgate longwall belt takeup storage unit. Mine
management must ensure that fire suppression systems are provided and maintained
where required.
Root Cause: The operator failed to conduct adequate examinations of fire suppression
systems and firefighting equipment.
Corrective Action: Mine management conducted training that stressed the identification
and correction of hazardous conditions and other conditions that would impair the
effectiveness of fire suppression systems and firefighting equipment. Mine
management and persons conducting examinations, and functional tests of fire
suppression systems and firefighting equipment must be trained and knowledgeable in
the requirements of Sections 75.1101 and 75.1103, and MSHA PPL No. P06-V-5.
Root Cause: The mine map was not kept up-to-date by temporary notations to depict the
permanent ventilation controls constructed and/or removed in the NEM.
Corrective Action: The mine map was properly updated. Mine management must ensure
an accurate and up-to-date map of the mine be maintained, including but not limited to
required temporary notations. Mine management and persons assigned the
responsibility for maintaining the required map should be trained and knowledgeable
in the requirements of Subpart M-Maps.
Root Cause: Mine management failed to initiate and conduct an immediate evacuation
on January 19, 2006, when a fire at the 9 Headgate longwall belt takeup storage unit
presented an imminent danger to the miners.
Corrective Action: Mine Management must ensure that miners are withdrawn to a safe location
when there is a mine emergency which presents an imminent danger to miners due to a fire.
Root Cause: The mine operator failed to maintain the 9 Headgate longwall belt in a safe
operating condition and did not remove it from service as required.

95

 Corrective Action: Mine management must identify and promptly correct hazardous
conditions on mobile and stationary equipment. Mine management must remove
equipment in unsafe operating condition from service immediately.

96

 CONCLUSION
On January 19, 2006, carbon monoxide sensors in the 9 Headgate longwall belt unit area
of Aracoma Alma Mine #1 detected alarm levels of CO at approximately 5:14 p.m.
Twenty-nine underground miners were working at the time. During the evacuation
process, two of the 12 miners from 2 Section became separated from the remainder of
the crew when dense smoke was encountered. Initial attempts to locate the missing
miners and extinguish the fire were unsuccessful. Two miners died as a result of the
fire. The fire was eventually brought under control by mine rescue teams and the
deceased miners were found on January 21, 2006.
The fire occurred as a result of frictional heating when the longwall belt became
misaligned in the 9 Headgate longwall belt takeup storage unit. This frictional heating
ignited accumulated combustible materials. The required fire suppression system was
not installed in the area where the fire occurred. Water was turned off to the
firefighting waterline in the area, and firehoses could not be used. The fire
extinguishers expended did not extinguish the fire. Stoppings that were required to
maintain separation between the No. 7 Belt entry and the primary escapeway for
2 Section had previously been removed. Examinations of the mine were inadequate
and failed to identify the lack of separation between the primary escapeway and belt air
course. In addition, examinations of safety systems failed to identify deficiencies which
contributed to the severity and extent of the mine fire. Airflow carried the smoke from
the fire to the No. 7 Belt entry and then into the primary escapeway for 2 Section
through the openings created by the stoppings that had been previously removed.
Mine management did not immediately notify nor did they immediately withdraw
miners from the affected areas (2 Section and the longwall section) to a safe location
following the initial CO alarm signal from the AMS. At 5:39 p.m., the dispatcher
attempted to alert the 2 Section crew by remotely stopping the 2 Section belts. At
approximately 5:42 p.m., the 2 Section foreman called the dispatcher regarding the belt
stoppage, and was instructed by the dispatcher and the afternoon shift mine foreman to
evacuate. Two miners became separated from the other 2 Section miners during the
evacuation and perished. The remaining twenty-seven miners working underground
escaped safely.

97

 ENFORCEMENT ACTIONS
A 103(k) order was issued to ensure the safety of all persons until an investigation was
completed and the area and equipment deemed safe. The following violations were
deemed to have contributed to the accident. Other violations deemed not to have
contributed to the cause or severity of the accident were cited separately and are not
addressed in this report.
104(d)(2) Order No. 7435530

75.380(g)

S&S

Reckless Disregard

The primary escapeway provided for the 2 Section was not separated from the No. 7
Belt conveyor entry in the North East Mains inby the No. 7 Belt conveyor tail pulley.
This condition was created prior to November 2005, when one or more permanent
stoppings that provided separation between the No. 7 Belt conveyor entry and the
primary escapeway in the North East Mains were removed.
This lack of separation between the primary escapeway and the belt conveyor entry
allowed smoke and carbon monoxide gas to inundate the primary escapeway used by
the miners during the evacuation from 2 Section on January 19, 2006. Smoke from the
fire adversely impacted the ability of miners from 2 Section to escape, resulting in two
fatalities.
104(d)(2) Order No. 7435531

75.383

S&S

Reckless Disregard

Adequate escapeway drills were not conducted as required. The frequency of the
escapeway drills did not always meet the 90-day period requirement during the 12
months prior to January 19, 2006. In addition, the 90-day practice escapeway drills that
had been conducted during the 12 months prior to January 19, 2006, were not always
rotated between the primary and alternate escapeways. Mine records indicate that not
all miners working on 2 Section on January 19, 2006, participated in a practice
escapeway drill in the 90 days preceding the accident.
Moreover, the practice escapeway drills that were conducted were inadequate for the
following reasons:
1. Contrary to mine records, miners from 2 Section did not travel the primary
escapeway in its entirety to the surface during required 6-week escapeway drills.
The required 6-week escapeway drills conducted in the primary escapeway
consisted of traveling in a rubber-tired diesel mantrip from the section in the
North East Mains roadway, through the equipment doors at the 9 Headgate
longwall belt drive area, rather than the designated route over the intake
overcast at Survey Station 3221.

98

 2. Miners traveled through areas not clearly marked as escapeways during
escapeway drills. The escapeways from 2 Section were not clearly marked
throughout the North East Mains. The amber reflective tags used to mark the
alternate escapeway route did not clearly show the route and direction of travel
from the section to the surface. Green reflective tags, used to mark the primary
escapeway route, were located in multiple parallel mine entries between
2 Section and the North West Mains. In addition, not all changes in direction of
travel in the escapeways were clearly marked.
3. Miners were not afforded the opportunity to become familiar with the location of
all personnel doors in stoppings along the 2 Section escapeways during
escapeway drills. The personnel door used by the 2 Section crew during their
escape from the mine was located in North East Mains between SS 3224 and SS
3230 in the stopping that separated the primary and alternate escapeways. The
location of this personnel door was not marked so it could be easily identified by
anyone traveling in the escapeway.
4. The escapeway maps kept on 2 Section and the longwall working sections and
the escapeway map posted at the surface location where miners congregate were
not accurate nor kept up-to-date. The mine workings shown on the maps were
not up-to-date to show the current location of 2 Section and the designations of
the respective escapeways on the maps did not accurately depict the marked
underground routes of travel.
The failure to conduct adequate escapeway drills as required contributed to the
inability of the victims to successfully evacuate the mine on January 19, 2006.
104(d)(2) Order No. 7435109

75.333(c)(2)

S&S

High Negligence

The location of all personnel doors in stoppings along the 2 Section escapeways were
not clearly marked so that the doors could be easily identified by anyone traveling in
the escapeways. The personnel door used by the 2 Section crew during their escape
from the mine was located in North East Mains between SS 3224 and SS 3230 in a
stopping that separated the primary and alternate escapeways. The location of this
personnel door was not marked.
The failure to clearly mark the location of all personnel doors in stoppings along
primary and alternate escapeways so that the doors could be easily identified by
anyone traveling in the escapeways contributed to the inability of the victims to
successfully evacuate the mine on January 19, 2006.

99

 104(d)(2) Order No. 7435525

75.360(b)(9)

S&S

Reckless Disregard

Preshift examinations required at the location of the underground electrical installations
for the 9 Headgate longwall belt, south of SS 3266, were not adequate. The
examinations failed to identify the lack of a properly constructed airlock intended to
separate the 2 Section primary escapeway from the No. 7 Belt conveyor entry. A
permanent stopping, located immediately adjacent to the North East Mains roadway
South of SS 3266 was removed a significant period of time prior to January 19, 2006,
reportedly to reduce heat in the crosscut where the power boxes were installed. The
removal of this stopping, in conjunction with the open crosscuts along the North East
Mains roadway between 9 Headgate and 9 Tailgate, resulted in a lack of separation
between the 2 Section primary escapeway and the No. 7 Belt conveyor entry.
This lack of separation between the primary escapeway and the belt conveyor entry
allowed thick smoke and carbon monoxide gas to inundate the primary escapeway
used by the miners during the evacuation from 2 Section on January 19, 2006. Due to
reduced visibility caused by the thick smoke, two miners were separated from the
section crew and unable to escape.
104(d)(2) Order No. 7435110

75.360(b)(10)

S&S

Reckless Disregard

Preshift examinations required at the location where miners were scheduled to install
belt structure inby the No. 7 Belt conveyor tail pulley were inadequate. The stopping
between SS 3266 and 3332, in North East Mains had been removed to facilitate
extension of the No. 7 Belt conveyor structure. The stopping was necessary to separate
the No. 7 Belt conveyor from the primary escapeway for 2 Section. Corrective actions
were not taken for the hazardous condition created by the absence of stoppings
necessary to provide separation between the primary escapeway for 2 Section and the
No. 7 Belt conveyor Entry.
This lack of separation between the primary escapeway and the belt conveyor entry
allowed thick smoke and carbon monoxide gas to inundate the primary escapeway
used by the miners during the evacuation from 2 Section on January 19, 2006. Due to
reduced visibility caused by the thick smoke, two miners were separated from the
section crew and unable to escape.
104(d)(2) Order No. 7435108

75.360(b)(10)

S&S

Reckless Disregard

The mine operator failed to conduct an adequate preshift examination of the No. 7 Belt
conveyor for the day shift on January 19, 2006. This examination was also intended to
satisfy the requirements of 75.362 (b).

100

 The belt examiner failed to identify, record, and correct that the No. 7 Belt conveyor was
not separated from the primary escapeway for 2 Section. Further, the last record of an
examination of the No. 7 Belt conveyor was not signed or initialed by the examiner.
The examination was not complete, and hazardous conditions that were determined to
have existed at the time of the examination were not recorded. The examination record
indicated air was moving in the right direction with a velocity greater than 50 fpm.
However, the belt examiner stated he did not make airflow direction determinations, or
air velocity measurements, and was unable to identify the proper airflow direction in
the No. 7 Belt conveyor entry.
The stopping was one of those necessary to provide separation between the 2 Section
primary escapeway and the No. 7 Belt conveyor entry. This lack of separation allowed
smoke and carbon monoxide gas to inundate the primary escapeway used by the
miners during the evacuation from 2 Section on January 19, 2006. Smoke from the fire
adversely impacted the ability of miners from 2 Section to escape, resulting in two
fatalities.
104(d)(2) Order No. 7435526

75.362(b)

S&S

Reckless Disregard

The mine operator failed to conduct adequate on-shift examinations of the longwall belt
conveyor for the day shift on January 19, 2006. The following hazardous conditions
were not identified by the mine examiner:
1. Accumulations of combustible material were present in the form of grease, oil,
coal dust, coal fines, and loose coal spillage at numerous locations along the
approximate 2,000 feet length of the 9 Headgate longwall belt conveyor;
2. Damaged bottom rollers, bottom rollers on the ground with indications they had
been rotating in combustible material on the mine floor, and damaged top
rollers;
3. Damaged and missing trip latch lever posts and damaged drop-off carriage
assembly trip latch levers that affected positioning of the drop-off carriage within
the 9 Headgate longwall belt takeup storage unit;
4. No fire suppression system of any type, which would actuate in the event a rise
in temperature, was provided for the belt takeup storage unit and electrical
components; and
5. Fire hose outlet valves near the longwall belt conveyor tailpiece were not
provided with handles to actuate.
There were also several indications of prolonged operation of the longwall belt
conveyor system while the belt was misaligned, including:
1. Damaged belt hangers, some partially cut through and others severed from
prolonged rubbing from misaligned belt;
101

 2. Damaged belt takeup storage unit frame components, partially cut through from
prolonged rubbing of misaligned belt;
3. Severed strips of belt on the mine floor and hanging on belt structure;
4. Lengths of partially severed strips of belt;
5. Shavings of belt on the mine floor;
6. Belt cord fibers wrapped around belt roller components; and
7. Extended lengths of belt with frayed edges.
Further, the last record of an examination of the 9 Headgate longwall belt conveyor was
not signed or initialed by the examiner. The examination was not complete and
hazardous conditions that were determined to have existed at the time of the
examination were not recorded. Although the examination record indicated air was
moving in the right direction with a velocity greater than 50 fpm, the belt examiner
stated he did not make airflow direction determinations or air velocity measurements
and was unable to identify the proper airflow direction in the longwall belt entry.
Required mine examinations were routinely conducted by certified examiners who
were not equipped with an MSHA approved gas detector capable of determining
oxygen deficiency and methane concentrations.
Based on these conditions, the longwall belt conveyor should have been removed from
service by the examiner. These conditions were obvious and located in the areas
traveled by mine examiners. Many of these conditions contributed to the severity and
extent of the mine fire on January 19, 2006, which ultimately resulted in the two
fatalities.
104(d)(2) Order No. 7435527

75.363

S&S

Reckless Disregard

Not all hazardous conditions were being posted, corrected, and recorded. Although
mine management was aware of hazardous conditions, effective corrective actions were
not taken.
The record maintained by the operator for the purpose of recording results of
examinations for hazardous conditions indicated that actions were not taken to correct
the hazardous conditions listed regarding the 9 Headgate longwall belt conveyor from
January 2, 2006 to January 19, 2006. Although hazardous conditions, such as the need
for additional cleaning and rock dusting, were noted in the record book, no corrective
actions were listed for 38 of the 56 examinations. The corrective actions listed for the
remaining 18 examinations were inadequate. Mine record books indicated a history of
hazardous conditions, yet mine management failed to properly address the conditions.
Moreover, results of the two examinations on January 19, 2006, prior to the accident
indicate the 9 Headgate longwall belt conveyor needed to be cleaned and dusted. No
corrective actions were listed in the record and a physical examination of the 9

102

 Headgate longwall belt conveyor during the accident investigation indicated that
appropriate actions had not been taken to correct the conditions.
In addition, corrective actions were not taken for the hazardous condition created by
the absence of stoppings necessary to provide separation between the primary
escapeway for 2 Section and the No. 7 Belt conveyor entry. A permanent stopping,
located immediately adjacent to the North East Mains roadway South of SS 3266 was
removed a significant period of time prior to January 19, 2006, reportedly to reduce heat
in the crosscut where the power boxes were installed. The absence of this stopping
resulted in the lack of a properly constructed airlock intended to separate the 2 Section
primary escapeway from the No. 7 Belt conveyor entry.
Another stopping located between SS 3266 and SS 3332 in North East Mains had been
removed at the direction of mine management personnel to facilitate extension of the
No. 7 Belt conveyor structure. This stopping was necessary to separate the No. 7 Belt
conveyor entry from the primary escapeway for 2 Section.
These conditions were obvious and located in the areas traveled by mine examiners.
These conditions contributed to the severity and extent of the mine fire on January 19,
2006, which ultimately resulted in the two fatalities.
104(d)(2) Order No. 6643276

75.364(b)(1)

S&S

Reckless Disregard

Adequate weekly examinations of the entire No. 7 Belt air course were not conducted
from November 1, 2005, to January 19, 2006. The examinations failed to identify the
lack of separation between the No. 7 Belt air course and the 2 Section primary
escapeway. This condition was determined to have existed prior to November 2005,
when a permanent stopping located between SS 3266 and SS 3332 in North East Mains
had been removed to facilitate extension of the No. 7 Belt conveyor structure.
Examination records which specifically identified that the No. 7 Belt air course was
examined in its entirety were not provided by the mine operator. By definition, the belt
air course includes the entry in which the belt is located and any adjacent entry(ies) not
separated from the belt entry by permanent ventilation controls, including any entries
in series with the belt entry, terminating at a return regulator, a section loading point, or
the surface.
This lack of separation between the No. 7 Belt air course and the 2 Section primary
escapeway in North East Mains allowed thick smoke and carbon monoxide gas to
inundate the primary escapeway used by the miners during the evacuation from 2
Section on January 19, 2006. Due to reduced visibility caused by the thick smoke, two
miners were separated from the section crew and were unable to escape.

103

 104(d)(2) Order No. 7435528

75.364(b)(5)

S&S

Reckless Disregard

Weekly examinations of the primary escapeway provided for 2 Section conducted from
November 1, 2005 to January 19, 2006, were not adequate. The examinations failed to
identify the lack of separation between the 2 Section primary escapeway and the No. 7
Belt conveyor entry. This condition was determined to have existed prior to November
2005, when a permanent stopping, located south of SS 3266, was removed at the 9
Headgate longwall dual switch house electrical installation. Another stopping located
between SS 3266 and SS 3332 in North East Mains had been removed at the direction of
mine management personnel to facilitate extension of the No. 7 Belt conveyor structure.
This stopping was necessary to separate the No. 7 Belt conveyor entry from the primary
escapeway for 2 Section.
The examination also failed to identify the following: the lack of a clearly marked
primary escapeway to show the route and direction of travel from 2 Section to the
surface; the location of all personnel doors along the primary escapeway so that the
doors could be easily identified by anyone traveling in the escapeway; and holes in
numerous stoppings located between the 2 Section primary escapeway and the North
East Mains No. 1 Belt conveyor entry that compromised the separation between these
entries.
This lack of separation between the primary escapeway and the belt conveyor entry
allowed thick smoke and carbon monoxide gas to inundate the primary escapeway
used by the miners during the evacuation from 2 Section on January 19, 2006. Due to
reduced visibility caused by the thick smoke, two miners were separated from the
section crew and unable to escape.
104(d)(2) Order No. 7435533

75.1100-1(a)

S&S

High Negligence

The 2-inch diameter water supply line installed parallel to the 9 Headgate longwall belt
conveyor pursuant to 30 CFR § 75.1100-2(b) was not capable of delivering 50 gallons of
water per minute at a nozzle pressure of 50 pounds per square inch. An eye witness
statement indicated while attempting to fight the fire, the fire hose outlet valve located
near the belt conveyor takeup storage unit was opened and no water was produced.
The absence of water to fight the fire directly impacted the ability to control and
extinguish the fire on January 19, 2006. The condition contributed to the severity, extent,
and magnitude of the mine fire, which ultimately resulted in the two fatalities.
104(d)(2) Order No. 7435534

75.1100-2(b)

S&S

Reckless Disregard

Adequate fire fighting equipment was not provided for the 9 Headgate longwall belt
conveyor. The threads of the female coupling of the fire hose were not compatible with
the threads of the male pipe of the fire hose outlet valve.
104

 The lack of compatible fire fighting equipment resulted in the failure to extinguish the
fire on January 19, 2006. This contributed to the severity, extent, and magnitude of the
mine fire, which ultimately resulted in the two fatalities.
In addition, valuable time was lost during the initial effort to connect incompatible
firefighting hoses to fire hose outlet valves. This further delayed the evacuation of the
miners from 2 Section.
104(d)(2) Order No. 7435535

75.1101-8(a)

S&S

Reckless Disregard

The mine operator failed to install the water sprinkler system in accordance with 30
CFR § 75.1101-8(a). The water sprinkler system did not provide coverage over the
electrical motors, belt takeup storage unit, gear reducing unit, and the electrical controls
at the No. 9 Headgate longwall belt conveyor takeup storage unit. The fire initiated in
the belt takeup storage unit.
The absence of an adequate and complete water sprinkler system resulted in the failure
to extinguish the fire on January 19, 2006. The condition contributed to the severity,
extent, and magnitude of the mine fire, which resulted in the two fatalities.
104(d)(2) Order No. 7435536

75.1101-11

S&S

Reckless Disregard

The mine operator failed to conduct adequate weekly examinations of the water
sprinkler system for the 9 Headgate longwall belt conveyor belt drive, takeup storage
unit, electrical controls, and gear-reducing unit.
The electrical components and belt take-up storage unit were not provided with a fire
suppression system which would activate in the event a rise in temperature occurred at
this location. These hazardous conditions were not identified and recorded at the time
of the examination. Corrective action was not taken to address the condition.
Proper examinations would have revealed the absence of an adequate and complete
water sprinkler system. This resulted in the failure to extinguish the fire on January 19,
2006. The condition contributed to the severity, extent, and magnitude of the mine fire,
which resulted in the two fatalities.
104(d)(2) Order No. 7435522

75.1103-11

S&S

Reckless Disregard

Records were not produced by the mine operator to document required annual
functional tests of fire hydrants and fire hoses in the mine. Adequate functional tests
would have revealed the threads of the female coupling of the fire hose were not
compatible with the threads of the male pipe of the fire hose outlet valve.

105

 Valuable time was lost during the initial effort to connect incompatible firefighting
hoses to fire hose outlet valves. This further delayed the evacuation of the miners from
2 Section.
The lack of compatible fire fighting equipment resulted in the failure to extinguish the
fire on January 19, 2006. This condition contributed to the severity, extent, and
magnitude of the mine fire, which ultimately resulted in the two fatalities. This same
condition existed at the same location during a fire on December 23, 2005.
104(d)(2) Order No. 7435523

75.351(c)(4)

S&S

Reckless Disregard

The Atmospheric Monitoring System did not automatically provide visual and audible
signals at all affected working sections when the carbon monoxide concentration at CO
sensors reached alarm level. No carbon monoxide alarm unit was installed at a location
where it could be seen or heard by miners on 2 Section to provide automatic notification
of carbon monoxide alarm signals from outby sensor locations. The affected working
sections during the fire that occurred on January 19, 2006, included both 2 Section and 9
Headgate longwall section.
The failure to automatically provide visual and audible signals on 2 Section
significantly contributed to the delay in the notification and withdrawal of miners who
were working on 2 Section when a belt fire occurred on January 19, 2006.
104(d)(2) Order No. 7435521

75.351(n)(1)

S&S

Reckless Disregard

Adequate visual examinations of alarms and sensors used to detect carbon monoxide
were not conducted each production shift on 2 Section. An adequate visual
examination would have revealed there was no alarm unit installed on 2 Section to
automatically provide visual and audible signals that could be seen and heard by
miners on the section when carbon monoxide concentrations reached alarm level.
The failure to automatically provide visual and audible signals on 2 Section
significantly contributed to the delay in the notification and withdrawal of miners who
were working on 2 Section when a belt fire occurred on January 19, 2006.
104(d)(2) Order No. 7435529

75.352(a)

S&S

High Negligence

The Atmospheric Monitoring System (AMS) operator who was on duty when the mine
fire occurred on January 19, 2006, did not promptly notify the appropriate personnel
that an alarm signal had been generated.
Similar actions were taken by the AMS operator on duty on December 23, 2005, when a
fire occurred at the 9 Headgate longwall belt conveyor takeup storage unit. The AMS

106

 operator notified a miner to investigate the source of the alarms, but did not notify
appropriate personnel of alarm signals.
In these two fire events, the AMS operator on duty failed to promptly notify
appropriate personnel of alarm signals. This was supported by the fact that miners on
affected sections were not withdrawn to a safe location on these dates. This lack of
prompt notification significantly contributed to the delay of the withdrawal of the
miners on 2 Section and 9 Headgate longwall section to a safe location on January 19,
2006. This delay endangered miners due to the life-threatening and deteriorating
circumstances, and contributed to the inability of the two victims to escape the mine.
104(d)(2) Order No. 7435524

75.352(c)(2)

S&S

High Negligence

On January 19, 2006, an underground mine fire occurred at the 9 Headgate longwall
belt conveyor takeup storage unit. Atmospheric Monitoring System (AMS) alarm
signals were indicated for carbon monoxide sensors 81 and 82. Persons in the affected
areas were not notified of these alarms and were not promptly withdrawn to a safe
location identified in the mine operator’s Emergency Evacuation and Firefighting
Program of Instruction. The affected working sections during the fire that occurred on
January 19, 2006, included both 2 Section and 9 Headgate longwall section.
Two other fires occurred at this mine (December 23, 2005, 104(d)(2) Order No. 6643221,
and December 29, 2005, 104(d)(2) Order No. 6643222) during which carbon monoxide
sensors activated AMS alarm signals in the dispatcher’s office on the surface. In both
cases, the miners in the affected areas of the mine were not notified of the alarms and
were not withdrawn to a safe location. The mine operator’s repeated lack of proper
response to the carbon monoxide alarm signals is an indication of an attitude of
indifference to the requirements of 30 CFR § 75.352(c)(2). The delay in notification and
failure to promptly withdraw miners contributed to the inability of the two victims to
escape the mine on January 19, 2006.
104(d)(2) Order No. 7435538

75.1501(b)

S&S

Reckless Disregard

Mine management failed to initiate and conduct an immediate evacuation of the miners
working on 2 Section and the longwall when the conditions at the 9 Headgate longwall
belt takeup storage unit presented an imminent danger to the miners.
Mine management personnel were aware of a fire at the 9 Headgate longwall belt
takeup storage unit. The responsible person, designated by the operator for that shift,
was made aware of the fire by the belt examiner immediately upon discovery, and
failed to initiate and conduct an immediate mine evacuation.
The delay in conducting an immediate mine evacuation contributed to the inability of
the two victims to escape the mine on January 19, 2006.
107

 104(d)(2) Order No. 7435539

75.1725(a)

S&S

Reckless Disregard

The mine operator failed to maintain the 9 Headgate longwall belt conveyor in a safe
operating condition. Sworn statements taken from an eye witness indicated that a
carriage unit had become misaligned in the belt takeup storage unit which caused a
misalignment of the longwall belt conveyor. This misalignment created frictional
heating within the belt takeup storage unit.
In addition, the following conditions, some of which were indicative of prolonged
operation of the longwall belt conveyor system while the belt was misaligned, were
observed along the 9 Headgate longwall belt conveyor, and would have existed at the
time of the belt conveyor examination on the day shift of January 19, 2006:
1. Damaged and missing trip latch lever posts and damaged drop-off carriage
assembly trip latch levers that affected positioning of the drop-off carriage within
the 9 Headgate longwall belt takeup storage unit;
2. Damaged bottom rollers, bottom rollers on the ground with indications they had
been rotating in combustible material on the mine floor, and damaged top
rollers;
3. Damaged belt hangers, some partially cut through and others severed from
prolonged rubbing from misaligned belt;
4. Damaged belt takeup storage unit frame components, partially cut through from
prolonged rubbing of misaligned belt;
5. Severed strips of belt on the mine floor and hanging on belt structure;
6. Lengths of partially severed strips of belt;
7. Shavings of belt on the mine floor;
8. Belt cord fibers wrapped around belt roller components; and
9. Extended lengths of belt with frayed edges.
These conditions were obvious and located in the areas traveled by mine examiners.
These unsafe conditions warranted the immediate removal of the belt conveyor system
from service. Belt misalignment within the storage unit initiated the frictional heating
causing the mine fire on January 19, 2006, which ultimately resulted in the two fatalities.
104(d)(2) Order No. 7435532

75.400

S&S

Reckless Disregard

Accumulations of combustible material were present in the form of grease, oil, coal
dust, float coal dust, coal fines, and loose coal spillage at numerous locations along the
approximate 2,000 feet length of the 9 Headgate longwall belt conveyor.
These easily ignited accumulations quickly grew into the strong flaming fire needed to
ignite the flame-resistant belt. Once ignited, this belt quickly grew into an intense fire
that resulted in generation of copious quantities of hot, dense, toxic smoke.

108

 These conditions were obvious, extensive, and located in the areas traveled by the mine
examiners. The accumulations served as readily ignitable fuel that further contributed
to the ignition of the belt and to the severity and extent of the mine fire on January 19,
2006, which ultimately resulted in the two fatalities.
104(d)(2) Order No. 7435537

75.1202-1

S&S

Reckless Disregard

The mine operator did not keep the map required pursuant to 30 CFR § 75.1200 up-todate by temporary notations to depict the permanent ventilation controls constructed
and/or removed in the North East Mains. The map does not accurately depict the
location of permanent ventilation controls in the area of the No. 7 Belt tail pulley
necessary to separate the primary escapeway for 2 Section from the No. 7 Belt conveyor
entry. The designations of escapeways were not properly marked on the map by means
of symbols to accurately depict the underground escapeways.
The mine map was posted on the wall in the Superintendent’s Office where it could be
clearly seen and easily accessed by mine management. Although there were indications
the map was updated to track production-related activities such as the rate of retreat of
the longwall section and the development of the 2 Section, the temporary notations to
indicate construction or removal of permanent ventilation controls were not kept up-todate.
An up-to-date mine map would have alerted mine management and miners of the lack
of separation between the primary escapeway and the No. 7 Belt conveyor entry. The
inaccurate map resulted in the mine operator not correcting the lack of separation
between the primary escapeway and the belt entry. This lack of separation between the
primary escapeway and the belt conveyor entry allowed smoke and carbon monoxide
gas to inundate the primary escapeway used by the miners during the evacuation from
2 Section on January 19, 2006. Smoke from the fire adversely impacted the ability of
miners from 2 Section to escape, resulting in two fatalities.
104(d)(2) Order No. 7435548

75.351(k)

S&S

Reckless Disregard

Personnel who were assigned duties by the mine operator to install and maintain the
mine wide atmospheric monitoring system (AMS), were not adequately trained in the
installation of the system components. Personnel designated by the mine operator to
install and maintain the AMS had not received adequate training in the proper location
of section alarm units. There was no AMS alarm installed for the 2 Section miners to
receive automatic notification of CO sensor alarm signals.
The failure to automatically provide visual and audible signals on 2 Section
significantly contributed to the delay in the notification and withdrawal of miners who
were working on 2 Section when a belt fire occurred on January 19, 2006.

109

 104(a) Citation No. 7435540

48.7(d)

S&S

Reckless Disregard

The person designated by the mine operator as the dispatcher/AMS operator controlled
or directed haulage operations at the mine. The dispatcher/AMS operator on duty
when the mine fire occurred on January 19, 2006, was not adequately trained by the
mine operator in the mine ventilation system, firefighting procedures, and emergency
evacuation procedures. The dispatcher/AMS operator had insufficient knowledge of
the mine ventilation system and evacuation procedures outlined in the Mine
Emergency Evacuation and Firefighting Program of Instruction.
During the initial stages of the fire on January 19, 2006, the dispatcher/AMS operator
did not communicate to the appropriate personnel that an alarm signal had been
generated by the AMS, nor did he contact the affected sections to initiate withdrawal.
A similar lack of proper response was demonstrated by the dispatcher/AMS operator
on duty on December 23, 2005, when a fire occurred at the 9 Headgate longwall belt
conveyor takeup storage unit. The dispatcher/AMS operator notified a miner to
investigate the source of the alarms but did not notify appropriate personnel to initiate
withdrawal of miners from affected areas.
In these two fire events, the dispatcher/AMS operator on duty failed to notify
appropriate personnel of alarm signals. This was supported by the fact that miners on
affected sections were not withdrawn to a safe location on these dates. The
dispatcher/AMS operator’s training was not adequate to properly identify appropriate
personnel. The mine operator’s failure to provide adequate training significantly
contributed to the delay of the withdrawal of the miners on 2 Section and 9 Headgate
longwall section to a safe location on January 19, 2006. This delay endangered miners
due to the life-threatening and deteriorating circumstances, and contributed to the
inability of the two victims to escape the mine.

110

 North East Mains

  
 
 
 
 
 
  

8 Heodgote

   

elobpoeH LL

     

      
 
 
 
 

7 l?leangle

9105 10i 6
elobpoeH 0L

elobpoeH 5

6 Headgote

  

sumw 189M 

    
  

5 Headgote

5 Ta?gote

   

Mecca Shaft
and Fan

   

3 Mains

Ethel Shaft
and Fan

Melville Shaft
and Fan

  
   
    
 

Box Cut
Portal

 


7 

 

SU10W 189M 18L

 

APPENDIX A
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Active Underground Areas

LEGEND

Installed Conveyor Belt

 

 

O, I 000? 2000?
Rum Creek Portal BOX 

 

 

 

 AA - Corporate Communications

"Er-532.

 

 

MEMORANDUM

70-. All Deep Mine Superintendents
FROM: Den Blankenship

DATE: October 19, 2005

SUBJECT: RUNNING COAL

 

If any of yen have been asked by yeur group presidents, your supervisors, engineers or anyone
else to do anything smer than run coal (Le. bulld aver-casts, do jobs, or
whatever], yen need t0 ignore them and run coat. This memo is necessaryr only because we
seem not to understand that the coal pays the bills.



cc; Chris Adkins
Drexel Sher:

{mt-ram no: armed)

ARACOM 

 AA - Corporate Communications

?Eb-533



ch;

  

MEMORANDUM
Haney 
To: All Deep Him: Superior-Mimi:

FROM: Don Blankenship 

DATE: October H. 20:15

RE: MEMBERSHIP

 

By now each of you Should know that safety and 5-1 is our first responsibility. Producriviry anti
are second. It has been the culture of our Company for a long time.

Last week i sent each of you a memo on running coal. Some of you may have interpreted that
memo to imply that safety and 31 are secondary. I would question the membership of anyone
who thought that I consider safety to be a secondary responsibility.

The point is that each of you is responsible for coal producing sections, and our goal is to keep
them running coai. If you have construction jobs at your mine that need to he done to keep it

safe or productive. make every effort to do those jobs without taking members and equipment
from the coal producing sections that pay the bills.

LEW

ARACOMA003442

JOHNNY MCNEELY
Airway Walker

TONI DARDI
Third Shift Chief Electrician

BILLY HALL
Evening Shift Chief Electrician

JESSE JUDE
Hourly Electrician

JIMMY WELLS
Chief Electrician

CHARLES CONN
Safety Director

FRED HORTON
Second Shift Mine Foreman

PATRICK CALLAWAY
Production Foreman

LINDSEY WHITED
Belt Examiner

JIMMY JARRELL
Asst L/W Maintenance Chief

MARK KEYSER II
L/W Maintenance Chief

ROBERT MASSEY
Longwall Chief Electrician

ED ELLIS
Assistant L/W Coordinator

ACIE CLINE
Longwall Foreman

ANTHONY GIBSON
Longwall Foreman

ADAM TILLER
Section Foreman

TERRY SHADD
Box Supt. 002 Section

LARRY GIBSON
Belt Examiner

MIKE PLUMLEY
002 Section Foreman

LANNIE HOOSIER
Belt Examiner

TOM ATKINS
Third Shift Mine Foreman

MARK KEYSER SR.
Third Shift Foreman

DAVID R. RUNYON
L/W Evening Shift Foreman

BRIAN CABELL
Belt Examiner, Fireboss

PAUL SCOTT
Section Foreman

CLARENCE WORKMAN
Longwall Coordinator

JEFF PERRY
Belt Coordinator

DUSTIN DOTSON
Mine Foreman

LAWRENCE "Peppy" LESTER
Superintendent

GARY GOFF
General Manager

ROD MORRISON
Assistant Superintendent &
Longwall Manager

EDDIE LESTER
Vice President of Operations

DERRICK CHRISTIAN
Longwall Foreman

FRANK FOSTER
Safety Coordinator

CHRIS HERNDON
Outby Construction Foreman

DON HAGY
Outby Construction Foreman

ROBERT ELLIS
Superintendent of Maintenance

MANAGEMENT STRUCTURE
RELATIVE TO
ARACOMA COAL
JANUARY 19, 2006

SIMON STEPP
Mine Engineer

KENNY WILLIAMS
Chief Engineer

SID YOUNG
President

LINTON STUMP
Assistant Director of Production

DWAYNE FRANCISCO
President

KEITH HAINER
Director of Maintenance

LOGAN COUNTY MINE SERVICES

DEWAYNE FRANCISCO
Director of Underground Mining

ARACOMA COAL COMPANY, INC.

H. DREXEL SHORT
Senior Vice President of Group
Operations

H. DREXEL SHORT
Chairman

DON L. BLANKENSHIP
Chairman, CEO, & President

J. CHRISTOPHER ADKINS
Chief Operating Officer

MASSEY COAL SERVICES, INC.

MASSEY ENERGY COMPANY and A.T. MASSEY COAL COMPANY, INC.

Appendix B – Mine Management Structure

  

 

 

 

 

 

 

 

 

 

 

hh?th East Mains

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

North East Mains No. 2 2 Section Belt Discharge Pulley
- Belt Discharge Pulley 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   

 

 

 

 

 

II

 

 

 

 

 


?Ilj

mandoor 
mandoo mandoor [si man oor man 00F w? mondoor ?Uri if  iI i?l 1mm; i
i 


 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  
  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

It 



4-. +0

 

 

 

 

   

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   

 

 

North East Mains No. 1
Belt Discharge Pulley

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Ll 
mgndoor HA mandoor
SI mandoor  S gn
a sign  (t  

mandoor 
3 sign 

't
No. 7 Belt Drive
C,

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

    
 

2500 
longwaH

beH power
center/beH
starter

 

 

 

 

 

 

   
 

 

  

 

 




 

   

 

 

    

No. 7 Belt
Discharge Pulley

 

  

controller

carriage
assembly
Longwall Belt Drive

 

 

 

 

rear frame

mandoor
Sign assembly

Longwall Belt Takeup
Storage Unit

mandoo


sign
3

L0
I
(D i

doors open
I 
 
(2,2
(I)

 

2 Sectkwi

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 


63:Headgate .  
?0

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

APPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

mandoor
sign

 

Area Surrounding 9 Headgate Longwall Section

Notes: and 2 Section

Ventilation controls depicted as mapped during
the investigation. Alterations to permanent
ventilation controls made during rescue and
firefighting operations are shown in blue. LEGEND

mandoo mandoor 
5'9? mandoo Sign
sign

Primary Escapeway Reflective 

Roof Fall

 

BUD Cribs

I Survey Station (SS) Location and

Number
Roadway
Stopping

Hole in Ventilation Control Indicated

by Slash
Stopping with Personnel Door
Box Check Stopping

Overcast


(I)
U)
r?P
i

9

door 3 man door
open Sign
3

mandoo
sign

I

 

No. 6 Belt

Discharge Pulley

6 Headgate

 

 

 

 

 

 

 

 

mandoor
sign
Overcast with Personnel Doors
 Set of Equipment Doors
2  i 
mandoor 
Regulator

 

Seal

 

II EXXII 

sign  
Secton

 

Check Curtain

Installed Conveyor Belt

o? 100? 200?
Installed Belt Structure

 

 

 

 

 

 

 

 

 

 

 



CITIU
II r7

 

 

 

 

 

7r If Tl

 

 



    
   
  
    
    
   
   
  
 

  
  
 
 

    
  
 
   

  
   

    
    

    

Inline Intermediate Pinch IMP 'Otch PCA Corrhge. Detached Drop?off trip 'Otch 'ever?
. . ever post keeper, missmg . appeared damaged
Loading Section Assembly Roller 3353?: Carriage Assembly

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



Supply Flat

    
   

  
  

      
 

   
   
   

   
   

 
  

 
  
 

   
 

  

trip latch trip latch trip latch trip latch lever trip latch trip latch trip latch

    
      

Longwall Belt Longwall Mantrip Pear Frame

     
    

  
 
   

. . lever post lever post lever post post, damaged lever post lever, lever postrive Ca support, support, support, support, domoged damaged Assem I (P FA)
empty empty empty empty

 

PuHey Carnage
Assembly (PCA)

 

 

l3kwi\/ew cd LongwaH Beh:[hhwe 

. . SGCTIOH Asset-TIny 0 ?t If A with edn :thIZId tgsn?that thee Bligh?6(fo carblce to rerTioI/I/gmslagkJ Belt efrom thNeI conveeyvdi'ncbelt
Suspe?ded  carriage assemblies travel on. Pairs of system as the longwall tailpiece is pushed toward

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

approximately lO?foot long beams are connected the drive.
in series, one of each pair on either side of the
O?d StrUCture takeup storage unit, between the REA and the Trip Latch Grab Bar Trip latch grab bars are
winch frame. located on each side of the drop?off carriage
. .. Mantrip assembly and the end of the PCA facing the
Rear Frame Assembly (RFA) The portion of the drop?off carriage assemblies. The trip latch grab
belt takeup storage unit containing three 20?inch bars. enable the .trlp latch levers on the drop-Off
diameter pulleys, attached to the center section Carnage assemblles t0 attaCh the drop-Off .
beams, that provides the stationary end support carriage assembly to the PCA or to the preceding
0 0 . for the laps of belt in the storage unit. drop?off carriage assembly.
.. ROIler Ch Pulley Carriage Assembly (PCA) The portion of Ijeteh I?eVer TrIPdeteh IeVerS ere Ihete'ted
0 -- the belt storage unit containing three 20?inch 'h Pe're? Ohe 0h 0f 0 drop?Off Cerr'ege
 'j . diameter pulleys that travels along the center Eeeh 'e to be the some he'ght~
 section beams on four V?grooved wheels. The The he'ght 0f 0f tr'P Ieteh IeVerS
PCA provides the movable end of the storage unit from the Shortest IS to be ?tted
.  thet suppertS the tape of belt that are contained to the drop?off carriage assembly closest to the
Discharge Pulley approximately   -. in the unit. The further the PCA is located from RFA, t0 the tallest. which Is to be fitted to the
7 degrees -- the RFA, the more bett that is Stored in the belt drop?off carriage assembly that attaches to the
Belt Drive Pulley Carriage takeup storage unit. PCA-
The 0f.the 9 Headgete beIt entry 0 Drop?Off Carriage Assembly A drop?Off eerreige Trip Latch Lever Post Trip latch lever posts are
W03 7 degrees from herlzehtel- -. Assembiy  assembly contains multiple belt rollers thet installed in pairs at regular intervals along each
. DetQChed support the tape of belt in the belt takeup a: the cenrter fsectior?1 be10mr81i.t Each rpair is tfo tbe
. stora unit between the PCA and RFA. Ei ht some e'g . e'g 0 0 
  COl?l?lOge Assembiy drop_goff eerriege assemblies were Observed gin the latch lever posts.ascends from the shortest,
Headgete tehgwe? belt takeup storage unit. which are to be installed closest to the REA, to
or .. These assemblies travel along the center section the teIIe?t: Wh'eh are to be 'hSteIIed CIeseSt to
-- beams on four V?grooved wheels. Each drop?off W'he -
433 -- Rear Frame carriage assembly is fitted with trip latch grab
II ., bars and trip latch levers that enable connection
of the drop?off carriage assemblies to each other
-- and the PCA.
20? .. ..
529:5: 
0 The belt is pulled around the tail pulley and the top portion of the appropriate trip latch lever
discharge pulleys in the belt conveyor system by lever post.
9  Storage It the two electric motor driven drive pulleys of the
belt drive. The belt takeup storage unit functions As belt is removed from the storage unit, the
0 as the takeup by maintaining tension in the belt PCA is pulled toward the REA and drop?off
to enable the drive pulleys to move the belt. The carriage assemblies are sequentially reattached to
belt takeup storage unit enables storage of belt the PCA/drop?off carriage assembly "train".
to facilitate its removal in a practical manner for
operationcf the IongwaII mining System. When The pinch roller is a hydraulically powered unit
the PCA IS Closest to the RFA, the used to facilitate removal of belt from the takeup
drop?Off eerrlege ere eehheeted to storage unit. The belt is "pinched" between two
the PCA sequentlally In a traln . rollers and forced out of the the takeup storage
. . unit by the turning action of the rollers. The
Belt Is added to the storage unlt as the wInCh removed belt was manually laced onto a supply
pulls the PCA. Drop?off carnage assembIIeS flat car positioned adjacent to the pinch roller.
connected to the PCA are detached and left in
place .as the PCA advances toward the WinCh. A The belt in the takeup storage unit is depicted as
speCIfic drop?off carriage assembly becomes wrapped around the upper PCA pulley. However,
detached from the trip latch grab bar of the it was not determined which PCA pulley the belt
succeeding drop?off carriage assembly or PCA was actually wrapped around.
when the tri latch lever is raised as it contacts
Three 20?inch Diameter PCA Pulleys 

Winch Cable

 

  
 
 
  
  
 

 

 

Three Drop?off Carriage Assemblies Attached
to the Pulley Carriage Assembly
Conveyor Belt
Notes:
Floor elevations were determined from elevations
depicted on mine maps provided by the mine
operator. Roof elevations were estimated from
photographs depicting objects of know size.
Lever Individual components of the belt conveyor

system, many of which were located by a total
station survey jointly conducted by MSHA and the
mine operator, are intended to be depicted for
visual descriptive purposes only. All structural
and mechanical components are not shown.

 

 

Detached Drop?off Carriage Assembly

 

Portions of the suspended belt structure shown in
the Section side view was damaged by the
fire and fell from the roof. The belt structure
and other conveyor belt system components
shown are depicted as similar to how they likely
existed, based on information collected during the
investigation, before the fire and is for
demonstrative purposes only.

This mine map and drawing is not intended to be
a detailed mechanical drawing. Specific objects
may not be to scale. Observed damage of some

Drop?Oil Assembly takeup storage unit components is identified.

 

V?Groove Wheel

Trip Latch Grab Bar

0? I, 2?
SEE

 

   

APPENDIX 
MINE MAP AND DRAWING
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Center Section Beam Trip Latch Lever Post
St?e 

I)eta? eh/

 

 

 

 

 

 

 

. Trip Latch Lever 9 
OIC  Q?d AdeCei/Tt Splice Plate Post Support ondOperotuonDesinptuon

0 0

 

Carr

 

 

age Assenmies

mandoor
sign

not fully coated
with sealant

 

 

doors open
4?in ch
waterline

not fully coated

with sealant/

 

 
   
      

 

 

 
     
   
 

 

 

 

 

  

 


\x I

 

 

 

 

 

 
 

 

 

 

 
 

miner circuit
extended inby

 

 



 

 

   
 
 

  
 

North East
Mains No. 1
Belt

Discharge

  
   
    
  
   
 
 

  
 

 
 
 
 

power

center not fully coated

with sealant

 
  
    
 
 

personnel door,
on ?oor

    

CO sensor
longwall circuit

   
   
 

miner circuit
man door

sign

mandoor
sign

 
  
  

  
 

4-in ch
waterline

 
  
 

 

 

 

 

 

 
 

 

 

 
  

 

 

 

    
   
 
 

 

 

tvorth

 

:ast Ma

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

I
II 

 

 

 

 

 

 

 

 

 

 

SCSR, expended



Wk

8?Inch waterline
SOV 2 Section

extended toward

 

 

 

 

 

 

 

 

 

CO sensor

 

ANN

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

EIEIDEI

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

CO sensor\ 

 



 

 

 

 

 

 

 

 

 

 

belt, damaged\

 

 

 

 

 

 

 

 

 
 
   
   

 
 
 
 

    

 

 

 

 

 
  

/longwall circuit

 

 

 

 

 

belt takeup

 

 

 

 

sensor

 

 

  

-
VFO


VFO VFO 
SOV
mandoor

Discharge
Pulley

waterline sign

 
   
   

SOV

 

 

miner circuit

 

 

 

 

 

 

 

 

 

 

 

mandoor
sign mandoor
sign

I

 

 

 

 

 

 

 

 

 

 

 

 

 

~ ongwall circuit

 

 

 

 

 

/-mandoor I . .t 
Sign ongwa 

bottom cover belt raised Belt Drive

/?not fully coated
with sealant

 

 

 

 

 





3
$3
(D
CO

i
9

 

 

 

SCSR top and

bottom covers
No. 96103

 

 

 

 

Ii

 

 

 

 

 

 

 

 

 

 

 

    
 

  

 
 

 

 

belt out

 

4?inch
waterline

firehose
VFO

    
  
 
 
    

    
 
 

I

  
   

firehoses
firehose, did not
fit nearby VFO

foam machine-\

3

 





 

 

extent of heat
damage to
conveyor belt

(moved to splice)
belt, burned

  

 

 

 

 

VFO, valve
handle missing

0
high voltage
4_inch cable spliced
waterline I

4?inch waterline

  
 

firehose from
4?inch waterline

longwall circuit
not fully coated extended to
with sealant longwall section
I
not fully coated
with sealant

 

 

 

 

 

 

 

QIOEDOSH 6

     

 

 

 

bottom roller, . 
. 
detached one snde 

belt, damaged .
edge



waterline,
charred
belt crossover

sprinkler

missing hose


pipe nipple on floor

high voltage cable
cut (moved to
splice after

accident) CO sensor,
burned




2?inch waterline,
burned where dashed

AMS cable, on floor

high voltage cable cut,

.6 
ii!
phone, damaged

supply flat car

pinch roller hydraulic unit

row of concrete
wunch I


 



 

personnel
door on floor

AMS cable, on floor

pulley carriage
assembly (PCA)

fire extinguisher 

AMS cable, burned
where dashed

AMS cable, on floor

 

 

 

 

 

 

2?Inch waterline

bottom roller,

damaged
top roller, damaged

doors open
bottom roller, damaged 
CO sensor, unused I

CO sensor



bottom hanger, damaged I
bottom hanger, damaged

  
   

  

VFO
bottom hanger,
damaged

     
  

severed belt strips,
wrapped around

bottom roller 

      
   

 

   

severed belt strips,
wrapped around
bottom roller

    
 
    
  

partially severed
belt strips

belt out

 
  

  

  


CO sensor touch pad?\
I

I

AMS cable, on floor
VFO
end of burned
2?inch waterline
rear frame
assembly (RFA)
bottom roller,
against hanger
AMS cable 
CO sensor, new, unused-\







 



firehose, high
voltage cable
firefighting lance
firehose
waterline, belt, and
electrical cables
burned in fire area-I
I

No. 7 Belt

taH puHey

4?inch waterline,

burned where dashed
valved outlet, sh?
washdown hose (Cabell)

Longwall Belt drive
belt structure, damaged from
discharge pulley to PCA

pile of folded belt,

burned tool box
0? cans

  

mantrip

pinch roller

blocks on floor
(remaining from
removed stopping)



expended,

floating in water

(Hatfield)

Longwall Belt Takeup Storage Unit

bottom hanger,
damaged

belt damaged, folded
against hangers

pile of severed
belt strips

7 bottom roller,
damaged

belt, damaged, rubbing
frame and hangers

bottom roller,
against hanger

belt damaged, partially
severed strips

bottom hanger,
damaged

\bottom roller, indications
of rotating on mine floor

bottom roller, damaged

bottom hanger, damaged

belt, damaged edge

 

 

 

 

 

 

IL

 

 

 
   

 

 

 

 

 

 

 

 

SCSR bottom cover

SCSR bottom cover No_ 122599 (Kinser)

No. 109376 (Baisden)

  
  
 
 

SCSR bottom cover
No. 100000 (Hensley)

 

 

SCSR bottom cover
No. 102662 (Vanover)

 

roof fall occurred
after accident

SCSR bottom
cover No. 104970

(E. Mayhorr7


   

    

 

 

SCSR bottom cover
No. 114792 (Shull)

SCSR bottom cover
No. 122596 (Bragg)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



  
 

 

 

 

 

 

 

 

bottom 

 

 

 

 

 

green reflective
tag, melted

and beams

 

 

bottom
cover No. 83549

(B. Mayhorn)

SCSR bottom cover
No. 107363 (Hatfield)

No. 107521 (Plumley)

SCSR bottom cover
No. 100069 (Crouse)

SCSR bottom cover
No. 104946 (Hunt)


2 Section
mantrip

  

3

curtain installed
during rescue

pusddv

denim shirt

 

lunch bucket

(Hatfield)\


 

 

 

 

 

 

 

 

 

 

 

ii

 

 

 

 

 

 

 

I
I

at 
1 



 

 

 

 

 

 

 

 

 

 

 

 

 
 

miner?s belt and
SCSR No. 104948
(Cabell), burned
lunch bucket (Cabell)
belt structure and
rollers, stacked

high voltage
cable, burned

[hgh voltage cable

 

 

 

   

not fully coated

belt structure not with sealant

installed across roadway

 

 

 

 

 

 

 

 

I
ILII

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  
   
  
  

Kremnants of

dual switch house removed stopping

2500 longwall

center/belt starter

winch controller
concrete blocks,

 

 

4?inch waterline
extended toward
10 Headgate

.J

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

longwall circuit

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

stacked against rib

 

 

Longwa circuit
e.

 

 

 

 

 

 

 

Ellery Hatfieldnot fully coated
with sealant

 

 

 

 

not fully coated
with sealant


not fully co
with sealant

 

 

 

 

 

 

I
I

 

 

 

Notes:

Ventilation controls depicted as mapped during
the investigation. Alterations to permanent
ventilation controls made during rescue and
firefighting operations are shown in blue.

Locations of mapped Longwall Belt fire sprinkler
components in drive and discharge pulley area are
shown in Appendix U.

The acronym SOV indicates a waterline shut?off
valve.

The acronym VFO indicates a valved fire outlet.

 

 

   
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

APPENDIX 
MINE MAP

ARACOMA ALMA MINE MSHA ID No. 46?08801

ARACOMA COAL COMPANY, INC.

Affected Area of Mine
Portion of North East Mains

LEGEND
Primary Escapeway Reflective Tag
Roof Fall
Cribs

Survey Station (SS) Location and
Number

Roadway
Stopping

Hole in Ventilation Control Indicated
by Slash

Stopping with Personnel Door
Overcast

Overcast with Personnel Doors
Set of Equipment Doors

Seal

Check Curtain

Installed Conveyor Belt

Installed Belt Structure

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   

2 Section mantrip

   

goggles
SCSR top cover 

SCSR top cover

t/f
top coyer top cover
mou piece pug 
SCSR top cover\

/?gogg es
SCSR pouchV \safety glasses
SCSR top cover sweat Jersey

gogwes
lunch box

SCSR top cover 

   

 

 

 

 
    
  

 

 
 
 

 

 

  
 

 



  

/?gogg es
top cover

;//?hamrlner
0 es
SCSR top gg

goggles?
SCSR top cover?'


goggles?I/

SCSR top cover??

 

safety glasses



    
  
 
 

 

 

 

 

 

 

 

 

 

 

DD

DD.
DD:

a BBQ

   

SCSR top cover

 

  

North East Mains No. 1 Belt

curtain installed during
/rescue operations

 

curtain installed during

rescue operations 

 

  

 

 

 

 

 

personnel door
through which miners

traveled to North
East Mains belt entry

 

Note: Ventilation controls depicted as mapped
during the investigation.

roof fall occurred
after accident

 

 

 

 

 

 

 

APPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Affected Area of Mine 

Detail of Area Surrounding 2 Section Mantrip

 

 

 

 

 

 

 

 

 

LEGEND
[0 Primary Escapeway Reflective Tag
.-    Roof Fall
 BUD Cribs

3 Survey Station (SS) Location and
Number

Roadway
Stopping

Hole in Ventilation Control Indicated
by Slash

II

Stopping with Personnel Door

Check Curtain

Installed Conveyor Belt
0? 20? 40?
Installed Belt Structure



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

belt structure
not installed
across roadway

4:50 p.m.
Day shift longwall
crew reached surface
4:55 p.m.
Callaway and Rose entered mine from Box Cut
5:01 p.m.
Callaway and Rose called dispatcher
from 3-Way Intersection
5:14 p.m.
CO Warning and Alarm at Sensor 82
(21 second separation)
5:16 p.m.
CO Warning and Alarm at Sensor 81
(21 second separation)
5:33 p.m.
ALPHA Page sent out - "Aracoma lw
down on storage unit at mother drive."
5:45 p.m.
Miners on 2 Section boarded mantrip and evacuated from 2 Section
5:50 p.m.
Phone communication lost at longwall headgate
5:59 p.m.
AMS communication failures with Sensors 82 and 83
7:00 p.m.
E. Ellis and Morrison made air
change in 9 Tailgate-4 Right
area; observed smoke in the
area; waited and watched for
missing miners

6:00 p.m.
J. Adkins and Runyan left longwall section to investigate what was going on in
the longwall belt drive area; longwall crew assembled at the longwall headgate

2 Section crew traveled in smoke

6:04 p.m.
Noe entered mine from Box Cut with fire extinguishers

7:16 p.m.
E. Ellis and Morrison returned
to phone near 4 Right

6:05 p.m.
Longwall section lost electrical power; longwall crew left longwall section
6:08 p.m.
Longwall crew met Horton at No. 2 Cut-Thru.

2:20 p.m.
White completed pre-shift of
belt entries, then went to the
phone to call examination
report to Cabell on the surface

3:35 p.m.
Miners who worked day shift in 9 Tailgate passed the longwall
belt drive area leaving the mine - no unusual conditions noticed;
White then walked to 9 Headgate longwall section to ride out with
the longwall crew; White passed by the longwall belt takeup
storage unit (the longwall belt was not operating at the time);
White observed no hazardous conditions

2:30 p.m.
Hagy reported 0.0% methane
concentration at longwall belt drive;
on the surface, Cabell recorded
White's pre-shift examination, then
entered the mine and walked the
belt entries toward 9 Headgate

6:10 p.m.
CO Warning at Sensor 71

delay in notification of 2 Section miners
due to lack of AMS alarm unit

4:20 p.m.
Longwall belt started

6:19 p.m.
AMS communication failure with Sensor 80

4:00 p.m.

3:50 p.m.
Cabell arrived at the longwall belt
drive area (longwall belt was not
operating)

3:48 p.m.
Afternoon shift 2 Section crew arrived
on 2 Section; day shift 2 Section crew
left shortly thereafter

3:30 p.m.
White called Cabell on the phone; White opened
equipment doors for 2 Section crew passing through area;
no unusual conditions noticed by 2 Section crew

3:25 p.m.
White received call from longwall section;
longwall production was to be ceased for routine
maintenance – replace bits on shearer, remove
longwall belt structure near tail

6:00 p.m.

4:25 p.m.
Day shift 2 Section crew
passed the longwall belt
drive; no unusual
conditions noticed

7:00 p.m.

6:31 p.m.
Miners got spare
SCSRs and curtain from
longwall section

4:45 p.m.
Day shift 2 Section
crew reached
surface
4:31 p.m.
ALPHA Page sent
out - "Aracoma lw
has been running for
about 10m."

Between 8:00 - 8:30 p.m.
Asbury (Elk Run Mine Rescue
Captain) called by company
representative

6:20 p.m.
E. Ellis, Morrison, Shadd, Dotson, R. Massey
entered mine from Box Cut

5:00 p.m.

4:00 p.m.
Day shift 9 Headgate
longwall crew departed
longwall section for mantrip
3:55 p.m.
Afternoon shift 9 Headgate
longwall crew arrived; longwall
belt was not operating

7:55 p.m.
Mine operator reported
fire to MSHA (Kline)

6:15 p.m.
AMS communication failure with Sensor 82 ;
2 Section crew met 9 Headgate longwall crew

3:41 p.m.
ALPHA Page sent out - "Aracoma lw
down on bits & structure, EST 10m."

3:00 p.m.

7:33 p.m.
Mine operator reports fire to
WVMHS&T(Boggess)

6:13 p.m.
2 Section miners arrived entered intake outby longwall belt drive

longwall belt operating

2:00 p.m.

7:18 p.m.
Horton told 2 Section
and longwall crews
to leave mine

6:23 p.m.
Miners traveled to
longwall section to
gather supplies

6:01 p.m.
Search conducted for missing
miners in heavy smoke
firefighting activity
by Cabell,
Callaway, and
Rose

Rose went to retrieve
additional fire
extinguishers; two
additional fire
extinguishers were
discharged; Cabell
attempted to connect
a firehose; Cabell
found no water in
waterline; Callaway
traveled to No. 7 Belt
Discharge pulley
area and fully
opened the No. 7
Belt waterline
shut-off valve

6:00 p.m.
Ten 2 Section crew members
entered the North East Mains
belt entry; two miners were
determined missing

8:00 p.m.
Kline called other MSHA officials
7:50 p.m.
First Logan County EOC contact Inspector Mullins learned of fire by Phone
7:45 p.m.
Production crews out of mine Conn arrived at mine (East
Kentucky mine rescue team
captain)
7:40 p.m.
Crews left No. 1 4-Way Intersection ;
underground freshwater pumps de-energized
by Hall on the way out of mine

5:52 p.m.
After encountering smoke too dense to continue driving
mantrip, 2 Section crew exited mantrip and continued
evacuation in heavy smoke on foot

5:38 p.m.
Horton and Hall arrived in the fire area
5:34 p.m.
Brown called 2 Section – no
response; Brown then set off signal
light on the 2 Section pager phone no response

5:33 p.m.
Callaway returned from opening the No. 7 Belt waterline
shut-off valve; management officials on surface learned of fire;
call for evacuation already made to dispatcher by Cabell

5:18 p.m.
Grimmett entered mine from the Box Cut with chain rachet for longwall belt
takeup storage unit ; Callaway and Rose arrived at longwall belt drive and saw
smoke; Rose saw flames after exiting the mantrip; Cabell discharged first fire
extinguisher while Callaway parked the mantrip
5:16 p.m.
While Cabell talked with Horton, smoke in longwall belt drive area increased;
Cabell saw glowing embers and told Horton there was a fire
5:12 p.m.
Cabell called for Horton to find out when help would arrive; Brown first answered the
phone; Horton joined the conversation
5:06 p.m.
Cabell interupted Richardson's call with dispatcher and told Richardson
he had shut off the belt, there was smoke at the longwall belt drive, he
would find the cause, and would get the belt operating shortly

Prior to 5:00 p.m.
Cabell observed longwall belt misaligned,
rubbing a bearing in takeup storage unit,
and a small amount of smoke; Cabell
attempted to align a skewed drop-off
carriage assembly in the longwall belt
takeup storage unit; unsuccessful, Cabell
then called Horton for chain ratchets to
correct the condition

6:48 p.m.
L. Lester entered mine
from Box Cut; Noe at
4-Way Intersection

5:53 p.m.
2 Section crew donned SCSRs in heavy smoke

5:39 p.m.
North East Mains and 2 Section belts stopped by
Brown to gain attention of 2 Section miners

5:05 p.m.
Cabell stopped the longwall belt

8:01 p.m.
Logan 911 EMS Service called
from mine and radios requested

6:21 p.m.
ALPHA Page sent to
L. Lester – "Peppy
call Aracoma VERY
IMPORTANT."

5:47 p.m.
B. Mayhorn and Baisden were picked up just outby 2 Section

9:00 p.m.

8:15 p.m.
Mullins arrived at mine

7:00 p.m.
Began calling mine
rescue teams from
mine

5:55 p.m.
SCSR's donned, the 2 Section
crew made their way toward the
personnel door through the smoke
filled intake entry

5:42 p.m.
2 Section foreman Plumley called Brown – Plumley
told to evacuate 2 Section crew by Brown and Horton

3:08 p.m.
Longwall crew finished fourth pass
delays on fourth pass: 57 minute delay belt down; 15 minute delay - cutting rock

8:00 p.m.

7:30 p.m.
On way toward 9 Headgate, E. Ellis
and Morrison met crews exiting mine
7:21 p.m.
2 Section and longwall
crews leave mine
7:17 p.m.
AMS communication failures
with multiple sensors
7:15 p.m.
Check curtains installed in
longwall headgate entries
7:13 p.m.
CO Warning at Sensor 79

Between 8:30 - 9:30 p.m.
East Kentucky mine
rescue team members
began to arrive at mine

8:40 p.m.
Mullins issued 103(k) Order (MSHA)

 Appendix H –Mine Rescue Teams and Team Members
MINE RESCUE TEAMS
The following mine rescue teams were contacted during the rescue and recovery efforts:
Alliance Resources, LLC
Excel Mining, LLC Mine Rescue Team
Roger Thacker
Robert Fletcher
Bobby Patrick

Gregory Carroll
Mark Fitch
John Ray
Woodrow Slone

Rodney Maynard
Mike Richards
Dwayne Thaxton

Consol Energy, Inc.
Consol Energy Buchanan #1 Mine Rescue – A-Team
Archie Ruble
Dave Goad
Elizabeth Chamberlin

Danny Quesenberry
Scott Honaker
Gerald Saunders

Tim Bandy
Reggie Lambert

Consol Energy, Inc.
VP-8 Mine Rescue Team
Dennis Perry
Andy Sawyers

Glenn Thompson
John Teets

Chris Whitt
Matt Lane

Consol Energy, Inc.
Consol of Kentucky Mine Rescue Team
James Kelly
Jeff Webb
Leroy Young

Tony Benton
Jeremy Webb
Marshall Fugate

Denny Combs
Joey Samons

Cumberland Coal Resources, LP
Cumberland Mine Rescue Team
Robert Drzazgowski
Gary Valusek
Harry Powell
Robert Bohach

Almon Tressler
David VanSickle
Jerry High
Bernard Cafferey

Robert Hutchinson
Eugene Manchas
Preston Toney

Dickenson-Russell Coal
Dickenson-Russel Coal Mine Rescue Team
Team responded to the mine site, but did not participate in rescue or recovery activities.
1

 Appendix H –Mine Rescue Teams and Team Members

Eastern Associated Coal, LLC.
Federal No. 2 Mine Rescue Team
John Sabo
Richard Matheney
Harry McGinnis

Gary McHenry
John Toothman
Roger Carpenter

Timothy Fleeman
Robert Brown
Roger Carpenter

Eastern Associated Coal, LLC - Peabody Coal Co.
Southern Appalachia Operations Team
Harvey Ferrell
Danny Acord
Jeff Spratt
Kyle Blair

Keith Reeves
Jackie Repass
David Blankenship
Danny Spratt

Wayne Stafford
Terreal Blankenship
Joe Runion

Foundation Coal
Emerald Mine Rescue Team
Gary Bochna
Bill Davisson
Tom Oliger
John Gallick

David Thearle
Jasson Detrick
Dave Rice, Jr.
Tom Rager

Tom Bochna
Emmitt Cox
J.D. Pekar

Foundation Coal – Riverton Coal Production, Inc.
Riverton Coal Production Team
Ronnie Ooten
Elmer Perry
Mark Jerasnek

Mitchel Bryant
Jarrod Sisko
Mark Schuerger
Randy Hansford

Matt Simpkins
Ernie Bartram
Ed Rudder

International Coal Group
ICG Viper Mine Rescue Team
Team was contacted and placed on standby, but did not travel to the mine.
Jewell Smokeless Coal Corporation
A- Team
J.P. Richardson
Ervin Grimmett

Joe Ratliff
Rodney Justice
Richard Waddell

2

Scott McGlothlin
Nick Osborne

 Appendix H –Mine Rescue Teams and Team Members

Jewell Smokeless Coal Corporation
B- Team
Elmer Vandyke
Chad Gibson

Randy Taylor
Avery Stollings

Jessie Elswick
Gerald Kendrick

Lone Mountain Processing, Inc.
Lone Mountain Processing, Inc. Mine Rescue Team
Ronnie Smith
Tim Gooden
David Shackleford

Greg Brashears
Jude Johnson
Jim Vicini

Freeman Crosby
John Rutherford

Massey Energy
Massey Energy East Kentucky Team
Nathan Mounts
Paul Adkins
Mike Jude
Frank Foster

Eric Jewell
Steve Coleman
Preston Cantrell
Charles Conn

Steve Miller
Chris Prater
Bill Linkenhoker

Massey Energy
Southern West Virginia Mine Rescue Team
Rob Asbury
Mike Vaught
Jamie McClaugherty
Johnny Robertson

Jim Aurednik
Jeremy McClung
Mike Alexander

Shane McPherson
John Click
Jamie Ferguson

Mine Safety and Health Administration
Mine Emergency Unit
Ron Hixson
Thomas Todd
Mike Hicks
Clark Blackburn
Bob Clay
Jeffery Kravitz

Charles Pogue
Jan Lyall
Jerry Cook
Mack Wright
Jim Langley
John Gibson

3

Virgil Brown
Frank Thomas
Otis Matthews
Fred Martin
Fred Fugate
Edward Chuta

 Appendix H –Mine Rescue Teams and Team Members

Mingo Logan Coal Company
Mountaineer Team
Eddie Lawson
Dick Beauchamp
J. Matt Murray

Rockey Pope
Shawn Grimmett
Dickie Estep

Brad Birchfield
Terry Shearer
Brian Keaton

Mountaineer Mine Rescue Association, Inc.
Blue Team
Gerald Lucas
Thomas Dove

Burge Speilman
Steve Williams

Mark Short
Jeff Hartley

Mountaineer Mine Rescue Association, Inc.
Gold Team
Robert Hill
Barry Mullens

George Lawson
John Lewis
Terry Tolley

Fred Bennett
Dale Adkins

Paramont Coal Company Virginia, LLC
Paramont Blue Team
Andy Anunson
Jamie Ratliff
George Sailers
Johnathan Shelton

B.J. Stanley
Mark Williams
John McCoy
Jim Rose

Tivis Johnson
Chuck Morris
Gary Bowman
Jerry Bledsoe

Pinnacle Mining Company
Blue Team
Richard Crockett
Mike Vickers

Mike Plumley
Darren Blankenship
Larry Hedrick

Bob Perry
Sampey Bailey

Pinnacle Mining Company
Gray Team
Steve Stanley
Jimmy Surat

Jim Bennett
Don King

Mark White
Doug Williams

4

 Appendix H –Mine Rescue Teams and Team Members

Pocahontas Mine Rescue Association, Inc.
Pocahontas Mine Rescue Team
Vince Cantrell
Douglas Pauley
Woodrow Williamson
Dewayne Bishop

Michael Williams
Dennis Donathan
Randolph Richardson
Jeff Donathan

Danny Cregger
Steve Stinson
Jerry Rhodes

Southern Coalfield Mine Rescue Association, Inc.
Southern Coalfield Team 1
Brad Justice
Tim Morgan
Mark Taylor

Rodney Blankenship
Mike Stover
Carl Cohenour

Mike Lucas
Ricky Carter

West Virginia Office for Miners Health, Safety & Training
WV Mine Emergency Team
Mike Rutledge
Randy Smith
Eugene White
Phil Adkins

Barry Fletcher
Bill Tucker
Jeff Bennett
Jim Hodges

5

John Scott
Clarence Dishmon
John Hall
Steve Cox

 Appendix I - Victim Data Sheet

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Accident Investigation Data - Victim Information U.S. Department of Labor 
Event NumberMine Safety and Health Administration
Victim Infonna?on: 1
1. Name of Employee: 2. Sex 3. yicli'm's Age 4. Last Four Digits of SSN: 5. Degree of Injury:
Eiiery Hatii'eid 46 01? Fatai
6. and Time(24 Hr.) Of Death: Date and Time Started:
a. Date: D. Time: F500 a. Date: oTirne: 2330
s. RegularJop Title: 9. Work Activity when Injured: 10. Was this work activity part of regularjoo?
5.12 Boggy; OPERA TOR 022 Evacuation during mine tire Yes I IND I I
11' Experience Years Weeks Days Years Weeks Days Years Weeks Days Years Weeks Days
a_ This In. Regular 5; This d. Total
Work Activity: ?it 26 0 Job Title: 4 0 Mine: 4 26 0 Mining: 11 2s a
12. What Directly Inflicted Injury or Illness 13. ature of Injury or Illness:
945 Bait Fire 119 
14. Training Deficiencies:
Hazard; I I Nethewly?Employed Experienced Miner: I I Annual: I I Task: I I

 

15. Company of Em ploym different from production operator)
Independent Contractor ID: (if applicable)

 

 

 

 

 

 

 

 

 

Operator

16. On?site Emergency Medical Treatment

Not Applicable: I  First?Aid: I  CPR: I EMT: I I Medical Professional: I I None:  I
Part SD Document Control Number: (form TODD-1) 18. Union Affiliation otVictim: 9999 None (No 
Victim Infonna?on: 2
1. Name of Employee: 2. Sex 3. Victim's Age 4. Last Four Digits of SSN: 5. Degree of Injury:

Don Bragg 3.3 01? Fatai
6. and Time(24 Hr.) Of Death: Date and Time Started

a. Date: D. Time: 2:30

 

a. Date: 0?;?19?2006 D. Time: 3'00

 

 

 

 

 

s. RegularJop Title: 9. Work Activity when Injured: 1o. Was this work activity part of regularjoh'?
014 Ronggj?fer 922 Evacuation dun'ng mine fire YES I INU I I
1a1I'TIErispenencei Years Weeks Days Regular Years Weeks Days C: This Years Week Days Total Years Weeks Days
Work Activity: 9 25 9 Job Title: 4 9 9 Mine: 2 34 9 Mining: 9 2,5 .5:
12. What Directly Inflicted injury or Illness? 13-Na?fure UT lniur?r Dr 
945 Belt Fire 110 Carbon Monoxide intoxication

 

 

14. Training Deficiencies:
Hazard; I I NewiNewlyEmployed Experienced Miner:I I Annual: I I Task: I I

 

15. Company of Employment (If different from production operator)
Independent Contractor ID: (if applicable)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Operator

15. On?site Emergency Medical Treatment:

Not Applicable: I I First?AidMedical Professional: I I None: I I
IIPBIT 50 Document Control Number: [form Union  of Victim:

Victim Information:
1. Name of Employee: 2. Sex 3. Victim's Age 4. Last Four Digits of SSN: 5. Degree of Injury:
6. and Time(24 Hr.) Of Death: T. Date and Time Started:
a. RegularJoo Title: 9. Work Activity when Injured: 10. Was this work activity part of regularjoo?
Yes I I I

11- Expe?enca Years Weeks Days Years Weeks Days Years Week Days Years Weeks Days
a_ This in. Regular c: This d. Total
Work Activity: Job Title: Mine: Mining:
12. What Directly Inflicted Injury or Illness 13 Nature of Injury 
14. Training Deficiencies:

Hazard; I I NewiNewa?Employed Experienced Miner:I I Annual: I I TESK I I

 

15.Company of Em ploym ent:(lf different from production operator)
Independent Contractor ID: (if applicable)

 

16. On?site Emergency Medical Treatment:
I Fir5t_Aide I I I EMT: I I MedicalF'rofessional: I I None: I I

Part 50 Document Control Number: [form 18. Union Affiliation Df Victim:

 

MSHA Form Dec 1994 Printed D2i15i2ElD'i? 3:31:38 PM

Appendix J – Investigation Participants
ARACOMA COAL COMPANY, INC.
Charles Acord
Jamie Adkins
Jason Adkins
Gary Baisden
Nicholas Baisden
Larry Browning
Billy Brown
Gary M. Brown
John Brown
Bryan Cabell
Patrick Callaway
Brian Caserta
Elbert James Clay
Brandon U. Conley
Charles Conn
Randall Crouse
Timothy Dingess
Dustin Dotson
Joey Duty
Bryson Ellis
Edward Ellis
Chad Evans
Kevin Evans
Kevin Ferguson
Dwayne Francisco
Anthony Gibson
Gary Goff
Raymond Grimmett
Donald Hagy
Billy Hall
Bucky D. Harvey
Steven Hensley
Chris Herndon
Fred Horton
Joseph F. Hunt
Jimmy Jarrell
Jesse J. Jude, II
Mark Keyser, II
Mark Keyser, Sr.
Patrick W. Kinser
Arnold Lane

Longwall Move Crew
Maintenance Foreman
Continuous Miner Operator
Shuttle Car Operator
Construction Crew
Longwall Headgate Operator
Longwall Setup Crew
Dispatcher
Utility Man
Belt Examiner
Foreman
Shield Operator
Longwall Move Crew
Utility Underground
Safety Director
Roof Bolter Operator
Outby Electrician
Mine Foreman
Electrician
Electrician
Longwall Foreman
Supply Tractor Operator
Longwall Move Crew
Mechanic/Welder
President
Longwall Foreman
General Manager
Grader Operator
Outby Construction Foreman
Chief Electrician
Roof Bolter Operator
Continuous Miner Operator
Outby Construction Foreman
Afternoon Shift Mine Foreman
Shuttle Car Operator
Assistant Longwall Maintenance Chief
Hourly Electrician
Longwall Maintenance Chief
Third Shift Foreman
Shuttle Car Operator
Shield Operator
1

 Appendix J – Investigation Participants
ARACOMA COAL COMPANY, INC. (continued)
Eddie Lester
Eric Lester
Lawrence Lester
Brandon Lusk
Steve Marcum
Robert Massey
Billy Mayhorn
Elmer Mayhorn
Billy J. Maynard
Brad Maynard
Johnny McNeely
David Meade
Rodney Morrison
Chad Neil
Joshua F. Noe
Roger Ooten
Jeff Perry
Michael Plumley
Kirby Puett
Gary Richardson
Wyatt Robinson
Jonah Rose
David Runyon
David R. Runyon
Dave Sanders
Paul Scott
Terry Shadd
James L.B. Shelton
Harold Shull
Shawn Sturgell
Darrick VanNatter
Thomas D. Vanover
Jimmy Wells
Carl White
Clarence Workman
Jerry Workman

Vice President of Operations
Outby Utility Man
Superintendent
Roof Bolter Operator
Electrician
Longwall Chief Electrician
Continuous Miner Operator
Roof Bolter Operator
Continuous Miner Operator
Utility Outby
Airway Walker
3 Section Foreman
Assistant Superintendent & Longwall Manager
Longwall Electrician
Roof Bolter Operator
Beltman
Belt Coordinator
2 Section Foreman
Dispatcher
Longwall Headgate Operator
Beltman
Roof Bolter Operator
Outby Beltman
Evening Shift Longwall Foreman
Shearer Operator
Production Foreman
Box Superintendent/2 Section
Dispatcher
Electrician
Roof Bolter Operator
Longwall Move Crew
Scoop Operator
Chief Electrician
Beltman
Longwall Coordinator
Longwall Move Crew

2

 Appendix J – Investigation Participants
LOGAN COUNTY MINE SERVICES
Robert Ellis
William B. Stapleton
Simon Stepp
Jamie Vanover
Kenny Williams
Sid Young

Superintendent of Maintenance
Engineer
Engineer
Surveyor
Chief Engineer
President

MASSEY COAL SERVICES, INC.
J. Christopher Adkins
Frank Foster
Dwayne Francisco
Keith Hainer
H. Drexel Short

Chief Operating Officer
Safety Coordinator
Director of Underground Mining
Director of Maintenance
Chairman

ALPHA ENGINEERING SERVICES, INC.
Gary M. Hartsog

Mining Engineer

CONTINENTAL CONVEYOR
Mike Ray Williams

Service Technician

LOGAN COUNTY EMERGENCY MANAGEMENT
Roger Bryant
Marilyn Crosby

Dispatcher
Supervisor

MINE SAFETY & HEALTH ADMINISTRATION
George Aul
Dennis A. Beiter
Anthony L. Burke
Robert D. Cline
Jason E. Cox
David S. Creamer
William Crocco

Mining Engineer
Supervisory Mining Engineer
Coal Mine Safety & Health Inspector
National Mine Academy Instructor
Audiovisual Production Specialist
Chemist
Accident Investigation Program Manager
3

 Appendix J – Investigation Participants

MINE SAFETY & HEALTH ADMINISTRATION (continued)
Kim S. Diederich
Howard C. Epperly
Michael G. Finnie
William J. Francart
Kevin L. Hedrick
Mike A. Hockenberry
Scott K. Johnson
Timothy L. Justice
Jeffrey H. Kravitz
Jason D. Lane
Brian R. Malin
David S. Mandeville
Jason C. Middleton
Andrew C. Moore
Clarence W. Moore
Thomas A. Morely
Kenneth A. Murray
Randy A. Thompson
Rhodes Ooten
Craig D. Plumley
Charles W. Pogue
Mark A. Pompei
Mark E. Schroeder
Joan C. Sesco
Jimmy A. Soard
William R. Spens
Ronald W. Stahlhut
David A. Steffey
Donald A. Sulkowski
Dave Thompson
Derrick M. Tjernlund
David Trent
Jerry W. Vance
Jeffery N. Waggett
Chris A. Weaver
Arlie A. Webb

Mining Engineer
General Engineer
Supervisory Special Investigator
Mining Engineer
Electrical Engineer
Fire Protection Engineer
Coal Mine Safety & Health Inspector
Coal Mine Safety & Health Inspector
MEU Coordinator
Electrical Engineer
Electrical Engineer
Mining Engineer
Information Technology Specialist
Electrical Supervisor
Mining Engineer
Mining Engineer
Coal District 6 Manager
Mining Engineer
Coal Mine Safety & Health Inspector
Mining Engineer
Roof Control Specialist
Mining Engineer
Mining Engineer
Program Analyst
Mine Safety & Health Specialist
Supervisory Mine Safety & Health Specialist
Electrical Supervisor
Mining Engineer
Mining Engineer
Coal Mine Safety & Health Inspector
Senior Fire Protection Engineer
Coal Mine Safety & Health Inspector
Mine Safety & Health Specialist (Training)
Civil Engineer
Supervisory Coal Mine Safety &Health Inspector
Supervisory Special Investigator/Staff Assistant

4

 Appendix J – Investigation Participants

MSHA OFFICE OF THE SOLICITOR
Daniel M. Barish
Keith Bell
Marne Mitskog

Attorney
Attorney
Attorney

NATIONAL INSTITUTE FOR OCCUPATIONAL SAFETY & HEALTH
John Kovak
Robert R. Stein

Physical Scientist
General Engineer

PYOTT-BOONE CORPORATION
Doug Coon
Joey A. Davis

Director of Sales & Engineering
Computer Technician

SPILMAN, THOMAS & BATTLE, PLLC
David Hardy
Mark Heath

Attorney for Aracoma
Attorney for Aracoma

WEST VIRGINIA OFFICE OF MINERS’ HEALTH, SAFETY & TRAINING
Dennie C. Ballard
Willie Barker
Richard Boggess
Tim Bradford
Danny Cook
Steve Cox
Terry Farley
Mote Heib
John D. Higginbotham
John Kinder
Harry Linville
C.A. Phillilps
William Tucker
Eugene White

Assistant Inspector-at-Large
Safety Instructor
Inspector
Attorney
Electrical Inspector
Safety Instructor
Health & Safety Administrator
Chief Engineer
Engineer
Inspector
Inspector-at-Large
Deputy Director
Assistant Inspector-at-Large
Contractor Inspector

5

 EH5.

12-24-05 827 
12-31?05* 970 
01-07-06 1.005 0
01-14?06 985 0.
01-21?06 703 0

DD 
12-24-05 1,129 0.0% CH
DU 12-31-05* 1,298 0.0% CH
01-07-06 1,540 0.0%
DU CH4
01-14-06 1,605 0.0% CH
DU 01-21-06 836 0 0% CH


 01-21-06 
am}
mama
31m t6
a1 6 HeadgG 
gal UPS 
0 0 @se0

mama 

?at-05 967 0.0% CH4

DUB are ?smza?s



12-24-05 48,087 -

 

 

 

 

 

l?ar?w EOSI CKDCI
C3 C3

1]




a



IJEIJEKJ
6

 

 




 

 

etabpaeH 5




  

10,140 -
9,874 -

CKH

LangwaH
Sec?an

 

9.0M

01-21-06 -


D.

01-02-06 thru 01?19-06,

0 ations in the Pre-Shift - Onshift

Report mine record books

eadgate longwall section
air movement at MP-A





 



mm mm 


Cut?Thru

 

 

 






E11


CH3







i

 



ee??e

DD

 

 

 

 

 




 

 



 

EJEKJEMJEJEJED

DEED

DD




 

 

 

 




CICICI





 



12-24-05 11,745 

 

 

 

 

 

am] 
 gages as


gge?wawy

DUES

DUE . 
DD 5 Tom 0 
E1 
UUDU ODDS

gamma DDS

dg% DUDE QQ ii
DEED geesamgmt
Mecca Sha?. DPD QQDB 
 01?21?06 46,967 0 0% CH
DD
and Fan 
[153 
 01?21?Ell  SUEDE DDGCIDCIDCIIZHZICICIIZI CID
1%
Em

  
DUDU . .

   
9 01?21?06 

6% 1331.43; 5.12273  
gigig?g $31131):  11.0% CH4
QQ
43%
 mm (approximate locations)
g?smem: d9
01-07?06 459,738 - 
01-14-06 472,512 - 
 01-21-06 473,630 
26,8 Melville Shaft 
and Fan

Bax Cut
9 QQ a 
<st
o? wags; 182% 
0000 81:12:82 1,769 90% CH:
0%

Q?b 
be

 
 
 
  
   

 

Houses 

9
24-05 226,680 

CJEJEZJEJEJEJCIEICDEJU

 



DUDE

E3 



12-24-05 12,870 - 12?24?05 19,526 
12-31?05* 15,450 - 12?31?05* 31,950 
01-07-06 11,730 - 01?07?06 20,030 
01-14?06 12,985 0.0% CH. 01?14?06 31,210 
01-21?06 - - 01?21?06 


13:31:85: 119638332: 
DDS 1215815 9:07. 

Q1:
DD
C) 2 Schan a;
j: C)
(D CL
(Q

r?l?




 

 

 

 



EJCHHEHUCIUCIJCJ Ek? 
UDD


DDUDDQ DD

355mm: 



DDS 


Ethel
and Fan

Shaft

 

 

 

 

MATCH TO 

 



12-24?05 1,154 0 0
12-31-05* 2,037 0.0% CH
01-07?06 1,157 0.02% CH4
01-14-06 1,136 00% CH

01-21-06 -

    
 

 

1;Emmjm?amm

 

m1

 

MATCH TO APPENWX 

Notes:

Air quantity measurements and methane
concentrations (for all locations except and
were obtained from the Weekly
Examinations for Methane and Hazardous
Conditions mine record book. The associated
dates denote the week ending dates listed in the
mine record book.

AMS event log information, interview statements,
and enforcement records indicated the
direction of airflow in the 9 Headgate longwall
belt air course was not constant. At times it
was found moving toward the longwall face; at
other times it was found moving toward the
longwall belt drive.

The 2 Section intake and return air quantities
were reportedly measured outby the last
permanent stoppings. The actual location
changed as the section was advanced.

The actual location of and
moved as the longwall panel No. 9 was
mined.

and were not listed in the
Weekly Examinations for Methane and Hazardous
Conditions mine record book.

Asterisk indicates no week ending date entered
in the Weekly Examinations for Methane and
Hazardous Conditions mine record book. Date
shown in this appendix for these was based on
other entries.

A dash in the record book information depicted
indicates no entry in the Weekly Examinations for
Methane and Hazardous Conditions mine record
book.

Ventilation controls depicted as prior to fire.

Roof falls are not shown.

500? 
Ei??lg?ii

 

APPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Mine Ventilation
Map 1 of 2

LEGEND

Intake Airflow

ll

Return Airflow

Belt Airflow

Stopping

Hole in Ventilation Control Indicated
by Slash

I

Stopping with Personnel Door
Box Check Stopping

Overcast

Overcast with Personnel Doors
Set of Equipment Doors

Regulator

ll 1

Seal
Check Curtain

Installed Conveyor Belt

 l

 

 

 

 2,112 0.0% CH4
01?14?06 1,769 0.0% CH4
01?21?06 - -



      
   
  

 



  

EH

12-24-05 6,144 0
12-31-05* 5,685 0. 4
01-07-06 7,025 0.0% CH4
01-14-06 6,146 0
01-21-06 6,348 0

 

MATCH TO APPENWX 

 

 

 

IDIZUDIZIIZICIDCIIZII

 

w?

 


12-24?05 1,154 
12-31-05* 2,037 
01-07-06 1,157 

01-14-06 1,136 
01-21-06 


 
  
 



I -


EM

12?24-05 4,702 0.0% CH4
12?31-05* 1.888 0.0% CH4

01-07-06 3,308 0.01% CH4
01-14-06 3.646 0.0% CH4

01-21-SUIDW 189M HIJON 181

Notes:

Air quantity measurements and methane
concentrations were obtained from the Weekly
Examinations for Methane and Hazardous
Conditions mine record book. The associated
dates denote the week ending dates listed in the
mine record book.

Asterisk indicates no week ending date entered
in the Weekly Examinations for Methane and
Hazardous Conditions mine record book. Date
shown in this appendix for these was based on
other entries.

A dash in the record book information depicted
indicates no entry in the Weekly Examinations for
Methane and Hazardous Conditions mine record
book.

 

 

 

 

Ventilation controls depicted as prior to fire.

Roof falls are not shownI.I.I.IAPPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.



Mine Ventilation
Map 2 of 2

LEGEND

me?

 

Intake Airflow
{g Return Airflow
Belt Airflow

Stopping

I I

Hole in Ventilation Control Indicated
by Slash

II

Stopping with Personnel Door
Box Check Stopping
Overcast

Overcast with Personnel Doors

I71

Rum Creek Portal

Set of Equipment Doors

Regulator

II EXXII II

Seal

1000?

- Installed Conveyor Belt
I I 

 

 

 

 

 

 

 

 

 

2:4727203.  g/I'Iw
00.550 -: 
3' - 1.. . .
MI $20,000 r_n  -. ..   .  .
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19094045 I .
0i TPF: 2-8 .I 
8 -- 4:35. 
73.390 a 
I222.020  NI: 9 .4
. II (193.II .000



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YLD: 85.7

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YLD: 65.0 . . . I '19- 2?
TPF: 3.1   1.  - .I w? Reese?41 
43:: .r  . "maliggfx  YLD: 50.8 
Fun 113. 0 Volt su TEF: 2&5 w? ,r/zx030200 I 
0 v" 
we 0" 94/ YLD: 62:ri?9.4.22- - i 

YLD: 53.0
TPF: 2.1

 





YLD: 95.0

 

 

  
   

    

     
     

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A-

A.  YLD: 69.5

  

 
 
 
 
    
       
  
    

  
 

  

   

 

 

 

   

 

   

A 


TPF: 2.3 
YLD: 48.3
TPFYLD: 43.
TPF: 3.2

 

 



 



YLD: 29.64
TPF: 2.33





YLD: 30.9
TPF: 3.12

 

 

 

 




 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

 

 

 

    

 

   

 

 

 

 

 

 
 
       
    
  
    
  
  
    
 
 
   
           
  
 

 
 
  

  

 

 

 

 

 

   

 

 

 

 

 

 
 

 

  
  

 

 

 

  

      
  
 
  

    
   

   

  
  
  
  
 

       

  
 

 

  

 

   
   

 

      

   

   
  

    
 

 
 
  
   
     
  
  
    
  
   

   

 

 

     
 

   
     

    
    
   
      
 
 

   

 

     

        
 
    

    

 

 

 
     
  
  
 

    
            
   
 
  
        
  
 
  
 
    
  
    
 
  
    

   

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YLD: 33.3 A 0-0 YLD.62.0 I I I
Ag,? 4   II TPF: 2,5 ?gag  - SIR
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YLD: 38.8 .  - .0006 090g .09. 
I . 0004TPF. 2.5 004%0492 .I ?09. 4 - 0-w- ?f033.0% odgoo I. . II Egg. 
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BY 5 IIRTIFIED Ems AND BY THE WATER. A 
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REVIEWS HES LINER TFE SUPERVIXIEN EITHER I .
REGISTERED ENGINEERS. THE PERTAINIM T11 I I I I
WERNERTPE LAWS I .. IV, .I
AND Ir THIS I  
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BEAMS WITH MINE WOR AREA .
- -- 5 BLOCK SEAM. INT- I. I. 
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CHILTON SEAN. INTE TPF: 1.9   . 
UPPER CEDAR GROV -- -. 
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N012 CA5 SEAM, INTERVAL - NI ?300,000
I,  - 
Hens-I_534% ?pm NAME ARACOMA COAL COMPANY MNE NOAlma ?1013?? 55?15 - I,
. 
MPANY ADDRESS P-O- 3011120 Holden. WV REC I - 
NEAREST POST OFFICE StollmOS. WV SEAM ALMA - 1
MINE LOCATION Rt. 14. Elm Creek Road. Near Hutchinson LOGAN TPF: 2.0 If; I I.II 2.,
TOPO OUAD NAME LOGAN LONGETUDE 31'55'53' 3748'50' 
ENGINEERED BY LOGAN COUNTY SERVICES DISTRICT 106AN .  .I 
DATE 08?31?05 DRAWN BY Kenneth Marcum MAP SCALE 400' -  
FAN PROPOSED OVERCAST LATITUDE 5: :2  
INTAKE NR TRACK 9 CORE NOTE I 
RETURN NR II
INTAKE AIR  WATER FOOL . SURFACE STATION .
- UNDERGROUND STATTON 
PRIMARY ESCAPEWAT 48' UNE POWER CENTER II I I II .I 
ALTERNATE ESCAPEWAY '50 ?z BELT ?"55 I . I TPF: .1.2
CRIBBED AREA BAWERY CENTER - x.
TEMPORARY STOPPING El SUB STATION . 1:1 PERMANENT STOPPING 0 400 .900 1300 . k. I
BARRIER LINE El STATION . II: .. I
I: PROPOSED STOPPING . . .2
GAS LINE WELL .I  . I, 0086?01 RCQB-02  ?1 .
l=l  OPOSED SEAL WATER Li PLUGGED Jr RC98-01 172;.5 
0 $012 ELECTRIC UN 0 GAS WELL II - . YLD: 76.5 YLD 41 YLD: 31.1
I I I - I
REGULATOR TELEPHONE LINE PLUGGED 9?6 WELL  "mary scapeway  It.  .2 TPF. 2.1 TPFI 1 1 TPF.1.3 
. . .
I BOX CHECK A CONTROL POINT. UNDERGROUND   In - I  [ff-3?
CHECK CURIAIN A CONTROL POINT. SURFACE BLEEDER EVALUATION EB BENCH MARK. SURFACE HIM W. I
I
OVERCAST BENCH MARK. UNDERGROUND MEC COORDINATE SYSTEM - 2? 4702 (GPS) 
mtake . 65_17 I. w. EuFfulo Hump HPI g, am) 3 phase  Kl VERTICAL CONTROL NGVD 29 us (GPS) .
- 134103277714 29933909429 2 994.404 45 
 FAN MAKE FAN BLADE 59?55 Axlvune 480 Ii 65_14 (Ana) 1,740,209.93933 299.047.450.79 2 309.332 0 I
 I TYPE MOTOR MAKE, Dr MODEL YLD: 79.0 WATER GAUGE 5' ,7 -H 9 .0 (ma) 134036060132 29902277155 2 965.032 .0
. IVAN SIZE 108? MOTOR HP. PHASE 1.500 3 Pho 1,770 YLDI 75-0 8 - 
II R.P.M. 1.180 D. VOLTS O: AMPS 4160.1?3 1 MAX. CAP. C.F.H. 220.000 TPF: 24 0 ?Tax 0 
MAX. CAP. C.F.M. 500.000 WATER GAUGE 12"  'JiTHAT THIS MAP IS CORRECT AND SHOWS TO THE ETHEL FAN DATA -
0 BELIEF ALL OREJNFORMATTON REQUIRED BY THE MINING 
LITE-HSETATE: WERNHE PERIOD ENDING . FAN MAKE JEFFREY Hp, g. pHAsg 500 a Phase 
_2 ,1 SEAL KFON TYPE AREBDYNE PAN SIZE 96 MATER GAUGE 5 :?Il 
REGISTRATION Nd 380 . 8

350.000 . O) -
I. HM YLD: 95EELE NOAPPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Image of Mine Map Identified by Mine Operator
Representatives Maintained as the Map
3OCFR Section 75.1202?1 Required to Be Kept
Up?to?Date with Temporary Notations

 

 

2 Section Belt


North East Mains No. 2 D'SChorge ey

Belt Discharge Pulley

 

 

 

Longwall Belt Discharge Pulley

 

 

No. 7 Belt Tail Pulley borehole

 

 

a



a
a


a
LL 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

wz
c_D_o
*"Cam
HZ




 

 

 

 

 

 

 

 

 

 

 

 

 

 



2 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Longwall Belt Drive

 

 

 

 

 

it
TEL

Pulley Carriage
Lon wall Belt Takeup
Assembly Stogage Unit 4

 

7th

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 




 

 

 

 

 

 

 

91??p?9u or

 

 

EH

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 

 

ll\\

?gfh
i

 

 

[j





 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



S-Hl?tiij 


 

'Dlh68gtPuey\:g T44:  
SS IS
I LongwaH 
E: <3 5? Secbon
IDICEJLLT 
(1E: l/jtl S.
No.l I
Eff Cut?Thru ng er:
Z?x A:
xjiljism?h . Sr?
XZE 
[jCjt?No.l PX:
 t. Fl. S4 
nersec Ion . . RH
.g
FHSS 
ll?l ?14
gfbi -?4wa
 135? I sJ a 
 FE?:Ejltt




cl



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 






irj

Ema:





 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

5e
?3

 

 

 

 


A





 

 

 

 

 

l4

 

 



 

 

 

 

 

Kl

 

 

 

 

 

 

 

 

 

 

 

EDD

Pl\l?iD
_p
ED
tQ
3?
r?l?



ESQ 


DD.
SS 



mama

BSD
SEE

uguu
USSU .


SDS 
SSE 
SSE
SUD

SEES
EDS
\No. 4 48?inch Belt

(N




JSD SD
l?m SD

 

 

 

 

 


Dumut

 

 

 

 

 

 

 

l4

 

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

s:
Ventilation controls depicted as mapped during
.

I he investigation. 
:j Depicted locations of CO Sensor 81 and CO  
Sensor 82 are approximate. Sensor 82 was
damaged rely by the fire. Extensive heat and  

ARACOMA COAL COMPANY, INC. 
Atmospheric Monitoring System 

Carbon Monoxide Sensor Locations 

LEGEND

 

 

 

 

 

 

 

Roof falls are not shown.

 

 

 

 

 

0 Carbon Monoxide Sensor

 

Alarm Unit

uoqo

[l 
HWwaun
tjti 
5l_
f:
[51Cifi
[j 
[j











 

 


Stopping
Hole in Ventilation Control Indicated
by Slash
Stopping with Personnel Door
Box Check Stopping

Set of Equipment Doors

 

 

 

 

 

 

 

 

 

 

 

 

BIL ll JE ll

 

Regulator
Seal

Check Curtain

 

 


 
.-

 

 

 

Installed Conveyor Belt 

I In talled Belt Structure
5 i K,
r7 

 

 

 

 

 

 

 

 

:1:jur?fwmuL, i7

 

 

 

A

 


\1

i
QT

 I 4?inch waterline

8 8?inch waterline JR  

extended to 2 Section

 

 

 

 

 

 

 

 



 

 

4?inch waterline

 

 



North East Mains No. 1
Belt Discharge Pulley/

 

 

 

 

extended to 10 Headgate

 

 

 

 



IIU
#1
II

 

 

 

 

 

 

 

 

 

 

NO. 7 Belt II I ngwoll 
Discharge Pulley/ xtended 
10 Head ate
pp IX 
7 It i 


 

 

 

 

 

 

 

 

 

 

 

 

power center/belt star er

 

 

 

 

NH


Longwall Belt Drive

 

 

 

 
 




6

 



elpbpoeH 5


Longwall Belt Takeup
Storage Unit

 

 

 

 

 

 

 

 

2?inch waterline

 

m??mt

 

 

 

 

 

gr

 

 

 

 

 

 

HM

 

 

 

 

Ah

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

IWPIWITII It 

 

 

 

 

 

 

 

 

 

 

 

 

Lid
-ml


 

 

shut?off valve,
closed

 

 



 

 

 

 

 

 

 


J.
5M

freshwater hose
extended to
longwall face

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

?J\l

LongwaH
Sec?LEWJITF

 

 

 

 

 

 

 

 

 

II 
WWI IDI

 

 

 

 

 

 

 

 

 

 

 

 

 

 

SUIDW 139M WON 

 



 

 

 

 

 

 



ILJLJU
II WL?l?l I

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

lull 

 

No. 1
If Cut?4ihnl



 

 

 



\wwnp
I
ttlf??rl?

 

 

 

 

 

 

 

U1

 

 

 


I

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

6?inch waterline

extended to
longwall section

 

 




 




 

 

\mw
4?Way
Intersection

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

I l\ Til

LI

 

 

 

 

 

 



 

 

 

 

 

I

HWI
Hit MuLlw//

tee

 

 

 

 

I

 

 

 

 

 

 

 

 

 

 

 



 



 

 

 

 

 

 

firLJLII Elle
[1 3_
lel 

lJEl
I ea
a DD

a 
Em mmw??rln?t
MI

II

E?ggi 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

shut?off 3 
valve, closed 

 

 

 

 

 

 

 






 

 

 



I

Fl
4


 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

6?inch waterline 
extended toward 4 Right

 

 

r?GEE
QUE


DUDE
EDS
BED
DEE

ugug
USED .

EGG 
EDD 
EDD 
EEG
CUE
USU
LUCIE
EEG

DE

DE
QUE
DEG

 

 

 

 

 

3 Mauws
221:;

E:


LA 
WW 5 I \No. 4 48?inch Belt
power


a 
3% 3E .

house ter 

 

 

DULLJ

 

 

 

 

 



 

 



l__l MLILJ

a 
DE







,3 Sec?on 

 

 

 

 

 

 

Ll
I

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

Shaft 



and Fan Cg?


longwall circuit entered 0O

 

 

 

 

 

 

 

 

 

APPENDIX 0

MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

 

mine from Box Cut
waterline from surface 
freshwater supply tank

Electrical and Freshwater Supply Systems

. . Schematic

device Note:
Ventilation controls depicted as mapped during
0 the investigation. LEGEND
3 Stopping


<3
C?jl?:j 

 

I

I

Hole in Ventilation Control Indicated by
Slash

 

Stopping with Personnel Door
Box Check Stopping
ast

 

ast with nel Doors

Set of Equipment Doors

 

 

Regulator

 

Seal

Check Curtain

 



 




Installed Conveyor Belt

 

Installed Belt Structure

Waterline Gravity Fed from Surface
Freshwater Supply Tank

Waterline from No. 1 Freshwater Pump

 

Waterline from No. 2 Freshwater Pump

 

Miner (12,470 VAC Electrical) Circuit

7 
Longwall (12,470 VAC Electrical) Circuit
- - 

 

 

 

 

IPPQI

 

 

 

 

 

 

 

 



miner circuit 

No. 6 Belt


valved fire
outlet

     
  

 

 

 

 

No. 7 Belt

 

No. 7 Belt
4?inch waterline
shut off valve

4?inch waterline

 

 

 

Deta?

 

 

8? inch waterline from

No. I Freshwater Pump 

 
 
 
 

 

 

4?inch 
waterline

cooHng Hne

   
  

cooling line]

 

 

  
    

No. 2
NO 1 Freshwater
Freshwater Pump
Pump 2?inch closed
pressure shot?off valve
relief Iine
4?inch
waterline ended

x480?volt power to
freshwater pumps
from miner circuit
8?inch
waterline 

 

 

I



4?inch
waterline
4?inch
waterline 

 

 

 

 

 

power center

8?inch waterline from
surface freshwater

supply tank 



miner circuit 

4?inch waterline

extended to Rum
Creek Portal 

 

 

 

 

 

3

 

longwall circuit

4? inch waterline

longwall circuit extended

to 10 Headgate\

 

 

   
  

  
       
 
 

 

      
        
   
     
 
  
 

  

  

 

    

  
   
 

 

 

 

ShUt?Off extended from No. 6
for Belt entry
LongwaH
Belt 2?inch
waterline
dual
switch
No. 7 Belt house
Longwall Belt
discharge pulley
2500 longwall belt I
power center/belt starter
LongwaII Belt
drive
2?inch waterline winch
extended toward controller
longwall section
LongwaIl Belt
. 
longwall circuit
extended to
longwall section
/?pinch roller



 

 

 



pulley
carriage
assembly

(PCA) 

 ongwa   belt takeup
storage unit

 

 

rear
frame
assembly

(RFA) 

 

 



 

 

 

Deta?

 

I

 

 

 



installed
72?inch belt
structure

 

Note:
Ventilation controls depicted as mapped during
the investigation.

LEGEND
Stopping
Hole in Ventilation
Control Indicated by

Slash

Stopping with Personnel
Door

Installed Conveyor Belt
Installed Belt Structure

Miner (12,470 VAC
Electrical) Circuit

LongwalI (12,470 VAC
Electrical) Circuit

Waterline Gravity Fed
from Surface Freshwater

20: 407 Supply Tank

 

APPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

Electrical and Freshwater Supply Systems Schematic Detail Views

Waterline from No. 1
Freshwater Pump

Waterline from No. 2
Freshwater Pump

Open Waterline Shut?off
Valve

Closed Waterline Shut?off
Valve

Water Pressure Regulator
FIow Check Valve

Flow Switch

Waterline Adapter (used
to connect waterlines of
different diameters)

Survey Station (SS)
Location and Number

 

 

 

door
open?\\

 

 

 

 

 

 

 

 

 

 

East Mair;

 

 

 

 

 

I

 

 

 

mandoor 2 Section Belt

 

 

 

 


 


 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

3'9? North East Mains No. 2 Discharge Pulley
Belt Discharge Pulley 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

i ll 'lroof fall, occurred
- after accident

?ll-ll

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

8 Headgate

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   

 

   

 

 

 

 

 

 

 

 

 

  
  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 
   
  

  
  

  

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

  

 

 

 

 

Longwall Belt Drive

 

rear frame

assembly

Longwall Belt Takeup
Storage Unit

mandoor 
Sign man oor
Sign

mandoor mandoor mandoor
mandoor mandoor as . Sign mandoor mandoor 
sign Sign Sign . Sign Sign North East Mains No. i mandoor, 3 3 a:
Belt Discharge Pulley 8'9? boreholemandoor 7 mandoor
Sign ?rmandoor  dual switch Sign 3
house
- 3 Sign A

doors
2500 
oor Iongwall 3 I open
belt power
. center/belt 
a *0 4? starter 3 
No. 7 Belt *0 . e. ?o *0 
Discharge Pulley 
controller 

I

No. 7 Belt Drive (D


'3 23$?de
assembly 


2 Sectkwi

 

 

 

 


I
(I)
.
doors open



(I)

 

 

 

 

 

doors

Lopen?\

 

 

 

 

 

 

 

door
open

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   
  

ll
 
Jl

mandoor

7 Headgate 

8?
8?

mandoor

K. Sign 5 



?0

5 door open

0 
I

3 a.  



3 

Cor open
3? .

 

 

. APPENDIX 

 

 

 

. MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.
mandoor
mandoor Escapeways for 2 Section and
sign mandoor mandoor 9 Headgate Longwall Section
sign I
(D 3 I .
 U) LEGEND
Notes: . .
Ventilation controls depicted as mapped during V. Prlmory Escapeway Re?eCtlve Tag
1 the investigation. Alterations to permanent  Roof Fall
I ventilation controls made during rescue and "335*"
i 3 firefighting operations shown in blue. UM Cribs
[door 3 mandoor Survey Station (SS) Location and
open Sign . Number
i
Roadway
Stopping

3 
U)

 I
I
mandoor
sign 0. I,
7? .

ES Headgate mmam

mandoor
sign

Hole in Ventilation Control Indicated
by Slash

Stopping with Personnel Door

Box Check Stopping

 

Overcast

Overcast with Personnel Doors

 

ll

 

 

Set of Equipment Doors

Regulator

 

Seal

 

 

II EXXII ll

mandoor 0 
mandoor 
sign
- - LongwaH

 

Check Curtain

Installed Conveyor Belt

sign  
Secton

 

on
.
.

Installed Belt Structure

 

 

ITIIJ 

 

 

 

 

 

 

 

 

 

 

 

 

 

0 Primary Escapeway Routes Shown on
Surface Escapeway Map
7 7 7
Alternate Escapeway Routes Shown on
Surface Escapeway Map

 

7 

 

man door 
M-m-n
If a 
sign


km\ 3 






 

 

 

 



$2





t3 Sec?on

 

 

Shaft
and Fan

 

 

 

 

 

 

 

DE DE 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

North East Mains

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

2 Sec?on Beh

NO- Discharge Pulley

2

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Yew E33 Ben [Nscharge PuHey
-- .. SD El
Longwall Belt Tail Pulley ES   
BEEF 
DDQUUDEEF DEEMED E1 W7 4
A
LMJ. re p: C) tT1??
i 7Be t Longwall Belt Drive bmm'e  LO 2  
Dri Lon waH Takeu 
Ll Stogage Unit (D 
F?LongwaH
:d 23::
. :3 Sechon eze2e_ t%:No.1 l: 
3  Cut?Thru 
3?51:   :l 
-ff? 3 
~4?Wd ?Lr? 1x 
gEgi Intersection E]r#
;t 5% 9 
lD_11Belt Discharge Pulley
.
.
48?g?r 
3 TO  
l: 

Qilm 
e9 

ET/m4%u 
a 

E5 3 Headggte Notes;
SE depicted as mapped during ASREENEXPR
ARACOMA ALMA MWE MSHAID No 46?08801
R??f fal's are not Show? ARACOMA COAL COMPANY, INC.
. Pnnuny Escapeways ?x 2 Sec?on and
3?way Intersection   9 Longwall Section to Box Cut 
LEGEND 
to Escapeway Re?ec?ve Tag 
[1 
Lg? ElyleanghVentilation Control Indicated
Stopping
D60 wt.
,eD dx?mxm
Emmi \ng
es. Check Curtdut 
O, 300, 600, Installed Conveyor Belt
F1
 Installed Belt Structure 
3E
?n

 

Egan-m

. 


Scale:
AH

Pr

E?sTc?Jpewoy Mop



 




 

..




[if?mory Escopewoy

Image of 2 Section Escopeway Mop

ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

  







EscopewoyV

APPENDIX 8
MINE MAP

 

D4:


UDUDU

 


26/05

way
'9

scope.



f1 9?

mpewoy Mop

ma.
Primary Escopewcy

. it?? - 
.
 
Scale.
- grin?{hf?

Secondory 

 

 



MWE MAP
ARACOMA ALMA MWE MSHAID No 46?08801

ARACOMA COAL 

Hnage of 9 Headgote Longon Sec?on
Escopewoy Map

 

 

1700

1600

1500

1400

1300

1200

1100

1000



on (feet above mean sea level 

 

0

ESCHD

Elevot



(SCH)

EHDC)

Freshwater Supply Tank (located on surface)
static head available at the overflow pipe
elevation of 836 feet MSL

Freshwater Supply Tank (located on surface)
static head availabe at the outlet pipe

elevation of 817 feet MSL

No. 2 Freshwater Pump

Hydrou

 

0

 



 

 

Elevottwt Drot

 

0

 

 



 

elevation approximately 595 feet MSL

pump rating:

843 feet of head at 0 (365 psi)
422 feet of head at 450 (183 psi) 

near 3?Way Intersection

(SS 731)
No. 2 entry portal in Box Cut

1000

near No. 2 Freshwater Pump
(SS 1649)

5000

Water



 

 

Approximate maximum static head available

at discharge of No. 2 Freshwater Pump

when the pump is operating at no flow and

the water level in the Freshwater Supply
Tank is at the outlet pipe
(843 feet 817 feet 1660 feet)

pressure rating limitation
of the underground waterline:

315 psi (726 feet of head
above the No. 2 Freshwater

Pump elevation)

end of waterline at 8 Headgate
in North West Mains

(ss 2885)

North East Mains
No. 1 Belt Discharge Pulley

(ss 

No. 7 Belt

Discharge Pulley

(SS 




SS 2826 in North

West Mains
2255 in North
West Mains
SS 2211 in North
West Mains
H1000

ne Length (feet)

near 2 Section Belt
Discharge Pulley

in North East Mains
(SS 4208)

near 10 Headgate
in North East Mains

near 9 Tailgate in
North East Mains

(ss 3223)

3 crosscuts inby 9 Headgate
Belt Discharge Pulley toward
9 Tailgate in North East Mains

(ss 3332)

   

9 Headgate Belt
Discharge Pulley

(SS 3249)

near end of 2?inch
waterline in 9 Headgate
(SS 3320)

15,000

Notes:

Color designations for specific of waterline
are relative to waterline diameter and are not
intended to be consistent with waterline color
designations used in Appendix 0 and Appendix P.

All elevations are approximate based on mine
maps and other information provided by the mine
operator.

All waterline are approximate and scaled
from mine maps.

All survey stations (SS) are shown at approximate
locations along the linear length of the waterlines.

 

APPENDIX 
GRAPH

ARACOMA ALMA MINE MSHA ID No. 46-08801
ARACOMA COAL COMPANY, INC.

Hydraulic Elevation Profile

LEGEND

12?Inch Waterline on Gravity Fed Side
of Pump (on surface)

8?lnch Waterline on Gravity Fed Side
of Pump

4?lnch Waterline on Gravity Fed Side
on Pump

4?lnch Waterline on Discharge Side of
Pump in North West Mains

8?lnch Waterline on Discharge Side of
Pump Along North East Mains Belts

4?lnch Waterline on Discharge Side of
Pump Along No. 7 Belt

2?lnch Waterline on Discharge Side of
Pump Along 9 Headgate Belt

 

 

 

 
  
    

rear frame
assembly (PEA)

mantrip

 

  
    
  
  

 

 

 

   

 

 

 

 

   

    
  
 

Ir-1 I - I I 7 I-Ill Illr-valved fire outlet (location
from which VFO was
recovered during the

investigation)

   

2?inch waterline pulley carriage
assembly (PCA)

 
 

Detail Plan View

  

 

longwaH 
dBcharge puHey

roller

  
 

shut?off valve for

2?inch waterline

 
     

0

 

 

 

ve aha Takeup Storage Un?t Area

Plan V?ew of Longwall Belt Dr

inline intermediate sprinkler system piece of sprinl<ler Longwall
leading section hose system hose on floor Belt Drive

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 



 

A 0 i 
View}


 

 

 

 



 

 

 

 

 

 

 

 

 

 



shut?off valve for Longwall Belt 2?inch

LongwaH . . .
2?inch waterline Drive motors waterline

Discharge Pulley
Notes:
Floor elevations were determined from elevations
7 7 7 depicted on mine maps provided by the mine
4 8 operator. Roof elevations were estimated from

photographs depicting objects of know size and
visual observations.

Individual components of the belt conveyor
system, many of which were located by a total
station survey jointly conducted by MSHA and the
mine operator, are intended to be depicted for
visual descriptive purposes only. All structural

and mechanical components are not shown.

Portions of the suspended belt structure shown in
the Section side view was damaged by the
fire and fell from the roof. The belt structure

Deta?

 

 

 

 

l? ll) 6 l? term Gdete  OW Gil Cl and other conveyor belt system components
I    .  shown are depicted as similar to how they'likely
00 mg 86C stem Spl?ll?i el? 60 . eXIsted, based on information collected during the
investigation, before the fire and is for
demonstrative purposes only.

system hose

This mine map and drawing is not intended to be

piece Of Spl?l?klel? syStem hose Oi) a detailed mechanical drawing. Specific objects
. . . . may not be to scale.
In this area (object not depicted)

Waterline and other objects in the area of the
fire were damaged. Approximate location of
specific objects depicted as mapped and
photographed for demonstrative purposes.

 

     
 
 
    

Longwall Belt Drive motors

 

 

APPENDIX 
MINE MAP
ARACOMA ALMA MINE MSHA ID No. 46?08801
ARACOMA COAL COMPANY, INC.

 

 

 

9 Headgate Longwall Belt Drive
Area Fire Protection

 

 

 

 

 

 

LEGEND

sprinkler system
shut?off valve

Set of Equipment Doors

Installed Conveyor Belt

4?inch waterline 
Survey Station (SS) Location and

Number

shut?off valve for Sprinwer system
2?i?Ch WOlerll?e hose end, burnt off

Waterline from No. 2 Freshwater Pump

Closed Waterline Shut?off Valve
O, 4, 8, 2?inch waterline . Water Sprinkler Head

Waterline Adapter (used to connect
waterlines of different diameters)

 

 

 

Sect?on 

 

Appendix W – Conveyor Belt Flame Resistance Testing
Conveyor belt flame resistance testing
All conveyor belt materials used in underground coal mines are required to have flameresistant qualities meeting those established by the Secretary (30 CFR § 75.1108). The
flame resistance test determining this requirement is described in 30 CFR § 18.65, which
is based upon the former US Bureau of Mines Schedule 2G test protocol.
The 2G test is a small scale piloted-ignition test conducted in a special enclosure. It
utilizes ½-inch by 6-inch test strips of the belt material. Tested one at a time, each strip
is directly exposed to a three-inch-high pilot flame from a natural gas fueled PittsburghUniversal Bunsen burner in quiescent air conditions. At the end of one minute, the
flame is withdrawn and the air velocity is immediately increased to 300 feet per minute
by a small fan. After the burner flame is removed, the duration of any continued
flaming is timed and noted. Starting at the termination of any continued flaming, the
sample is observed for at least an additional three minutes for any after glow. The
duration of any such after glow is also timed and noted. If during this three minute
period additional flaming occurs, the duration of the additional flaming is added to the
previous duration of flaming recorded. If the average total flaming time of the four
samples exceeds one minute, or if the average total after glow time exceeds three
minutes, then the sample fails to meet the requirements for testing. Additional details
of the test procedure can be found in the referenced regulation.
Two belt samples were obtained during the initial mine fire investigation. One belt
sample had been taken from the 72-inch wide No. 7 belt, and the second sample from
the 60-inch wide longwall belt. The longwall belt sample was recovered inby the belt
storage unit. Both samples were recovered adjacent to the fire area but far enough
away from the fire that the samples had no visible signs of fire or heat damage. Both
samples were stored at the MSHA Approval and Certification Center (A&CC) in a
secure evidence cage. Neither belt sample carried a manufacturer’s marking; however,
the name of the belt manufacturer was found embossed on belt material farther away
from where the samples were taken. These markings were significantly worn and
barely discernable.
On June 13, 2006, the two belt samples were given visual examinations and
flammability tests in the first floor Quality Assurance laboratory in Building One of the
A&CC. The visual examination was conducted by MSHA personnel including
investigation team member Derrick Tjernlund, William Francart, and Kenneth Murray.
Harry Verakis, a physical scientist with MSHA’s Technical Support group, along with
inspector John Kinder from the West Virginia Office of Miners Health and Safety
Training, also witnessed and participated in the visual examination and testing.
Michael Hockenberry, a fire protection engineer with the Mechanical and Engineering
Safety Division of the A&CC, provided assistance in moving the samples and
conducting photography work. Dave Creamer, chemist with the Quality and
1

 Appendix W – Conveyor Belt Flame Resistance Testing
Assurance Division of the A&CC, cut the test strips and conducted the 2G flameresistance tests. The visual examinations and 2G tests were also video taped.
72-inch wide No. 7 belt sample
The visual examination of the 72-inch belt sample revealed that it was of a two-ply
construction with a fabric skeleton and molded edges. The approximate dimensions of
the sample were 72 inches wide by 33 inches long on one side, and 39 inches long on the
opposite side. Thickness measurements at six different locations yielded values ranging
from 0.725 to 0.745 inches. The belt did not indicate excessive surface wear, nor did it
have any signs of charring or heat. No unusual odors, colors, or coatings were found.
The surface did show some signs of rub marks, possibly due to the recovery effort when
the sample was pulled along the mine floor several breaks to a mantrip used for
transport from the mine. Additionally, a cut was found parallel to each edge of the belt,
approximately 1-1/8 to 1-1/2 inches in from the edges. These cuts ran the length of the
belt sample but did not go through the belt. A shallower cut was also seen
approximately in the middle of the sample running parallel to the side edges. This cut
extended into the first layer of fabric with some cords showing.
After the visual examination, four ½-inch by 6-inch test strips for 2G testing were cut
from the sample, two parallel to the edges and two perpendicular to the edges, as
required by the test procedure.
The results of the 2G test indicated the recovered belt sample passed the criteria
established for this test. The longest continued flaming after burner removal was seven
(7) seconds with no strips experiencing after glow.
60-inch wide longwall belt sample
The visual examination of the 60-inch belt sample revealed that it was a four-ply
construction with a fabric skeleton. The approximate dimensions of the sample were 60
inches wide by 24 inches long on one side, and 28 inches long on the opposite side.
Thickness measurements at six different locations yielded values ranging from 0.837 to
0.855 inches. The belt did not indicate any unusual surface wear, nor did it have any
signs of charring or heat. No unusual odors, colors, or coatings were found.
The surface showed signs of rub marks and several small gouges, possibly due to the
recovery effort when the sample was pulled along the mine floor approximately 750
feet to a mantrip used for transport from the mine. A deep cut extending the length of
the sample was found parallel to one edge of the belt approximately 7/8 inches in from
the edge. This cut extended into multiple plies of the belt, in some areas almost
penetrating the total thickness. Strings of the fabric skeleton were visible and

2

 Appendix W – Conveyor Belt Flame Resistance Testing
protruding from the cut. Based upon the frayed and ragged state of these skeleton
cords, the condition appears to have existed from some time.
After the visual examination, four ½-inch by 6-inch test strips for 2G testing were cut
from the sample, two parallel to the edges and two perpendicular to the edges, as
required by the test procedure.
The results of the 2G test indicated the recovered belt sample passed the criteria
established for this test. The longest continued flaming after burner removal was two
(2) seconds with no strips experiencing after glow.
Information provided by Aracoma Coal Company indicated twelve (12), 1000 -foot long
rolls of conveyor belt were purchased for the longwall and shipped to the mine in April
of 2005. The belt manufacturer’s information described the belt as a 60-inch wide, 4 ply,
1800 PIW, MSHA approved belt with molded edges.
Neither belt sample described above carried a manufacturer’s marking.

3

 .DUWW IV-I-I IV 1 LI
EILJLI IEI I I 3 WI 7m I Lro
Lil-Fr Ir?rit II 
E) E1 If II I ALI WHITFIL IITI Ij I
DE
DE
2 Section

 

 

North East Mains

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Ll


 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

I

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

North East Mains No. 1
Belt Discharge Pulley

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

2 Section
mantrip

 

 

No. 7 Belt 
No. 7 Belt tail pulley

Longwall Belt drive

 

I:
a)


LQ

(at


fire origin and
oca ion 0 RFA
Longwall Belt takeup storage unit

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

t:

9106p?9H 6

 

APPENDIX 
MINE MAP

ARACOMA ALMA MINE MSHA ID No. 46?08801

Notes:
Ventilation controls depicted as mapped during
ARACOMA COAL COMPANY, INC.

investigation.
Extent of Fire Spread

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 





3

I

. 6 It  
Dscha Pull  

(D Roof falls are not shownApproximate Extent of Observed Soot
0 Deposits
. 0 Approximate Area of Extensive Heat
1 and/or Flame Damage
UH . . I Stopping
. I . . Stopping with Hole
Stopping with Personnel Door
.  Box Check Stopping
ast
Overcast with Personnel Doors
Set of Equipment Doors
Regulator

 

Seal

 

 

Check Curtain

a




moo

200? 400? 

 

 

 

 

 

Appendix Y – Evaluation of Spontaneous Ignition Potential of Aracoma Alma Mine #1 Coal
Sample
It is well known that some materials, under the right conditions, can undergo a selfheating reaction sufficient to allow the material to reach its auto-ignition temperature.
Oxidation is usually the principle reaction driving this self-heating process. Coal is
among the materials that have demonstrated the ability to undergo self-heated ignition.
Traditionally, the self-heating process has been referred to as “spontaneous
combustion.” However, the use of the word “spontaneous” in this phrase actually
refers to the process leading up to ignition, rather than to the on-going burning after
ignition has occurred. For this reason, the term “spontaneous ignition” is more
appropriate and will be used in this discussion. This usage is also consistent with the
growing trend within the fire science and research community to use “spontaneous
ignition” when referring to the self-heating ignition process.
Not all coals tend to undergo spontaneous ignition, either in the laboratory or under
real world conditions. Substantial research has demonstrated that a number of factors
play a role in this process. These factors include certain chemical and physical
properties of the coal, the location and physical condition of the coal, and the
surrounding environment.
In terms of location and conditions, it has been observed that larger coal piles or
accumulations have a greater tendency to self-heat than small accumulations. Small coal
piles or accumulations are much less likely to undergo spontaneous ignition because,
among other things, they are more effective at shedding heat created by any selfheating process. This is due to the smaller mass and greater surface area of the pile. The
compactness of the pile is also a factor, with loosely piled coal more prone to
spontaneous ignition than tightly compacted piles.
Ventilation can have a significant effect on the occurrence of spontaneous ignition.
Continuous ventilation can provide an on-going source of oxygen; however, it can also
act as a convective heat transfer media to provide cooling of coal accumulations that
may be self-heating. Greater ventilation rates tend to discourage self-heating, while
very low ventilation rates can encourage the process. The continuous replenishment of
oxygen, in conjunction with a lack of cooling, can permit an excessive temperature rise
to occur in the coal. Since the rate of oxidation has an Arrhenius temperature
dependence (i.e., increasing exponentially with increasing temperature), the increasing
temperature in the coal can become a self-sustaining process, with the reaction
sometimes “running away” until ignition occurs (autoignition).
As evidence of the importance of these factors, Kutchta, et.al [1] reported that from 1952
through 1969, 877 fires occurred in underground coal mines. Sixty five (65) of these
were due to “spontaneous combustion,” with all of those fires restricted to gob areas. In
another study, De Rosa[4] found that from 1990 through 1999, 84 mine fires occurred
with 15 fires attributed to “spontaneous combustion.” All of those occurred either in
1

 Appendix Y – Evaluation of Spontaneous Ignition Potential of Aracoma Alma Mine #1 Coal
Sample
gob, sealed off, or abandoned areas. Gob areas are worked-out areas from which coal
pillars have been partially or wholly removed. They usually contain loose coal left from
the mining process and have sustained but limited ventilation.
The chemical and physical properties of the coal also play a significant role in
spontaneous ignition. Of particular importance concerning the chemical and physical
properties are the ability of the coal to adsorb water vapor, the amount of volatile
matter within the coal, and the amount of oxygen contained within the chemical
structure of the coal.
Kutchta found that self-heating of coal tends to be a two–step process. The first heating
step occurs when dry coal adsorbs water vapor. In order to change from a liquid to a
vapor, water must absorb a significant amount of heat. For example, this happens
when sunshine evaporates water from a highway after a rainfall. When the opposite
process occurs, that is, when water vapor re-condenses back into a liquid, the heat it
gained during evaporation is given up to the surrounding environment. This process is
sometimes referred to as the “heat of wetting.” It is interesting to note that this same
process is one of the primary heating mechanism driving thermal updrafts in
thunderclouds. When coal adsorbs water vapor, the heat of wetting raises the
temperature of the coal. The more moisture the coal can adsorb, the more heat that can
be generated by the heat of wetting.
The rate of oxidation within coal that occurs at ambient temperatures is usually
insufficient to initiate a self-sustained heating process. However, with sufficient heat of
wetting, a critical temperature may be reached whereby the oxidation reaction can
become dominant and take over the heating process. Two additional factors affect the
likelihood of this happening. These are the amount of volatiles in the coal and the
amount of inherent oxygen. Volatile matter in the coal is generally easier to oxidize
than nonvolatile content, and additional oxygen in the coal further supports the
oxidation process. Therefore, coals with higher volatile matter and oxygen content have
lower critical oxidation temperatures. Smith and Lazzara [2] provided information on
the role the amount of inherent oxygen plays in the spontaneous ignition of coal.
Mine safety researchers have developed the concept of a minimum self-heating
temperature, which will be referred to as the critical self-heating temperature, or CSHT,
in this discussion. [1][2] The CSHT is a laboratory determined quantity that cannot be
used to directly predict spontaneous ignition under specific real world conditions.
However, this value can play an important role as an index for classifying the relative
propensity of a coal to spontaneously ignite by correlating this value to coal fire history
data.
In the referenced research, the CSHT was determined using pulverized dry coal
samples. Samples were placed in an insulated (adiabatic) vessel and then exposed to a
continuous steady flow of moist air of predetermined temperature. This exposure
2

 Appendix Y – Evaluation of Spontaneous Ignition Potential of Aracoma Alma Mine #1 Coal
Sample
process continued for 24 hours, or longer, if temperature measurements in the sample
indicated self-heating was occurring. If an initial limited temperature rise occurred, but
then leveled off and remained constant throughout the 24 hour period, spontaneous
ignition was deemed not to have occurred. Where self heating was evident, the test run
was continued beyond the 24-hour cutoff time. If self heating led to an exponentially
increasing temperature rise, then spontaneous ignition was either occurring or
immanent.
For coal samples from a given coal seam, this experiment was repeated at various
temperatures with fresh samples for each run. The lowest heating temperature
demonstrating thermal runaway was termed the “minimum” self-heating temperature.
The time from the start of a heating experiment until ignition occurred is often referred
to as the induction time. For cases in the referenced research where spontaneous
ignition occurred, the induction times in those experiments varied from about 4 hours
for airflow temperatures well above the CSHT, to induction times often 24 hours or
longer for airflow temperatures at the CSHT.
Two different critical self heating temperatures have been identified, one based upon
the amount of oxygen in the coal, the second based upon a combination of the water
adsorption capability of the coal and the amount of coal carbon and volatiles. These last
three values are incorporated into a quantity known as the “moist fuel ratio” or MFR.
Determination of the oxygen-based CSHT requires knowledge of the amount of oxygen
in the coal on a dry, ash-free basis. This can be determined by an ultimate analysis
(ASTM D-3176). Determination of the MFR-based CSHT requires the percent moisture
content, percent volatiles, and percent fixed carbon, which can be determined by a
proximate analysis (ASTM D-5142). All percents are on a mass basis.
Both a proximate analysis and an ultimate analysis were conducted by an independent
laboratory on a coal sample from Aracoma Alma No. 1. The results are listed below.
% moisture
2.99

% volatiles
36.39

% carbon
54.30

% oxygen (DAF)
6.89

As stated, the percent oxygen is elemental oxygen on a dry, ash-free basis from the
ultimate analysis. All other values are from the proximate analyses.
For the CSHT based upon oxygen content, Smith and Lazzara proposed the following
empirical equation.

3

 Appendix Y – Evaluation of Spontaneous Ignition Potential of Aracoma Alma Mine #1 Coal
Sample
CSHTOX = 139.74 − 6.57 × ODAF
Where:
CSHTOX = critical self heating temperature in °C based upon elemental oxygen level.
ODAF = mass percent elemental oxygen on a dry, ash-free basis.
Based upon the ultimate analysis, the CSHTOX was calculated to be 94.5°C.
The CSHT due to the moist fuel ratio is based upon an empirical equation proposed by
Litton and Page [3], who in turn, based their equation on data and results from Smith
and Lazzara. This equation was given as:

(

CSHTVOL = 117 1 − e −2.6 x

)

Where:
CSHTVOL = critical self heating temperature in °C based upon carbon, volatiles, and
moisture adsorption.
X = “moist fuel ratio” and is defined as:

⎛ % fixed carbon ⎞
⎟
⎜
%volatile matter ⎠
.
X =⎝
%moisture
Based upon the results from the proximate analysis, a value of 85°C was obtained for
CSHTMFR.

Smith and Lazzara proposed that for CSHT values less than 70°C, the coal should be
classified as having a high potential for spontaneous ignition. Coals having a CSHT at
or above 70°C, but less than 100°C, should be considered as having a moderate
potential for spontaneous ignition. For coals having a CSHT equal to or greater than
100°C, the potential for spontaneous ignition should be considered low.
The average of the two values obtained in the analysis is 90°C. It is very important to
note that the temperature ranges proposed by Smith and Lazzara, although not
arbitrary, are set somewhat for convenience in that they are established at whole units
of ten degrees. The results yield values toward the upper boundary between the
moderate and low ranges of spontaneous ignition potential.

4

 Appendix Y – Evaluation of Spontaneous Ignition Potential of Aracoma Alma Mine #1 Coal
Sample

Conclusion
The results of this analysis strongly suggest that spontaneous ignition of coal
accumulations in the No. 9 Headgate longwall takeup storage unit area was not the
source of ignition for the fire on January 19, 2006.

Bibliography
[1] Kutchta, J. M., V. R. Rowe, and D. S. Burgess. Spontaneous Combustion Susceptibility of
U.S. Coals, U.S. Bureau of Mines Report of Investigation No. 8474, 1980
[2] Smith, Alex C., and Charles P. Lazzara. Spontaneous Combustion Studies of U.S. Coals, U.S.
Bureau of Mines Report of Investigation No. 9079, 1987
[3] Litton, C. D. and S.J. Page, Letter to publisher of Fuel Magazine, 1994, volume 73, number
8, pg 1369.
[4] De Rosa, Maria L. Analysis of Mine Fires for All U.S. Underground and Surface Coal
Mining Categories: 1990–1999, National Institute of Occupational Safety and Health,
Information Circular 9470, 2004

5

 Appendix Z – AMS Event Logs and Schematics for Other Events

APPENDIX Z
Locations and Responses of CO Sensors for Events on October 8, 2005;
December 23, 2005; and December 29, 2005.

1

 Appendix Z – AMS Event Logs and Schematics for Other Events
October 8, 2005
Time
12:17:34
12:17:48
12:18:59
12:19:26
12:19:54
12:19:59
12:30:55
12:32:30
12:33:06
12:34:48
12:42:57
12:47:15
12:55:52
12:59:29
13:00:58
13:06:32
13:07:38
13:08:02
13:20:36
13:20:36

Sensor
Signal
90
Warning
90
Alarm
41
Warning
41
Alarm
55
Warning
55
Alarm
96
Warning
96
Alarm
91
Warning
91
Alarm
40
Warning
40
Alarm
43
Warning
39
Warning
89
Warning
92
Warning
89
Cleared
89
Warning
38
Warning
Warnings and Alarms begin to Clear

December 23, 2005
Time
21:55:29
22:13:27
22:13:28
22:16:28
22:17:42
22:28:49
22:31:56

Sensor
82
82
102 Alarm
81
81
82
82

Signal
Warning
Alarm
Alarm Latch
Warning
Alarm
Warning
Warning Cleared

December 29, 2005
Time
18:19:52
18:20:24
18:24:07
18:24:34
18:33:33
18:34:49
18:49:13
18:50:09
18:53:07
18:56:05
19:03:31
19:44:18
20:00:56
20:01:30
20:03:30
20:05:43
20:06:56

Sensor
94
94
50
50
51
51
53
53
80
80
81
51*
94
50
80
81
53

Signal
Warning
Alarm
Warning
Alarm
Warning
Alarm
Warning
Alarm
Warning
Alarm
Warning
Warning Cleared
Warning Cleared
Warning Cleared
Warning Cleared
Warning Cleared
Warning Cleared

* Indicated by Maximum Value Message for this sensor
Sensor 52 did not respond – In-Line with 51 and 53 sensors – Communications Dead
Sensors in 48-inch belt did not indicate warnings or alarms in Northeast Mains

2

 Appendix Z – AMS Event Logs and Schematics for Other Events

North West Mains
92

93

4 Right

91

October 8, 2005
Aracoma Alma Mine # 1

96

90

55
41

3
Section
40

89

Box Cut

43

LEGEND
39

Belt

Rum Creek

CO Sensor Warning/Alarm
96
43
93

CO Sensor Warning

38

CO Sensor No Signal
Air Direction

NOT TO SCALE

3

 Appendix Z – AMS Event Logs and Schematics for Other Events

No. 2 48-inch Belt Head

December 23, 2005
Aracoma Alma Mine # 1

No. 3 48-inch Belt Head

76
77
75

79

72

74

No. 1 48-inch Belt Head
73

as
E
rth
o
N

s
ain
tM

2 Section

71

52

No. 7 Belt Head

Longwall Belt Head

81

70

53

82
80

Unidentified Address

83
88

51

ll
wa
g
n
Lo

102

on
cti
e
S

50
94

No

No. 6 Belt Head

rth
es
W

92

t
a in
M
s
93

LEGEND
Belt
81

CO Sensor Warning/Alarm

92

CO Sensor No Signal

91

Longwall Gob
Air Direction
Not To Scale

4

 Appendix Z – AMS Event Logs and Schematics for Other Events

No. 2 48-inch Belt Head

December 29, 2005
Aracoma Alma Mine # 1

76
77
75

79

72

74

No. 1 48-inch Belt Head
73

No. 3 48-inch Belt Head

as
E
rth
o
N

s
ain
tM

2 Section

71

52

No. 7 Belt Head

Longwall Belt Head

81

70

53

82
80

Unidentified Address

83
88

51

ll
wa
g
n
Lo

102

on
cti
e
S

50
94

No

No. 6 Belt Head

rth
es
W

92

tM
a in
s

LEGEND
93

Belt
94

CO Sensor Warning/Alarm

52

CO Sensor No Signal

91

Longwall Gob
Air Direction
Not To Scale

5