PIPELINE INVESTIGATION REPORT
P14H0011

NATURAL GAS PIPELINE RUPTURE
TRANSCANADA PIPELINES LIMITED
LINE 400-1 AT MAINLINE VALVE SITE 402
NEAR OTTERBURNE, MANITOBA
25 JANUARY 2014

 The Transportation Safety Board of Canada (TSB) investigated this occurrence for the
purpose of advancing transportation safety. It is not the function of the Board to assign fault
or determine civil or criminal liability.

Pipeline Investigation Report P14H0011
Natural gas pipeline rupture
TransCanada PipeLines Limited
Line 400-1 at Mainline Valve Site 402
Near Otterburne, Manitoba
25 January 2014

Summary
At approximately 0115 Central Standard Time on 25 January 2014, a natural gas pipeline
rupture and ignition occurred on TransCanada PipeLines Limited’s 762 mm (30-inch) Line
400-1 at the site of Mainline Valve 402 near Otterburne, Manitoba. A crater measuring
approximately 24 metres long by 12.5 metres wide was created, and debris was ejected
approximately 100 metres from the rupture site. Natural gas burned for approximately 12
hours. Five residences in the immediate vicinity were evacuated, and Provincial Highway
303 was closed until the fire was extinguished. There were no injuries.
Le présent rapport est également disponible en français.

 Pipeline Investigation Report P14H0011   1

Factual information
At approximately 0115 Central Standard Time on 25 January 2014, a natural gas pipeline
rupture and ignition occurred on TransCanada PipeLines Limited’s 762 mm (30-inch) Line
400-1 at the site of Mainline Valve (MLV) 402 near Otterburne, Manitoba. A crater measuring
approximately 24 metres long by 12.5 metres wide was created, and debris was ejected
approximately 100 metres from the rupture site.
Prior to the occurrence, the TransCanada PipeLines Limited (TransCanada) Mainline system
had been operating normally. The operating pressure of the pipeline system at the
occurrence site was about 6330 kilopascals (kPa), based on the daily average supervisory
control and data acquisition (SCADA) data. For this section of the TransCanada system, the
maximum operating pressure, as approved by the National Energy Board (NEB), was
7030 kPa. Due to lack of customer demand, gas had not been flowing since 5 January 2014 in
pipeline 400-1. However, static pressurized gas was present in the line between closed
valves.
The occurrence site is located on TransCanada’s Line 400-1, at MLV 402, approximately
50 km south of Winnipeg, Manitoba. It is surrounded by agricultural land, with a flat
topography. The area is sparsely populated with the nearest dwelling approximately
540 metres to the east. The closest roadway is Provincial Highway 303, located
approximately 75 metres to the south. Otterburne, Manitoba, the nearest town, has a
population of about 120 residents (Figure 1).
After the initial failure and fire, natural gas burned for approximately 12 hours at the
occurrence site. Residents of 5 homes in the immediate vicinity were evacuated until the fire
self-extinguished. As a precaution, two adjacent pipelines, lines 400-2 and 400-3, were shut
down, assessed, and returned to service on 26 January 2015. This resulted in the loss of
natural gas service to 9 rural communities in Manitoba for approximately 80 hours.
The emergency measures implemented by TransCanada included the trucking of
compressed natural gas to local hospitals and emergency shelters. Normal gas delivery to
affected communities resumed on 28 January 2014 after initial repairs were completed.
At the time of the occurrence, the temperature was −26°C with calm winds out of the north.
Southern Manitoba was experiencing extreme cold-weather conditions that winter, one of
the coldest winters since 1898.

 2   Transportation Safety Board of Canada
Figure 1. Occurrence site (Source: Google Earth, with TSB annotations)

TransCanada’s pipeline system
TransCanada’s Canadian Mainline natural gas pipeline system extends from the Alberta–
Saskatchewan border to the Quebec–Vermont border and consists of 57 compressor stations
and more than 14 000 km of underground large-diameter pipe. The system, which is
composed of up to 8 parallel pipelines, is divided into approximately 30-km intervals by
mainline isolation valves.
Line 400 consists of 3 parallel pipelines extending south from Compressor Station 41 on
TransCanada’s Mainline near Winnipeg, Manitoba, to the export/import point at Emerson,
Manitoba. Line 400-1, a 30-inch diameter pipeline, was constructed in 1960; Line 400-2, a 36inch diameter pipeline, was constructed in 1969; and Line 400-3, a 48-inch diameter pipeline,
was constructed in 1990. These 3 pipelines supply natural gas to various customers along the
route and also interconnect with Viking Gas Transmission and Great Lakes Gas
Transmission at the Canada–USA border.
Although there are no compression facilities on Line 400, there are 5 MLV sites along the
pipeline. The MLV sites house the mainline isolation valves, crossover valves, associated
piping, and controls. Gas can flow in either direction (north to south or south to north) in
each of the 3 pipelines, depending on the configuration of the system.
At the time of the occurrence,
•

Line 400-1 had not been flowing gas since 5 January 2014 due to market demand;

•

Line 400-2 was flowing north to south;

 Pipeline Investigation Report P14H0011   3

•

Line 400-3 was isolated 1 at compressor station 41 and was not flowing.

Line 400-1 was designed in 1960 to the American Standards Association (ASA) B31.1.8 code.
The 762 mm (30-inch) external diameter pipeline with nominal wall thickness of 9.5 mm was
originally coated with coal tar enamel. It was constructed with American Petroleum Institute
(API) Grade 52 mild carbon steel pipe, which has a specified minimum yield strength
(SMYS) of 359 megapascals (MPa). At the time of construction, there was no requirement to
perform radiographic examination of every pipeline weld, nor was there a requirement to
retain weld inspection and test records.

Testing and inspection of Line 400-1
Line 400-1 had been hydrostatically tested when the pipeline was originally commissioned in
1960. No other pressure test had been performed on Line 400-1 since then. Welding and nondestructive examination records from the commissioning of Line 400-1 had not been
retained.
Internal inspections of Line 400-1 had been performed as follows:
•

In 2001, the pipeline was inspected using a caliper 2 tool and a high-resolution
magnetic flux leakage 3 (MFL) tool.

•

In 2009, the pipeline was again inspected using a high-resolution MFL tool.

In the vicinity of the occurrence, integrity-related activities had been performed as follows:
•

In 1997, a single excavation was performed 9 metres downstream of MLV 402 to
inspect for the presence of external corrosion.

•

In 1998, 1999, and 2009, a series of investigative excavations were performed in the
adjoining valve sections to inspect for external corrosion and stress corrosion
cracking 4 (SCC). The closest excavation occurred approximately 3 km downstream of
MLV 402.

Following the 1999 excavations, a 38-metre section of pipe located upstream of MLV 402 on
Line 400-1 was cut out and replaced due to the presence of SCC.

1

Gas is prevented from entering the pipeline section by way of closing valves specifically intended
for that purpose.

2

Caliper in-line inspection tools assess deformation of the pipe cross section.

3

MFL in-line inspection tools are designed to identify areas of internal and external metal loss, such
as corrosion.

4

SCC is a form of environmentally assisted cracking that occurs due to the combined interaction of
a tensile stress, a corrosive environment, and a susceptible material. SCC reduces the load-bearing
capacity of the pipeline.

 4   Transportation Safety Board of Canada

Design and construction of the MLV 402 site
The MLV 402 site was designed and built in 1960 as part of the construction of Line 400-1.
Line 400-2 was constructed in 1969, and was tied over to Line 400-1 at MLV 402 and MLV
403 in 1979. The original 1960 design and as-built drawings of the MLV 402 site could not be
located. However, since the MLV 402 site is of the same design as the MLV 403 site, the asbuilt drawings of the MLV 403 site were examined and compared with the current
configurations of both MLV sites. 5 No inconsistencies with respect to valve supports were
identified.
Over the years, multiple excavations and backfill activities had occurred in the vicinity of the
MLV 402 site as part of normal facility repair, maintenance, and upgrade. The most recent
maintenance activity at this location was in early January 2014, for gas handling operations,
which involved snow removal to gain access to the valve site.

Site examination
A detailed site examination was performed after the occurrence, and the following was
determined:

5

•

The pipeline failure resulted in 2 separate break locations approximately 11 metres
apart (Figure 2).

•

Break 1 occurred approximately 1 metre north of MLV 402-1, at a circumferential
transition weld between a fitting (bypass tee) and the adjoining pipe. There was no
significant metal deformation observed at this break location.

•

Break 2 occurred south of MLV 402-1, at a girth weld between two sections of welded
pipe. A sharp wrinkle at the top of the pipe was observed at this break location,
indicating that this was likely a secondary break.

•

A large crater (approximately 24 metres long by 12.5 metres wide) had been formed,
exposing the failed pipeline as well as MLV 402-1 (Photo 1).

•

Within the crater, the external coating of the pipeline was completely destroyed by
the fire.

•

One concrete support pad was observed under MLV 402-1.

The MLV 403 site was excavated for inspection as part of TransCanada’s integrity assessment of
Line 400-1 following the occurrence.

 Pipeline Investigation Report P14H0011   5
Figure 2. Lines 400-1 and 400-2 and associated piping and valves in the vicinity of the failure at
the MLV 402

Photo 1. Pipeline failure damage

 6   Transportation Safety Board of Canada

Laboratory analysis of the failed pipe
The failed sections of pipe (approximately 14.36 metres)—including MLV 402-1—were cut
out and transported to TransCanada’s compressor station 41 in Ile-des-Chênes, Manitoba.
After initial examination, the pipe components were shipped to the Acuren Group Inc.
(Acuren) laboratory in Edmonton, Alberta, for metallurgical analysis.
The analysis included visual examination, photography, magnetic particle inspection,
radiography, metallography, scanning electron microscopy, mechanical testing, and
chemical analysis, and the following was determined:
•

The pipe failed at a pre-existing crack that was present in the heat-affected zone 6 of a
girth weld, located north of MLV 402-1 (Photo 2). This girth weld joined the pipeline
to the bypass tee. The bypass tee 7 was completed in 1960 as part of the original
construction.

•

The pre-existing weld crack had acted as the initiation site for the circumferential
brittle fracture of the pipe section.

•

The pre-existing weld crack had likely formed at the time of the pipeline’s
construction due to poor welding quality and an inadequate welding procedure.
There was no indication that it had grown in service.

•

The weld at the failure location was likely performed using a manual shielded metal
arc weld process.

•

Similar pre-existing weld cracks of less severity were found at other locations on the
examined section of pipe.

•

Some minor environmental degradation (localized surface corrosion and SCC) was
observed at locations away from the failure. The surface corrosion and SCC were not
considered to be factors in the occurrence.

•

The chemical composition and mechanical (tensile) properties of the pipe steel
conformed to the specification requirements that existed at the time of manufacture.

•

The pipe steel toughness was low and would not meet the current requirements;
however, this parameter was not specified in code or pipeline industry standards at
the time of the pipeline’s construction.

•

The heat-affected zone at the girth weld exhibited very high hardness and was more
brittle than the base steel.

6

Area of base metal which has had its microstructure and properties altered by welding.

7

T-shaped fitting with 3 outlets, used to route gas into another pipe section for operational or
maintenance purposes.

 Pipeline Investigation Report P14H0011   7
Photo 2. Pre-existing crack at girth weld

Regulatory requirements for pipeline integrity management
Section 40 of the NEB Onshore Pipeline Regulations, 1999 (OPR) requires a company to develop
a pipeline integrity management program. While the OPR does not prescribe the integration
of all industry standards or best practices into pipeline integrity management programs, it
requires companies, through incorporation by reference in subsection 4(1), to adhere to
mandatory Canadian Standards Association (CSA) Z662 8 requirements.
While the NEB, in its Guidance Notes for the Onshore Pipeline Regulations, 1999, provides
some direction in developing a pipeline integrity management program, regulated
companies have flexibility and discretion to develop the content of their pipeline integrity
management program. Therefore, companies develop pipeline integrity management
programs tailored to their specific circumstances, and will initiate corrective action for
defects which are known to exist or are found to exceed criteria set in CSA Z662.
The effectiveness of each regulated company’s program is monitored by the NEB on an
ongoing basis, with the goal of ensuring that pipelines are suitable for continued safe,
reliable, and environmentally responsible service.

8

Canadian Standards Association (CSA) standard Z662, Oil and Gas Pipeline Systems.

 8   Transportation Safety Board of Canada

TransCanada’s integrity management program
TransCanada’s integrity management program (IMP) is the governing document the
company uses for managing the integrity of its pipeline facilities. The IMP uses a risk-based
pipeline integrity management process. It is based on various standards such as CSA Z662
(as required by the regulatory provisions) as well as various other industry standards and
recommended practices, such as certain annexes to CSA Z662, and relevant codes and/or
standards of the American Society for Mechanical Engineers, the American Petroleum
Institute, and the National Association of Corrosion Engineers.
One of the core components of the IMP is the management of the safety and reliability of line
pipe and other facilities. The IMP includes continuous monitoring of all the operation and
maintenance aspects of line pipe and other facilities. Identified or observed deficiencies are
escalated as necessary in accordance with TransCanada’s written procedures so that every
identified situation is addressed.
Manufacturing defects are one of the system-integrity threats identified in the IMP.
TransCanada’s approach to quantifying and mitigating such threats includes the use of
engineering critical assessments, in-line inspections, and investigative digs, in conjunction
with non-destructive examinations.

 Pipeline Investigation Report P14H0011   9

Analysis
The accident
Line 400-1 ruptured approximately 1 metre north of MLV 402-1 due to a circumferential
brittle fracture that initiated at a pre-existing crack. The pre-existing crack was a delayed
hydrogen crack located in the hard heat-affected zone of the circumferential transition weld
between a bypass tee and a short section of adjacent pipe. This crack had been formed at the
time of the pipeline’s construction, likely due to an inadequate welding procedure and poor
welding quality. The weld defect had remained stable for over 50 years prior to the failure
and there was no indication that it had grown in service. Due to internal pipe pressure and
forces in reaction to the failure, MLV 402-1 and an 11 metre–long section of pipe to the south
were lifted up during the failure. This resulted in a sharp wrinkle at a girth weld at the top of
the pipe, causing a secondary failure. The natural gas released from the pipeline ignited, and
the resulting fire burned for approximately 12 hours.
The weld at the initial failure point would have been performed manually at the valve
fabrication shop, as was the practice at the time of construction. The welding would likely
have been completed with welding consumables and practices in place at that time. The
strength of these welds would likely have matched the grade of the pipe and fittings.
The original standard for the pipeline’s construction, ASA B31.1.8, did not require every
weld to be inspected using radiography. Furthermore, as the standard had no requirement
for the retention of weld inspection and test records, no such records were retained. Based on
standard industry practice at the time of construction, the weld at the failure location had
likely been inspected only by visual means.
The source of the incremental stresses that caused the fracture could not be determined with
certainty. It is likely that one or more sources of secondary loading stresses were present at
the valve assembly. Possible sources include
•

weakened soil support in the vicinity of the MLV 402 site, which was due to multiple
excavations and backfill activities over the years as part of normal facility repair and
maintenance;

•

extreme cold weather conditions that may have driven frost deeper into the ground
when snow was removed as part of the maintenance work performed earlier in
January 2014 at and around the MLV 402 site; and

•

thermal contraction that may have occurred when the pipeline cooled due to the
absence of gas flow for 20 days.

Testing and inspection of Line 400-1
The segment of Line 400-1 that failed was hydrostatically tested when the pipeline was
originally commissioned in 1960. No other pressure test had been performed on Line 400-1
since that time.

 10   Transportation Safety Board of Canada

The integrity management program (IMP) in effect for Line 400-1 at the time of the
occurrence included the management of integrity threats due to possible manufacturing and
construction defects. The IMP included the use of in-line inspection in conjunction with
targeted integrity excavations. In 2001 and 2009, Line 400-1 was internally inspected using
caliper and high-resolution magnetic flux leakage tools. Since 1997, 36 integrity excavations
involving non-destructive examinations of exposed pipe surfaces had also been performed at
selected locations. These activities identified areas of external corrosion and stress corrosion
cracking, which were subsequently repaired. TransCanada’s IMP also relied on an
engineering assessment to evaluate integrity threats due to manufacturing defects on this
pipeline, and determine its fitness for service. If integrity threats due to manufacturing
defects, especially in older pipelines, are not identified, pipeline integrity may be
compromised, increasing the risk of in-service failures.

 Pipeline Investigation Report P14H0011   11

Findings
Findings as to cause and contributing factors
1.

Line 400-1 failed due to a circumferential brittle fracture that initiated at a preexisting crack that had remained stable for over 50 years prior to the occurrence.

2.

The crack had formed at the time of the pipeline’s construction, likely due to an
inadequate welding procedure and poor welding quality.

3.

During the failure, MLV 402-1 and an 11 metre–long section of pipe to the south lifted
up, resulting in a sharp wrinkle at a girth weld at the top of the pipe, causing a
secondary break.

4.

Soil support in the vicinity of the MLV 402 site may have been weakened due to
multiple excavations and backfill activities over the years as part of normal facility
repair and maintenance.

5.

Frost in the ground was likely deeper than normal due to the record cold winter in
southern Manitoba.

6.

Maintenance work in January 2014 at and around the MLV 402 site may have driven
frost even deeper into the ground.

7.

Secondary loading of the valve assembly with respect to the pipe may have occurred,
increasing the stresses at the failure location.

8.

Thermal contraction may have occurred when the pipeline cooled due to the absence
of gas flow for 20 days.

Findings as to risk
1.

If integrity threats due to manufacturing defects, especially in older pipelines, are not
identified, pipeline integrity may be compromised, increasing the risk of in-service
failures.

Other findings
1.

The pipeline’s original construction standard did not require the inspection of every
weld using radiography, and the weld at the failure location had likely been
inspected only by visual means.

2.

The pipeline’s original construction standard had no requirement for the retention of
weld inspection and test records, and no such records were likely retained.

 12   Transportation Safety Board of Canada

Safety action
Safety action taken
National Energy Board
Following the occurrence, the following safety actions were taken by the National Energy
Board:
1. TransCanada was required to submit an engineering assessment demonstrating that Line
400-3 was fit for service prior to returning the pipeline to service on 26 January 2014.
2. TransCanada was required to investigate all remaining valve sites along Line 400-1 to
determine the existence of valve assemblies similar to that in the incident.
3. TransCanada was required to submit an engineering assessment demonstrating the
fitness for service of Line 400-1 prior to its return to service.
4. TransCanada was required to undertake a review of its valve installations to evaluate
whether similar valve assemblies exist throughout its system.

TransCanada
Following the occurrence, the following safety actions were taken by TransCanada:
1. In February 2014, a ground-based leak detection was completed 500 metres upstream
and downstream of the occurrence location. No leaks were detected.
2. A program was initiated to excavate, inspect and, where applicable, repair all of the
mainline valve assemblies on Line 400-1. The program included
•

confirmation of the presence of supports as per design drawings;

•

inspection of all the girth welds in the vicinity of the valve assemblies to ensure their
integrity, using magnetic particle inspection, radiography and ultrasonic inspection;

•

performance of hardness testing on all flash butt-welded pups that are part of the
original valve assemblies; and

•

repair of defects exceeding the acceptance criteria outlined in CSA Z662.

3. In October 2014, an engineering assessment was prepared by TransCanada to
demonstrate safe operation of the pipeline at a reduced pressure; the assessment was
submitted to the National Energy Board.
4. Following the return to service of Line 400-1, TransCanada performed magnetic flux
leakage and electromagnetic acoustic transducer in-line inspections of the pipeline to rule
out other threats to safe operation.
5. In 2014, various cathodic protection upgrades were performed, and a complete closeinterval survey of the cathodic protection system on the entire Line 400 was completed.

 Pipeline Investigation Report P14H0011   13

This report concludes the Transportation Safety Board’s investigation into this occurrence. The Board
authorized the release of this report on 10 June 2015. It was officially released on 28 July 2015.
Visit the Transportation Safety Board’s website (www.tsb.gc.ca) for information about the TSB and
its products and services. You will also find the Watchlist, which identifies the transportation safety
issues that pose the greatest risk to Canadians. In each case, the TSB has found that actions taken to
date are inadequate, and that industry and regulators need to take additional concrete measures to
eliminate the risks.