Final Report AO-2013-008: Boeing 737-300, ZK-NGI,
Loss of cabin pressure, near Raglan, Waikato, 30 August 2013

Double engine power loss, Near Springston, Canterbury, 5 May 2014

 The Transport Accident Investigation Commission is an independent Crown entity established to
determine the circumstances and causes of accidents and incidents with a view to avoiding similar
occurrences in the future. Accordingly it is inappropriate that reports should be used to assign fault or
blame or determine liability, since neither the investigation nor the reporting process has been
undertaken for that purpose.
The Commission may make recommendations to improve transport safety. The cost of implementing
any recommendation must always be balanced against its benefits. Such analysis is a matter for the
regulator and the industry.
These reports may be reprinted in whole or in part without charge, providing acknowledgement is made
to the Transport Accident Investigation Commission.

 Final Report
Aviation inquiry 13-008
Boeing 737-300, ZK-NGI
Loss of cabin pressure
near Raglan, Waikato
30 August 2013

Approved for publication: July 2016

 Transport Accident Investigation Commission

About the Transport Accident Investigation Commission
The Transport Accident Investigation Commission (Commission) is a standing commission of inquiry and
an independent Crown entity responsible for inquiring into maritime, aviation and rail accidents and
incidents for New Zealand, and co-ordinating and co-operating with other accident investigation
organisations overseas. The principal purpose of its inquiries is to determine the circumstances and
causes of the occurrences with a view to avoiding similar occurrences in the future. Its purpose is not to
ascribe blame to any person or agency or to pursue (or to assist an agency to pursue) criminal, civil or
regulatory action against a person or agency. The Commission carries out its purpose by informing
members of the transport sector and the public, both domestically and internationally, of the lessons
that can be learnt from transport accidents and incidents.

Commissioners
Chief Commissioner

Helen Cull, QC (until 8 July 2016)

Deputy Chief Commissioner

Peter McKenzie, QC

Commissioner

Jane Meares

Commissioner

Stephen Davies Howard

Key Commission personnel
Chief Executive

Lois Hutchinson

Chief Investigator of Accidents

Captain Tim Burfoot

Investigator in Charge

Peter R Williams

General Counsel

Cathryn Bridge

Email

inquiries@taic.org.nz

Web

www.taic.org.nz

Telephone

+ 64 4 473 3112 (24 hrs) or 0800 188 926

Fax

+ 64 4 499 1510

Address

Level 16, 80 The Terrace, PO Box 10 323, Wellington 6143, New Zealand

 Important notes
Nature of the final report
This final report has not been prepared for the purpose of supporting any criminal, civil or regulatory action
against any person or agency. The Transport Accident Investigation Commission Act 1990 makes this
final report inadmissible as evidence in any proceedings with the exception of a Coroner’s inquest.
Ownership of report
This report remains the intellectual property of the Transport Accident Investigation Commission.
This report may be reprinted in whole or in part without charge, provided that acknowledgement is made
to the Transport Accident Investigation Commission.
Citations and referencing
Information derived from interviews during the Commission’s inquiry into the occurrence is not cited in
this final report. Documents that would normally be accessible to industry participants only and not
discoverable under the Official Information Act 1980 have been referenced as footnotes only. Other
documents referred to during the Commission’s inquiry that are publicly available are cited.
Photographs, diagrams, pictures
Unless otherwise specified, photographs, diagrams and pictures included in this final report are provided
by, and owned by, the Commission.
Verbal probability expressions
The expressions listed in the following table are used in this report to describe the degree of probability
(or likelihood) that an event happened or a condition existed in support of a hypothesis.
Terminology

Likelihood of the occurrence/outcome

Equivalent terms

Virtually certain

> 99% probability of occurrence

Almost certain

Very likely

> 90% probability

Highly likely, very probable

Likely

> 66% probability

Probable

About as likely as not

33% to 66% probability

More or less likely

Unlikely

< 33% probability

Improbable

Very unlikely

< 10% probability

Highly unlikely

Exceptionally unlikely

< 1% probability

  

Boeing 737 
(Photograph used with permission)

 

 

    

Legend

approximate location of
incident

 

 

Source: mapsof.net
Location of incudent

Contents
Abbreviations ..................................................................................................................................................... ii
Glossary

....................................................................................................................................................... ii

Data summary .................................................................................................................................................. iii
1.

Executive summary ...................................................................................................................................1

2.

Conduct of the inquiry ...............................................................................................................................2

3.

Factual information ...................................................................................................................................3
3.1.

Introduction – the need for cabin pressurisation and emergency oxygen ............................3

3.2.

The incident ...............................................................................................................................3

3.3.

Personnel information ..............................................................................................................5

3.4.

Aircraft information ...................................................................................................................5

3.5.

Boeing 737-300 pressurisation ...............................................................................................5

3.6.

Flight recorders .........................................................................................................................6

3.7.

Post-incident testing .................................................................................................................7
Initial inspection ........................................................................................................................7
Test for structural breach .........................................................................................................7
Outflow valve tests ....................................................................................................................7
Safety relief valve tests .............................................................................................................7
Further testing ...........................................................................................................................8

3.8.
4.

Previous occurrences................................................................................................................8

Analysis ......................................................................................................................................................9
4.1.

Introduction ...............................................................................................................................9

4.2.

Factors that affect cabin pressure ...........................................................................................9

4.3.

Defects that could cause a reduced air supply .......................................................................9

4.4.

Defects that could cause an excessive air outflow .............................................................. 10
Controlled air outflow ............................................................................................................. 10
Uncontrolled leakage ............................................................................................................. 10
Safety relief valves ................................................................................................................. 10
Pressure controller ................................................................................................................. 11
Summary ................................................................................................................................. 11

4.5.

Response to the emergency .................................................................................................. 11
Flight crew actions.................................................................................................................. 11
Response in the cabin............................................................................................................ 13
Crew training and procedures ............................................................................................... 14

4.6.

Cabin Altitude Warning checklist .......................................................................................... 15

5.

Findings .................................................................................................................................................. 16

6.

Safety actions ......................................................................................................................................... 17

7.

6.1.

General ................................................................................................................................... 17

6.2.

Safety actions addressing safety issues identified during an inquiry ................................. 17

6.3.

Safety actions addressing other safety issues ..................................................................... 17

Recommendations ................................................................................................................................. 18
7.1.

General ................................................................................................................................... 18

 8.

Key lessons............................................................................................................................................. 19

9

Citations .................................................................................................................................................. 20

Appendix 1: Boeing 737-300 technical information .................................................................................... 21
Pressurisation system ............................................................................................................................ 21
Oxygen system ........................................................................................................................................ 23
Toilet smoke alarms ............................................................................................................................... 23
Post-incident fault finding ...................................................................................................................... 23
Appendix 2: Boeing 737 emergency checklists ........................................................................................... 25
Appendix 3: Time of useful consciousness................................................................................................... 29
Time of useful consciousness (TUC) ..................................................................................................... 29

 Figures
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6

Cabin altitude compared with flight altitude .............................................................................. 3
Positions of cabin crew and their subsequent movement ........................................................ 4
Schematic of Boeing 737 pressurisation system ...................................................................... 6
Oxygen tubing, showing no flow (left) and full flow (right) ....................................................... 14
Boeing 737 pressurisation system components ..................................................................... 21
Boeing 737-300 pressurisation system control panel ............................................................ 22

Final report AO-2013-008   Page i

 Abbreviations
Boeing

Boeing Commercial Airplanes Limited

CAA

Civil Aviation Authority of New Zealand

Commission

Transport Accident Investigation Commission

FA1

flight attendant 1, senior cabin crew member

FA2, FA3

other flight attendants

ft

feet

NTSB

National Transportation Safety Board (United States)

psi

pounds per square inch

TUC

time of useful consciousness

Glossary
altitude

the height above mean sea level

annunciator

a captioned light that provides information on the state of a system

bleed air

air tapped off one or more compressor stages of a turbine engine and used to
supply some other systems

cabin altitude

the pressure of the air inside an aircraft cabin expressed as the altitude in the
atmosphere at which the same pressure would be found

differential pressure

the difference between cabin air pressure and the outside air pressure

pack

an air-conditioning system unit

pilot flying

the pilot actually manipulating the flight controls

pilot monitoring

the support pilot

Page ii   Final report AO-2013-008

 Data summary
Aircraft particulars
Aircraft registration:

ZK-NGI

Type and serial number:

Boeing 737-319, 25608

Number and type of engines:

two CFM International CFM 56-7B turbofans

Year of manufacture:

1999

Operator:

Air New Zealand Limited

Type of flight:

scheduled air transport

Persons on board:

81

Pilot in command’s licence:

airline transport pilot licence (aeroplane)

Pilot in command’s age:

44

Pilot in command’s total
flying experience:

12,100 hours, of which 5,200 were on type

Date and time

30 August 2013, 08191

Location

en route, near Raglan, Waikato

Injuries

nil

Damage

nil

Times in this report are New Zealand Standard Time (co-ordinated universal time +12 hours) expressed in 24hour format.
1

Final report AO-2013-008   Page iii

 1.

Executive summary

1.1.

On 30 August 2013 a Boeing 737-300 aeroplane operated by Air New Zealand was on a
scheduled service between Wellington and Auckland. After the aeroplane began its descent to
Auckland, it lost cabin pressure. The pilots commenced the relevant emergency procedures
and made a normal landing at Auckland Airport. No-one was injured and the aeroplane was
not damaged.

1.2.

The Transport Accident Investigation Commission (Commission) was unable to identify the
cause of the depressurisation despite extensive testing and a specialist examination of the
pressurisation system. An intermittent defect within the air-conditioning and pressurisation
system could not be excluded as the cause.

1.3.

The Commission made findings relating to the following safety issues:


non-adherence to the published emergency checklists for a loss of cabin
pressure



the training of cabin crew in the use of the emergency oxygen equipment and
the cabin depressurisation procedure.

1.4.

The operator acted to correct these issues. Therefore the Commission made no
recommendations regarding them.

1.5.

In addition, the inquiry considered the potential for the cabin to be pressurised on the ground
following the use of the Cabin Altitude Warning checklist. Boeing subsequently amended the
checklist to reduce that risk.

1.6.

The key lessons identified from the inquiry into this occurrence were as follows:


an unexpected loss of cabin pressure in any aeroplane is a serious event that
can cause both passengers and crew to lose consciousness rapidly from a
lack of oxygen. In such an event the appropriate emergency actions must be
undertaken immediately. Where oxygen masks are fitted, passengers and
cabin crew must put on their masks and await further instruction from the
flight crew



the purpose of emergency procedure checklists is to ensure that crew
members do not miss an important action at a critical time of high workload.
Therefore, unless the captain has an exceptional reason to deviate from a
checklist, it should be performed from beginning to end, if possible without
interruption, and without omitting any step



crew members must be thoroughly trained in and familiar with all emergency
equipment and procedures, because the equipment and procedures are for
their own protection as well as that of the passengers. They need to be alert
for emergency situations that differ from the standard scenarios that are
practised and demonstrated repeatedly



an aircraft door will be very difficult to open on the ground while the cabin is
still pressurised, and this can delay an evacuation if it is called for. When
pilots have been controlling the cabin pressure manually, they must ensure
that the cabin is fully depressurised to allow the doors to be opened



special care must be taken with the maintenance of aircraft emergency
equipment, such as oxygen systems.

Final report AO-2013-008   Page 1

 2.

Conduct of the inquiry

2.1.

Shortly after the aeroplane landed at Auckland, Air New Zealand Limited (the operator)
notified the Transport Accident Investigation Commission (Commission) directly of the
incident. The operator promptly quarantined the aeroplane and its flight recorders. The
Commission opened an inquiry and notified the Civil Aviation Authority of New Zealand (CAA).

2.2.

In accordance with the protocols of Annex 13 to the Convention on International Civil Aviation,
the Commission notified the National Transportation Safety Board (NTSB) of the United States,
being the state of the aeroplane manufacturer. The NTSB took part in most communications
between the Commission, Boeing Commercial Airplanes Limited (Boeing) and the makers of
key pressurisation system components.

2.3.

Two Commission investigators travelled to Auckland on 30 August 2013 to begin the
investigation. They were present for the initial fault-finding conducted by the operator, and
consulted an investigator from the CAA about potential airworthiness issues.

2.4.

The pilots and two of the cabin crew were interviewed on 31 August 2013, and the third cabin
crew member was interviewed on 9 September 2013. Passengers for whom contact details
were available were sent a questionnaire on their perspectives of the incident.

2.5.

The Australian Transport Safety Bureau appointed an Accredited Representative and
successfully downloaded the cockpit voice recorder at the Bureau’s laboratory in Canberra on
5 September 2013.

2.6.

On 22 October 2013 Commission investigators observed a Boeing 737 flight simulator detail
in which the cabin altitude2 warning and emergency descent checklists were demonstrated.

2.7.

The completion of the inquiry report was delayed by higher-priority investigations. In addition,
it was apparent early in the investigation that the cause was unlikely to be determined.

2.8.

On 27 April 2016 the Commission approved a draft report for circulation to interested persons
for comment.

2.9.

Submissions were received from the operator, some of the crew and the aircraft
manufacturer. The Commission has considered all submissions and any changes as a result
of those submissions have been included in this final report.

2.10.

On 28 July 2016 the Commission approved the report for publication.

Cabin altitude is the pressure of the air inside an aircraft cabin expressed as the altitude in the atmosphere at
which the same pressure would be found. ‘Altitude’ is the height above mean sea level.
2

Page 2   Final report AO-2013-008

 3.

Factual information

3.1.

Introduction – the need for cabin pressurisation and emergency oxygen

3.1.1.

Turbine-powered aeroplanes generally fly at high altitudes because their performance is more
efficient in the less dense air. As altitude increases the atmospheric pressure decreases.
However, above about 10,000 feet (ft) (3,000 metres)3, the lower atmospheric pressure is
detrimental to people because their lungs do not absorb sufficient oxygen. As the oxygen
content of blood decreases, one’s ability to think and act efficiently becomes impaired. In
severe cases unconsciousness and death can occur.

3.1.2.

This problem is avoided for aeroplane passengers by pressurising the aeroplane, using the
conditioned air that is pumped into the cabin. Aeroplanes that fly above 10,000 ft will usually
be pressurised. The cabin air is normally maintained at a pressure that is equivalent to that
found between 5,000 and 8,000 ft in the atmosphere. Therefore, when the cabin is
pressurised, the ‘cabin altitude’ is lower than the ‘flight altitude’ (see Figure 1).

Figure 1
Cabin altitude compared with flight altitude (illustrative only)

3.1.3.

Civil aviation rules, in general, require pressurised aeroplanes to have emergency oxygen
available in case cabin pressure is lost at high altitude. Typically, the emergency oxygen is
supplied automatically from units above the seats (and in the toilets) before the cabin
pressure decreases to an unsafe level. The pilots have a separate oxygen supply, but the
supply for pilots and passengers is limited. Therefore, in the event of a loss of cabin pressure,
the aeroplane must descend quickly to an altitude where there is adequate oxygen.

3.1.4.

A loss of cabin pressure is a rare event, but if mishandled it can cause injury or death. Prompt
and correct action on the part of the pilots may mean that control of the cabin pressure is
regained and the need for an emergency descent averted. However, if oxygen masks appear
in the cabin everyone must fit their mask immediately and keep it on until instructed
otherwise.

3.2.

The incident

3.2.1.

On Friday 30 August 2013 a Boeing 737-300, registered ZK-NGI, operated a scheduled return
flight between Auckland and Wellington. The crew comprised two pilots, both of captain rank,
and three cabin crew. For the flight back to Auckland the pilot in command was in the left

3

Imperial units are still used for vertical distances in most civil aviation jurisdictions.

Final report AO-2013-008   Page 3

 seat performing ‘pilot monitoring’ duties, and the pilot in the right seat was the ‘pilot flying’.4
The aeroplane departed Wellington with 76 passengers and climbed to a cruise altitude of
37,000 ft5, where it remained for approximately nine and a half minutes.
3.2.2.

When the aeroplane was passing approximately 30,000 ft on the descent to Auckland, the
cabin altitude warning horn sounded and the ‘cabin altitude’ annunciator6 illuminated. The
warnings meant that the cabin pressure was too low (above 10,000 ft equivalent altitude). An
indicator on the pressurisation system control panel on the flight deck overhead panel showed
that the cabin pressure was decreasing quickly. The pilots confirmed that the air-conditioning
and pressurisation systems were set correctly, and saw that no pressurisation system fault
lights were illuminated.

3.2.3.

The pilots put on their oxygen masks, initiated the emergency descent procedure, and advised
air traffic control. At about this time the senior flight attendant (designated ‘FA1’ by the
operator) called the flight deck on the intercom. She advised that the passenger oxygen
masks had deployed and checked that the pilots had put their masks on. When the cabin
loses pressure and the cabin altitude exceeds the equivalent of 14,000 ft, passenger masks
deploy automatically and a pre-recorded message plays over the public address system, telling
passengers to put on the nearest masks. The pilot flying confirmed with FA1 that the cabin
pressure had been lost.

3.2.4.

The pilots commenced the emergency actions for a loss of cabin pressure and an emergency
descent (see Appendix 2 for the emergency checklists). The pilot monitoring then silently
checked that all of the required actions had been completed correctly.

3.2.5.

One of the listed actions was to select the passenger oxygen switch to on.7 The pilot
monitoring did not do that because the associated annunciator was illuminated, indicating
that the passenger masks had already deployed.

3.2.6.

The cabin crew were preparing the cabin for landing when the masks deployed. FA1 was at
about mid-cabin, moving forward; one attendant (FA3) was in the rear galley; and the third
(FA2) was pushing a cart to the rear galley (see Figure 2). FA1 continued walking to her
normal crew station at the front left entry door and fitted a mask. She said the green flow
indicator was visible but the attached reservoir bag was not inflating. She was later uncertain
whether oxygen had been flowing. FA1 remained standing by her seat, observing the cabin,
until the pilots announced that masks could be removed.

Figure 2
Positions of cabin crew and their subsequent movements (generic cabin layout)

The ‘pilot flying’ is the pilot actually manipulating the controls; the ‘pilot monitoring’ is the support pilot who,
among other duties, makes the radio calls. Typically, pilots alternate these roles after each flight leg.
5 The aviation industry refers to a cruise altitude of 37,000 ft as ‘flight level 370’, but for the benefit of the general
reader the report expresses the altitudes in feet.
6 An annunciator is a captioned light on an instrument panel that provides information on the state of a system.
7 The switch was a back-up to the cabin pressure switch that automatically deployed the masks, and its position
did not affect the supply of oxygen to the masks (see paragraph 4.5.6).
4

Page 4   Final report AO-2013-008

 3.2.7.

FA3 first saw that the masks above the right rear door crew seat had deployed, but not those
above the left rear crew seat. When she saw that the masks had also deployed in the cabin,
she fitted a mask. FA2 pushed the cart to the galley, where FA3 helped her to stow it. FA2
donned a mask but was unsure whether oxygen was flowing to it. She observed that the
reservoir bag was not inflating like the bag on FA3’s mask. FA2 then manually deployed the
masks at the left rear door, fitted one and sat down next to FA3.

3.2.8.

It took approximately four minutes for the aeroplane to descend from 30,000 ft to below
10,000 ft, at which point the flight deck cabin altitude warning ceased. The pilots continued
the descent to 5,000 ft and maintained that altitude. Some of the cabin crew and passengers
said the cabin seemed hot, and many noticed a chemical smell. The right rear toilet smoke
alarm sounded, and later the smoke alarm for the forward toilet sounded. The crew took the
appropriate action in response to these alarms, which continued for the rest of the flight.8

3.2.9.

While the aeroplane was taxiing to the terminal after landing, the ‘equipment cooling OFF’ light
illuminated on the flight deck. The pilots switched to the alternate cooling source, the only
action required, but the annunciator remained illuminated.

3.2.10. At the terminal FA1 was unable to open the forward entry door because the cabin was still
slightly pressurised. The pilots depressurised the aeroplane manually and the doors were
then opened to disembark the passengers.
3.2.11. The incident occurred in daylight. Some passengers reported ear or sinus discomfort, which
for a few persisted for several days. Otherwise there were no injuries.
3.3.

Personnel information

3.3.1.

The pilot flying had more than 10,800 hours’ flight experience, including 3,500 hours on the
Boeing 737. He was employed in a fleet management role and had been on office or
simulator training duties for most of the six days prior to the incident. His most recent day
rostered free of duty had been 26 August 2015. On most days he had worked for 10 or 11
hours. He said he had been fit to fly on 30 August 2013.

3.3.2.

The pilot monitoring had more than 12,000 hours’ flight experience, including 5,200 hours on
the Boeing 737. He had returned from annual leave four days before the incident, had
worked for two days, and then had had a rostered day off. He said that he had been fit to fly
on 30 August 2013.

3.3.3.

The senior flight attendant, FA1, had been employed by the operator as a flight attendant in
1999 and promoted to purser in 2005. The other two flight attendants had a combined 22
years of flight attendant experience. They all considered themselves familiar with the Boeing
737 and said they had been fit to fly that day.

3.4.

Aircraft information

3.4.1.

The Boeing 737-300 is a short- to medium-range, narrow-body aeroplane powered by two
turbofan engines. It is a variant of the Boeing 737 family that has been in production since
1967. The normal crew is two pilots and three or four cabin crew. Depending on the cabin
configuration, up to 150 passengers can be carried.

3.4.2.

ZK-NGI had been registered in New Zealand on 20 November 1999. Air New Zealand retired
its Boeing 737 fleet in September 2015, but another New Zealand operator continued to use
the aeroplane type after that date.

3.5.

Boeing 737-300 pressurisation

3.5.1.

The Boeing 737-300 air-conditioning and pressurisation systems are typical for a turbinepowered aeroplane (see Figure 3). The cabin air is supplied by ‘bleed air’9 taken from the

The airport fire service inspected the aeroplane as soon as the engines were shut down and found no sign of fire.
Bleed air is air tapped off one or more compressor stages of a turbine engine and used to supply some other
systems.
8
9

Final report AO-2013-008   Page 5

 engines. The air-conditioning system (‘packs’) cools the very hot bleed air, then distributes it
at the desired temperature to the cabin. The continuous inflow of conditioned air pressurises
the cabin, with excess air being vented back to the atmosphere through the aft outflow valve.
3.5.2.

Under normal circumstances one of two identical digital pressure controllers regulates the
cabin pressure. The controllers maintain the required pressure by adjusting the aft outflow
valve. Unintended changes to the cabin pressure can be caused by low air inflow from the
engines or air-conditioning system, excessive leakage or a defect in the control system. The
pressure controllers detect internal and external failures that affect the control of cabin
pressure and, if appropriate, annunciate them on a flight deck panel regardless of whether the
faults are intermittent or not.

3.5.3.

See Appendix 1 for more information on the Boeing 737-300 cabin pressurisation system.

Figure 3
Schematic of Boeing 737 pressurisation system
(Hatched lines show bleed air flow from the engines to the packs, and conditioned air from the packs to the cabin)
(Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company)

3.6.

Flight recorders

3.6.1.

The aeroplane was fitted with a cockpit voice recorder with 30 minutes’ recording duration.
No useful information about the incident was obtained from the recorder because electrical
power was not removed soon enough after the engine shutdown to prevent the incident being
over-written. The operator later reminded its pilots that power must be removed from the
recorders after landing following a serious incident.10

3.6.2.

The aeroplane was fitted with a digital flight data recorder. However, unlike recorders on more
modern aeroplanes the recorder did not, and was not required to, record potentially useful
parameters such as actual bleed air duct pressures and the outflow valve position.

3.6.3.

A quick-access recorder was also fitted and that provided some data about the flight path.

10

The operator’s other jet aeroplanes were fitted with cockpit voice recorders with two-hour recording durations.

Page 6   Final report AO-2013-008

 3.7.

Post-incident testing

3.7.1.

Post-incident testing examined:

3.7.2.



the cabin pressure controllers



whether there was a structural breach that would have allowed air to escape



the outflow valve



the safety relief valves.

The operator’s engineering staff, in the presence of Commission investigators, followed the
fault-finding procedures (often called ‘troubleshooting’) given in Boeing Service Letter 737-SIL21-069 Airplane Pressurization – Guidance to Understanding.11
Initial inspection

3.7.3.

Both digital pressure controllers were tested with satisfactory results before the aeroplane
was towed from the terminal to a hangar and placed under quarantine. The manufacturer of
the controllers later tested them and downloaded their memory chips. These showed that
there had been an ‘inflow/leakage fail’ status message just over a minute prior to the cabin
altitude aural warning. That status meant there was a low inflow of air or excessive air
leakage, or possibly both conditions.

3.7.4.

The aeroplane was inspected visually for any sign of structural damage or mechanical defect,
and the condition of controls and oxygen masks in the flight deck and cabin was recorded
before electrical power was applied to the aeroplane to allow further checks.
Test for structural breach

3.7.5.

To test for a breach in the fuselage the cabin was pressurised on the ground using air from the
aeroplane’s auxiliary power unit. When the air supply was stopped the rate of pressure ‘leakdown’ was noted. The recorded leak rate was within limits but close to the maximum allowed.
The operator’s engineers considered that the test eliminated the likelihood of a major
structural breach in any fuselage areas that were difficult to access for inspection, such as
under the tail fin.
Outflow valve tests

3.7.6.

The memory chips of the digital pressure controllers recorded that the outflow valve had
closed appropriately when signalled to do so by the controllers in response to the loss of
pressure. As a precaution the outflow valve was replaced and tested by its manufacturer. The
valve had minor failures of some incoming test specifications, but the manufacturer said the
discrepancies, of which one related to the outflow valve position feedback to the pressure
controller, would not have caused the leakage condition recorded by the pressure controllers.
Safety relief valve tests

3.7.7.

The aeroplane has two cabin pressure safety relief valves, which open in the event of
excessive cabin pressure. They remain open until the pressure is relieved, then close.
Whether a safety relief valve has opened can be inferred only from data stored in the digital
pressure controller memory. There was no evidence that that had happened.

3.7.8.

One of these valves had been in place since the aeroplane was manufactured in 1999,
although it had been subjected to routine maintenance checks. The other valve had been
installed in 2012 following overhaul by the vendor.

11

Issued on 22 May 2006.
Final report AO-2013-008   Page 7

 3.7.9.

After the incident the operator removed and tested both valves. Neither valve met the
functional test requirements for ‘cracking’ pressure, which is the pressure when the valve
begins to open, nor the stabilised flow rate after the valve had opened.

3.7.10. The manufacturer, UTC Aerospace Systems in the United States, inspected the valves and
confirmed the operator’s results. The manufacturer considered that the results, and some
observed minor defects, were typical for the time the valves had been in service. The
manufacturer advised that such defects were not known to have caused any in-flight incidents
and would not have inhibited the correct operation of the valves. Boeing’s analysis concluded
that the defects with the cabin pressure relief safety valves would not have caused a cabin
depressurisation.
Further testing
3.7.11. After the initial fault-finding, the operator’s engineering staff performed another fuselage ‘leakdown’ test with a better result than the first test. Before the aeroplane was returned to
service it completed a satisfactory verification flight.
3.7.12. Boeing advised that the type of smoke detector fitted was sensitive to cabin pressure spikes
that could cause an alarm to activate.12 However, neither Boeing nor the oxygen generator
manufacturer (B/E Aerospace of the United States) knew of an oxygen generator having
caused a smoke alarm to activate.
3.7.13. For a more complete list of the testing and fault-finding carried out, see Appendix 1.
3.8.

Previous occurrences

3.8.1.

Between 2000 and 2013 the operator had had four other incidents involving a loss of cabin
pressure, although none had involved a rapid loss of pressure or the use of oxygen masks.
Three had been similar to the 30 August 2013 incident in as much as the pilots received a
cabin altitude warning but no indication of a pressurisation system defect, and the cabin
pressure had continued to decrease even though the aft outflow valve was closed.

This information was included as a note in the Boeing 737 maintenance manual task for performing a cabin
pressure leak test, but was not included in flight operation manuals.
12

Page 8   Final report AO-2013-008

 4.

Analysis

4.1.

Introduction

4.1.1.

Cabin depressurisation events are rare but potentially dangerous. The cabin pressurisation
system operated normally on the flight from Auckland to Wellington. On the return flight,
shortly after the descent to Auckland began, the cabin pressure began decreasing at a rate
equivalent to a climb rate of up to 4,000 ft per minute.13 (A decrease in the cabin pressure is
usually expressed as an increase in the cabin altitude.) Pilots would normally detect such a
rapid decrease in cabin pressure through physiological changes (for example, ear ‘popping’).
However, in this case the cabin rate increase appears to have occurred just prior to the cabin
altitude warning horn sounding, which gave no time for the flight crew to take pre-emptive
action to control the pressure change.

4.1.2.

In spite of extensive inspections and a detailed examination of key components of the
pressurisation system, no definite cause was found for the loss of cabin pressure. The
following analysis discusses a number of technical factors that might have contributed to the
cabin depressurising.

4.1.3.

This analysis also discusses the following three safety issues that were identified in the inquiry:

4.2.



non-adherence to the published emergency checklists for a loss of cabin
pressure



the training of cabin crew in the use of emergency oxygen equipment and the
cabin depressurisation procedure



the possibility of the cabin being pressurised on the ground following the use
of the Cabin Altitude Warning checklist.

Factors that affect cabin pressure
To pressurise the cabin, air is supplied continuously from the engines via the air-conditioning
packs. The pressure is regulated by controlling the exit of air from the aft outflow valve.
Therefore the cabin pressure is affected by the following factors:


the inflow, or supply, of air from the engines to the cabin



the controlled (regulated) leakage of air from the cabin



any uncontrolled leakage of air from the cabin.

4.3.

Defects that could cause a reduced air supply

4.3.1.

Key components of the air-conditioning and pressurisation system that are involved in the
supply of cabin air are:


the engine bleed valves



the packs.

4.3.2.

If the high stage14 bleed valve does not open when the engine thrust is reduced to begin a
descent, there will be low air flow from that engine. There have been incidents where high
stage bleed valves have had intermittent, but unidentifiable, defects. However, neither Boeing
nor the operator was aware of a high stage bleed valve defect having caused the cabin altitude
to increase at a rate exceeding 2,000 ft per minute.

4.3.3.

The aeroplane had had various bleed air system defects in the four months preceding this
occurrence, including low bleed (or ‘duct’) pressure from the engines. The most recent
occurrence had been a low duct pressure during a descent, which occurred six weeks before
this incident. The high-pressure (‘high-stage’) bleed valves for both engines had been replaced

The more correct unit for the cabin rates recorded by the pressure controller is ‘sea level feet per minute’.
The ‘high stage’ bleed valves are at a later stage of the compressor section. When they open, the higherpressure air maintains the required air mass flow for air-conditioning pack operation.
13
14

Final report AO-2013-008   Page 9

 several times. Defects had occurred with other bleed air system components, mainly those
connected with the left engine. There had been no other recorded defects in the six weeks
before this incident.
4.3.4.

On the incident flight the pilots followed the usual procedure of setting both packs to
automatic mode. If one pack is providing no flow when the packs are in automatic mode, the
other automatically increases its output to high flow. There was no indication of that
happening on this flight.

4.3.5.

The engine bleed valves and the packs tested satisfactorily after the incident.

4.4.

Defects that could cause an excessive air outflow
Controlled air outflow

4.4.1.

The principal components involved with the controlled leakage or outflow of cabin air are:


the aft outflow valve



the forward outflow valve.

4.4.2.

According to Boeing and the manufacturer of the outflow valve, the minor defects found with
the valve were typical for its time in service. They would not have caused the cabin pressure to
decrease at the rate that it did.

4.4.3.

The pressurisation control system also signals the forward outflow valve to close when the aft
outflow valve is fully closed. Because the aft valve remained closed for the rest of the flight,
the forward valve would also have stayed closed. This was a normal response of the system
and, although it caused the ‘Equipment cooling OFF’ light to illuminate after landing (see
paragraph 3.2.9), it did not require any corrective maintenance action.
Uncontrolled leakage

4.4.4.

Uncontrolled leakage can occur at a number of places: through door seals, where wire bundles
and controls penetrate bulkheads, from various drains, skin cracks and ruptures, and as a
result of a defect in an air-conditioning or pressurisation system component. A malfunction of
one of the aeroplane systems that was a minor user of bleed air would not, on its own, have
caused the substantial loss of cabin pressure that occurred.15

4.4.5.

An inspection of the aeroplane prior to the ground test of the pressurisation system found no
evidence of a structural factor having contributed to the incident. However, a worn cabin entry
door seal was identified and replaced. In the leak-down tests the fuselage met the minimum
requirement for retaining pressure.

4.4.6.

The fuselage was proven to be sufficiently airtight by remaining partially pressurised following
the emergency procedure until after the landing.
Safety relief valves

4.4.7.

15
16

Boeing confirmed that there had been cabin depressurisation events caused by safety relief
valves activating unnecessarily while in the cruise. However, Boeing said it was unlikely that
the cabin differential pressure16 in this case had increased to 8.1 pounds per square inch
(psi), which was the lower pressure found during the ‘crack’ testing of the safety relief valves
fitted to this aeroplane (see paragraph 3.7.9). This conclusion was partly confirmed by the
post-incident verification flight, during which a climb was made to 37,000 ft with a flight

For example, the hydraulic and water systems use bleed air to pressurise the fluid reservoirs.
Differential pressure is the difference between the cabin air pressure and the outside air pressure.

Page 10   Final report AO-2013-008

 altitude of 36,000 ft set in the pressure controller (as for the incident flight).17 The differential
pressure increased to only 7.9 psi compared with the normal cruise differential of 7.8 psi.
Pressure controller
4.4.8.

According to Boeing’s description of the pressurisation system, the ‘Auto fail’ annunciator on
the overhead panel should illuminate if the pressure controller senses a sustained cabin rate
of climb greater than 2,000 ft per minute. That light did not illuminate during this incident,
and the pressure controller did not record that it had come on. This suggested that the high
climb rate observed by the pilots was of very short duration. Both digital pressure controllers
tested satisfactorily after the incident, but both were replaced as a precaution.
Summary

4.4.9.

No individual component of the cabin pressurisation system was identified as having caused
the loss of cabin pressure. The outflow valve, selector panel and cabin pressure controller all
have internal, built-in test functions that report any faults affecting the control of cabin
pressure, whether intermittent or constant18, to the controller, which records these faults to
non-volatile memory. The non-volatile memory data for this incident was examined and no
pressurisation system failures were recorded. The tear-down examination of those
components revealed no faults. Experience has shown that older pressurisation system
components can have intermittent faults that do not show during subsequent testing. A
combination of components with low or marginal performance could have caused the incident,
but no such combination was identified. Boeing submitted that the cabin pressure continuing
to decrease when the outflow valve was closed indicated a root cause that was related to
insufficient cabin air inflow or excessive fuselage leakage.
Findings

4.5.

1.

The cause of the loss of cabin pressure was not determined.

2.

An intermittent defect within the air-conditioning and pressurisation system
could not be excluded as the cause of the loss of cabin pressure.

Response to the emergency
Flight crew actions

4.5.1.

Pilots and cabin crew must memorise and frequently practise emergency procedures so that
they react promptly and correctly. In particular, crew members must not delay putting on
oxygen masks as soon as there is a clear indication of a loss of cabin pressure.

4.5.2.

The pilot in command may take whatever action is necessary under the circumstances to
ensure the safety of everyone on board. That authority extends to varying an emergency
checklist if conditions require it. However, an unnecessary deviation from the published
emergency procedures is a safety issue if it is done without knowing why the step was in the
checklist or the potential consequences of the variation.

4.5.3.

A loss of cabin pressure is one of the few in-flight conditions that require an immediate,
memorised response by pilots. The usual training for this event is a simulated rapid
decompression while at cruise altitude. Pilots frequently practise this exercise so the
memorised actions counter the surprise and workload of an actual emergency, which could
otherwise lead to their making errors. However, this incident differed from the practised
scenario because the loss of cabin pressure occurred when the aeroplane was already in a
normal descent. It was conceivable that the different circumstances interfered with the pilots’
recall and performance of the memorised actions.

The conclusion was not fully confirmed because other components had been changed after the incident and the
cabin pressure on the verification flight might not have been exactly the same as it had been on the incident flight.
18 A constant or steady fault condition is sometimes said to be ‘latched’.
17

Final report AO-2013-008   Page 11

 4.5.4.

Both pilots fitted their oxygen masks immediately after they recognised the loss of cabin
pressure. However, their actions varied from the published procedures in the following areas:


no cabin announcement was made to warn the cabin crew of the emergency descent



the flight deck ‘passenger oxygen’ switch was not selected on



the subsequent checklist reviews were not conducted out loud.

4.5.5.

The pilot flying said that he did not warn the cabin crew of the more rapid descent because the
aeroplane was already descending and he had heard the automatic passenger announcement
to fit oxygen masks. He concluded that the cabin crew would have realised it was a real
emergency. Although the operator concurred with that reasoning, the cabin crew would have
had no doubt if the pilot had made the required announcement.

4.5.6.

The pilot monitoring said he did not turn on the passenger oxygen switch because the light
associated with the switch was already illuminated and the automatic passenger
announcement was playing, both of which indicated that the masks had deployed. However,
there is some risk involved when pilots make their own decisions as to the necessity of a step
in an emergency checklist. Oxygen is not generated until a deployed mask is pulled down, so
not selecting the flight deck switch did not prevent the supply of oxygen. However, Boeing
advised that the flight deck switch is a back-up to the cabin pressure switch that signals the
masks to deploy, and it should therefore be selected on. The operator passed that advice to
its pilots.

4.5.7.

When reviewing the emergency checklists, the pilot monitoring did not read the steps out aloud
as the operator’s procedures required, although the pilot flying was aware the review was
taking place. A different crew made the same omission during a simulator review of the
incident conducted for the investigation. The verbal review of a checklist is an important part
of the emergency procedures because it is a cross-check that the correct actions have been
performed completely. It gives pilots a shared understanding of the situation and any factors to
be considered for the rest of the flight.

4.5.8.

In this case the deviations were of a minor nature and did not affect the safe outcome.
Nevertheless, the operator has, during annual training programmes for pilots, emphasised the
importance of adhering to published checklists.

4.5.9.

One of the pre-flight tasks of the pilot sitting in the right seat was to set the planned cruise
altitude in the pressure control panel. In this case the pilots left the selected altitude for the
flight to Auckland at 36,000 ft, which it had been on the flight to Wellington, and did not reset
it to 37,000 ft. The right-seat pilot, who usually flew as a captain from the left seat, had met
the operator’s minimum requirements for recent flying in the aeroplane from the right seat.
The minor error in setting the cruise altitude could have been made by any pilot who regularly
sat in the right seat. However, the operator’s investigation into the incident noted that the
error might “indicate a need for a more formalised currency program for pilots with
management and administrative responsibilities”.19

4.5.10. One of the pilots made a radio call to air traffic control to advise of the emergency descent. He
did not begin the message with the words, ‘PAN, PAN, PAN’, which are internationally
recognised to mean an aircraft faces an urgent situation. The Commission and other agencies
have previously noted the omission of the recognised words by pilots making radio calls to
advise of situations of urgency (or distress).20 In an earlier effort to improve pilot compliance
with this requirement the CAA had included education on urgency and distress calls in one of
its annual pilot education programmes.21 The operator used this incident in its 2014 recurrent

Air New Zealand Investigation Report 13/SI/16, p.21.
For example, Commission inquiries 06-009 (Boeing 767, ZK-NCK, engine fire, Auckland International Airport, 30
December 2006) and 10-003 (Cessna C208 Caravan ZK-TZR, engine fuel leak and forced landing, Nelson, 10
February 2010).
21 This programme, called ‘Plane Talking’, was the basis of the 2012 AvKiwi annual education series.
19
20

Page 12   Final report AO-2013-008

 training programme for pilots as an example of the importance of using urgency and distress
calls when appropriate.
4.5.11. In view of the improvements made by the operator to pilot training, the Commission made no
recommendation regarding any of the above issues.
Finding
3.

The pilots did not follow exactly the emergency checklist actions, which
increased the risk of an action being omitted or a required sequence of
actions being altered.

Response in the cabin
4.5.12. The crew members of any pressurised aircraft must be acutely aware of the hazard of a loss of
cabin pressure. The ‘time of useful consciousness’ remaining after pressurisation is lost or the
oxygen supply is interrupted illustrates the seriousness of the hazard (see Appendix 3). The
time available cannot be predicted accurately because it depends on the nature of the event
and an individual’s physiology and level of exertion at the time. If a rapid depressurisation
occurred at 25,000 ft, the time of useful consciousness could be as little as 90 seconds.
However, cognitive performance could be impaired more quickly, in which case the affected
person might be unable to recall or take the required actions. Therefore it is imperative that a
mask be fitted as soon as possible and remain fitted until the wearer is instructed that it may
be removed.
4.5.13. An incident in the United States in which a Boeing 737 lost cabin pressure as a result of a
structural failure provides an example of the hazard. One of the flight attendants, who thought
he could get a lot more done before having to put on a mask, lost consciousness and fell,
suffering a fractured nose.22 A passenger who was also not wearing a mask tried to help the
attendant and also lost consciousness. Both regained consciousness during the descent.
4.5.14. On the incident flight to Auckland there was no prior indication, such as a perceptible cabin air
pressure change or an announcement by a pilot, that the oxygen masks might deploy.
Nevertheless, all passengers followed the standard instructions for fitting masks that are given
before every flight. However, two cabin crew members delayed fitting masks. A delay in fitting
a mask might lead to cognitive impairment that could endanger the individual and others.
4.5.15. The senior flight attendant, FA1, did not know why she had not sat down in the nearest
available seat and fitted a mask, as the crew had been told to do. A possible reason was that
the limited range of training scenarios had not required her to actually sit down in a passenger
seat if necessary. She said that the green flow indicator was visible in the oxygen tubing and
she had not felt any lightheadedness.
4.5.16. Later inspection showed that the oxygen generator at that position had not been activated.
Therefore FA1 had not been supplied with oxygen. It was highly likely that she saw only the
edge of the flow indicator, which may be slightly visible even when there is no flow (see Figure
4). The operator’s training for cabin crew had not demonstrated how the indicator becomes
fully visible when oxygen is flowing. The operator has since revised its cabin crew training to
describe and demonstrate the oxygen system more accurately.

NTSB report DCA11MA039, Southwest Airlines, Flight 812, Boeing 737-3H4, N632SW, Yuma Arizona, 1 April
2011.
22

Final report AO-2013-008   Page 13

 Figure 4
Oxygen tubing, showing no flow (left) and full flow (right)
(Picture from the operator)

4.5.17. Tests by the operator showed that improper packing of the oxygen mask was the likely reason
for the generator at the front left door, where FA1 stood, failing to activate. Another test on a
different Boeing 737 found some improperly packed passenger oxygen masks. Even though
each row of seats had a spare mask, the improper packing or maintenance of equipment that
is critical to life support is a potential safety issue on all aeroplane types. The operator
reviewed the quality control of the maintenance of oxygen units across its fleets and deemed
no further action was necessary. Therefore the Commission made no recommendation on this
matter.23
4.5.18. When the cabin oxygen masks deployed FA2 continued to push the cart ‘uphill’ to the rear
galley. One possible reason for her doing this was the subconscious association of the crew
station with safety, because the cabin crew training demonstrations tended to occur at the
crew stations rather than in the cabin aisles. This extra effort would have required additional
oxygen and delayed her putting on a mask. The correct action would have been to apply the
cart brakes, fit the nearest spare mask and, if possible, take a seat and remain seated. Four
masks are available for each set of three passenger seats.
4.5.19. After the incident both of the rear galley oxygen units were found to have been activated. FA3,
who was already in the rear galley, fitted a mask from the unit at the right rear door and had no
concern for the oxygen flow. Therefore FA2 might have been mistaken (like FA1) in thinking
she was not getting oxygen. Both flight attendants received oxygen from the unit at the left
rear door.
Crew training and procedures
4.5.20. Crew members must be completely familiar with the emergency equipment installed for the
passengers’ and their own safety. FA1’s incorrect interpretation of the oxygen mask flow
indicator and FA2’s delay in putting on a mask suggested some unfamiliarity with the
equipment and the actions to be taken for a pressurisation incident, which indicated a need to
improve the cabin crew training programme and resources.
4.5.21. The operator submitted that depressurisation and the associated procedures and equipment
were covered in detail during initial and recurrent training for crews. The training involved
lectures, videos and practical exercises. However, the operator also submitted that the
observed cabin crew procedural non-conformances might have been due to the artificiality of
the training scenarios. To reduce the potential for lapses like those seen in this incident, the
operator instituted monthly crew briefing questions and assessments of individual competency
in the depressurisation drills during the annual line checks.
4.5.22. In view of the improvements made by the operator to cabin crew training, the Commission
made no recommendation regarding any of the above issues.

23

Air New Zealand subsequently disposed of its Boeing 737 fleet in 2014.

Page 14   Final report AO-2013-008

 4.5.23. The cabin crew responded appropriately to the toilet smoke alarms by treating them as
genuine alarms. They were unable to silence the alarms in the normal way. Cabin crew are
informed during their training that false smoke alarms can occur, but it was not generally
known that a spike in the cabin pressure could cause a false alarm.
Finding
4. The actions of some of the cabin crew during the incident showed that their
emergency training had not sufficiently stressed the importance of sitting
down and fitting a mask without delay, and had not allowed for a range of
scenarios or adequately familiarised the crew with the oxygen equipment.
4.6.

Cabin Altitude Warning checklist

4.6.1.

Normally, when the pressurisation system is in automatic mode, the outflow valve opens upon
landing to depressurise the cabin fully. After pilots have carried out the Cabin Altitude Warning
checklist the pressurisation system will be in the manual mode. Unless the pilots open the
outflow valve while in manual mode, the valve will remain closed on landing.

4.6.2.

The Boeing manuals did not explain that the system configuration after performing the Cabin
Altitude Warning checklist could allow the cabin to re-pressurise. The cabin doors were ‘plug’type doors that moved inwards slightly before opening outwards. If there is any significant
cabin pressure, a door cannot be physically opened. Therefore if the cabin is not fully
depressurised on the ground, the doors will be difficult or impossible to open, and this would
hinder an emergency evacuation if that were needed.24 In this case the aeroplane was slightly
pressurised after landing and the crew were initially unable to open the cabin door after the
engine shutdown.

4.6.3.

The operator said that the re-pressurisation scenario had not been anticipated before this
incident, and therefore its Boeing 737 pilots had not been trained for it. The Cabin Altitude
Warning checklist did not require pilots to ensure that the aeroplane was depressurised before
landing. In contrast, the checklist for another condition for which manual mode is selected,
‘Unscheduled Pressurization Change’, had a ‘Deferred Item’ that called for the aft outflow
valve to be opened manually before landing.25

4.6.4.

Boeing later advised that it had added the Deferred Items of the ‘Unscheduled Pressurization
Change’ checklist to the Cabin Altitude Warning checklist, to direct pilots controlling the
aeroplane pressure manually to open the outflow valve upon landing. For this reason the
Commission did not make a recommendation regarding the checklist content.

For this reason the Ground Evacuation checklist requires pilots to open the aft outflow valve fully manually
before giving the ‘Evacuate’ command.
25 A deferred item was an emergency checklist action that was performed at a later stage, typically during a routine
checklist. In the example cited, the outflow valve would be opened manually prior to the usual Landing checklist.
24

Final report AO-2013-008   Page 15

 5.

Findings

5.1

The cause of the loss of cabin pressure was not determined.

5.2

An intermittent defect within the air-conditioning and pressurisation system could not be
excluded as the cause of the loss of cabin pressure.

5.3

The pilots did not follow exactly the emergency checklist actions, which increased the risk of
an action being omitted or a required sequence of actions being altered.

5.4

The actions of some of the cabin crew during the incident showed that their emergency
training had not sufficiently stressed the importance of sitting down and fitting a mask
without delay, and had not allowed for a range of scenarios or adequately familiarised the
crew with the oxygen equipment.

Page 16   Final report AO-2013-008

 6.

Safety actions

6.1.

General

6.1.1.

The Commission classifies safety actions by two types:
(a)

safety actions taken by the regulator or an operator to address safety issues identified
by the Commission during an inquiry that would otherwise result in the Commission
issuing a recommendation

(b)

safety actions taken by the regulator or an operator to address other safety issues that
would not normally result in the Commission issuing a recommendation.

6.2.

Safety actions addressing safety issues identified during an inquiry

6.2.1.

The operator took action to improve crew performance in the following areas:

6.2.2.



the declaration by pilots of an emergency (distress or urgency) situation



flight crew adherence to the published emergency checklists



cabin crew actions in response to a depressurisation.

The operator took action to improve the following aspects of training:


6.2.3.

oxygen mask training with gas flow, and familiarity with chemical oxygen generators.

The operator reviewed the quality control of the packing of oxygen masks across its fleets and
deemed that no further action was necessary.

6.2.4.

On 2 June 2016 Boeing advised that it had added the Deferred Items of the ‘Unscheduled
Pressurization Change’ checklist to the Cabin Altitude Warning checklist, to direct pilots
controlling aeroplane pressure manually to open the outflow valve upon landing.

6.3.

Safety actions addressing other safety issues

6.3.1.

Nil.

Final report AO-2013-008   Page 17

 7.

Recommendations

7.1.

General

7.1.1.

The Commission may issue, or give notice of, recommendations to any person or organisation
that it considers the most appropriate to address the identified safety issues, depending on
whether these safety issues are applicable to a single operator only or to the wider transport
sector. In this case, because of the safety actions taken by the operator and the key lessons
identified, no recommendations have been issued.

Page 18   Final report AO-2013-008

 8.

Key lessons

8.1

The following lessons were identified during the inquiry into this occurrence:
 an unexpected loss of cabin pressure in any aeroplane is a serious event that can cause
both passengers and crew to lose consciousness rapidly from a lack of oxygen. In such an
event the appropriate emergency actions must be undertaken immediately. Where oxygen
masks are fitted, passengers and cabin crew must put on their masks and await further
instruction from the flight crew
 the purpose of emergency procedure checklists is to ensure that crew members do not
miss an important action at a critical time of high workload. Therefore, unless the captain
has an exceptional reason to deviate from a checklist, it should be performed from
beginning to end, if possible without interruption, and without omitting any step
 crew members must be thoroughly trained in and familiar with all emergency equipment
and procedures, because the equipment and procedures are for their own protection as
well as that of the passengers. They need to be alert for emergency situations that differ
from the standard scenarios that are practised and demonstrated repeatedly
 an aircraft door will be very difficult to open on the ground while the cabin is still
pressurised, and this can delay an evacuation if it is called for. When pilots have been
controlling the cabin pressure manually, they must ensure that the cabin is fully
depressurised to allow the doors to be opened
 special care must be taken with the maintenance of aircraft emergency equipment, such
as oxygen systems.

.

Final report AO-2013-008   Page 19

 9

Citations

FAA. (2013). Advisory Circular 61-107B, Aircraft operations at altitudes above 25,000 feet mean sea
level or Mach numbers greater than .75. Washington, D.C.: Federal Aviation Administration.

Page 20   Final report AO-2013-008

 Appendix 1: Boeing 737-300 technical information
Pressurisation system
1.

Bleed air for the cabin air conditioning and pressurisation is supplied from the fifth or ninth
compressor stage of the engines (see Figure 3).26 The pressure at the fifth stage is adequate
except when the engine is at idle or a low thrust setting, in which case the ninth (‘high’) stage
valve automatically opens to supply the air. The pressure of the bleed air from each engine is
indicated on the flight deck overhead panel. If the bleed air temperature or pressure is
excessive, a shut-off valve closes and this is indicated to the pilots.

2.

Aeroplane pressurisation control includes the pressurisation control system, pressure relief
valves and the indication and warning system. The pressurisation control system is electrically
operated and electronically controlled, and comprises a control panel, two digital pressure
controllers and the aft outflow valve (see Figure 5).

3.

The forward outflow valve shown in Figure 5 is part of the cargo heating system, but the
pressure control panel (in automatic or manual mode) signals the valve to close when the aft
outflow valve is almost fully closed. This prevents the forward outflow valve adversely
affecting the cabin pressure.

4.

The pressure control panel, located on the flight deck overhead panel, allows the pilots to
select the system mode, enter the flight and landing altitudes, and control the aft outflow
valve manually (see Figure 6). System status annunciators27, including the cabin altitude
warning, are located on the forward and overhead instrument panels. Adjacent to the
pressure control panel are a combined cabin altitude and differential pressure gauge and a
cabin rate-of-climb gauge.

5.

The pressurisation control system has three modes of operation, selected on the control
panel:


automatic (AUTO) – the normal mode. This requires only that the pilots enter the flight
and landing altitudes into the control panel before take-off, and have the correct
barometric pressure set for landing



alternate – a redundant automatic mode. This mode takes over if the AUTO mode fails



manual – for when the AUTO and alternate modes fail. The position of the aft outflow
valve is controlled directly by the pilots using a switch on the control panel.

Figure 5
Boeing 737 pressurisation system components
(Source: Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company)

26
27

The technical information is from the Boeing 737-300/400/500 airplane maintenance manual (revision 77).
An annunciator is a light that provides information on the state of a system or component.
Final report AO-2013-008   Page 21

 Figure 6
Boeing 737-300 pressurisation system control panel
(Source: Boeing Airliner magazine, Oct-Dec 1994)

6.

Two identical digital pressure controllers located in the underfloor equipment compartment
sense the cabin pressure. Interfaces with other aeroplane systems enable the controllers to
determine the flight phase. When the system is in automatic mode, one controller is operating
and in command of the outflow valve position. The other is on standby, but monitoring the
system and mimicking the controller in command. The pressure controllers determine the
lowest possible cabin altitude that can be maintained during the flight and create a
corresponding schedule of pressure change. The operative controller sends signals to the aft
outflow valve to adjust its exhaust area to maintain the schedule.

7.

The pressure controllers also limit the rate of change of cabin pressure when climbing and
descending, and limit the differential pressure.28 If the pressure controller’s internal limit for
differential pressure is exceeded, one or both independent safety relief valves open and
prevent the differential exceeding 8.5 psi.29 The safety relief valves close when the differential
pressure returns to the allowable range. A negative relief valve is also installed to prevent the
atmospheric pressure exceeding the cabin pressure.

8.

If the cabin altitude exceeds 10,000 ft, an aural warning sounds in the flight deck and a red
CABIN ALT (altitude) annunciator illuminates on the forward instrument panel. If the system is
in automatic mode, separate pressure sensors on the electric actuators of the aft outflow
valve command the valve to close when the cabin altitude exceeds 14,500 ft.

9.

When the pressurisation system is in automatic mode, the aft outflow valve is commanded to
open after landing so that the cabin pressure equalises with that outside.

Differential pressure is the difference between the cabin pressure and the outside air pressure. When the
cabin is pressurised, the differential pressure is positive. Excessive differential pressure can lead to structural
damage.
29 The maximum differential pressure for flights above 28,000 ft is 7.8 psi. At lower altitudes it is 7.45 psi.
28

Page 22   Final report AO-2013-008

 Oxygen system
10.

Supplemental gaseous oxygen is provided for the pilots.

11.

A unit above each row of three seats contains one chemical oxygen generator and four masks.
Above each set of cabin crew seats and in each toilet there is one generator with two masks.
All units open automatically and deploy the masks if an altitude sensor that is independent of
the pressurisation system detects the cabin altitude to be above 14,000 ft, or if the passenger
oxygen switch on the flight deck is selected on.

12.

Deployed oxygen masks hang approximately 18 centimetres below the service units and each
must be pulled down to reach the face of a sitting person. Pulling down any mask releases a
safety pin from the associated generator and starts the chemical reaction to produce oxygen.
Unwanted reaction products are filtered from the gas that flows to all of the attached masks.
When oxygen is flowing a green indicator should be clearly visible in the transparent supply
tubing.

13.

The operator’s Cabin Safety Manual noted that the chemical reaction produced significant
local heat and a ‘hot’ smell. A heat-sensitive tape on the casing of each generator discolours
if the generator has activated.
Toilet smoke alarms

14.

The toilet smoke detectors were of the ionising type in which a weak radioactive source
ionises the air and produces a small electrical current. Smoke particles entering the detector
interrupt the current, which sets off the alarm.

15.

Newer models of the Boeing 737 use photo-electric detectors that are not affected by
pressure spikes, and are better suited to detecting a smouldering fire, which is more typical of
a toilet fire.
Post-incident fault finding

16.

The manufacturer of the digital pressure controllers (Nord-Micro, in Germany) retrieved the
data stored in the controllers. The controllers had no internal faults and had operated
correctly in automatic mode. Approximately 90 seconds prior to the cabin altitude warning,
when the aeroplane was descending through 34,000 ft, the pressure controller that was in
control recorded an ‘inflow/leakage fail’ status. That meant that there was a low inflow of air
or an excessive air leakage, or perhaps both conditions. The controller correctly signalled the
outflow valve to close to stop any further decrease in the cabin pressure. The cabin altitude
exceeded 14,300 ft when the aeroplane was descending through 26,700 ft flight altitude, but
the maximum cabin altitude (which would allow the minimum cabin pressure to be
determined) was not recorded.

17.

The following fault finding was accomplished for the Commission’s inquiry or by the operator:

30



satisfactory tests of both pressure controllers before their removal from the aeroplane



replacement of both pressure controllers



analysis of data stored in the removed pressure controllers



visual inspection of the fuselage, wheel wells, cargo compartments, bulkheads and all
openings, for structural defects



a worn cabin entry door seal was replaced as a precaution



downloads of the cockpit voice recorder, digital flight recorder and quick-access
recorder



satisfactory check of pitot-static plumbing30



check of relevant electrical wiring

The pitot-static system involves dynamic and static air pressures, which are inputs to the pressure controllers.
Final report AO-2013-008   Page 23

 

replacement of the flight deck pressurisation system control panel



replacement of the aft and forward outflow valves



replacement of the two safety relief valves



examination of the removed safety relief valves and the aft outflow valve by their
manufacturers



satisfactory check of the engines’ bleed air output pressure



satisfactory check of the packs’ output



satisfactory ‘leak-down’ check of fuselage pressure retention



a review of the maintenance history for this aeroplane and the operator’s Boeing 737
fleet



additional checks and component replacements as suggested by Boeing



inspection of the packing and function of passenger and crew oxygen masks, and
replacement of the oxygen generators



satisfactory verification flight prior to release to service.

Page 24   Final report AO-2013-008

 Appendix 2: Boeing 737 emergency checklists

Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company

Final report AO-2013-008   Page 25

 Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company

Page 26   Final report AO-2013-008

 Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company

Final report AO-2013-008   Page 27

 Boeing Proprietary Information. Copyright © Boeing. Reprinted with permission of the Boeing Company

Page 28   Final report AO-2013-008

 Appendix 3: Time of useful consciousness
Time of useful consciousness (TUC)
This is the period of time from interruption of the oxygen supply, or exposure to an oxygen-poor
environment, to the time when an individual is no longer capable of taking proper corrective and
protective action.31 The faster the rate of ascent, the worse the impairment and the faster it happens.
TUC also decreases with increasing altitude. The table below shows the trend of TUC as a function of
altitude. However, a slow depressurisation is as dangerous as or more dangerous than a rapid
depressurisation. By its nature, a rapid depressurisation commands attention. In contrast, a slow
depressurisation may go unnoticed and the resultant hypoxia32 may be unrecognised.

WARNING:
The TUC does not mean the onset of unconsciousness.
Impaired performance may be immediate.
Prompt use of oxygen is critical.
TIMES OF USEFUL CONSCIOUSNESS VERSUS ALTITUDE

Altitude (ft)
18,000
22,000
25,000
28,000
30,000
35,000
40,000

TUC
20-30 min
10 min
3-5 min
2.5-3 min
1-2 min
30 sec-1 min
15-20 sec

Following rapid depressurisation
10-15 min
5-6 min
1.5-2.5 min
1-1.5 min
30 sec-1 min
15-30 sec
Nominal

This appendix is sourced from the Federal Aviation Administration Advisory Circular 61-107B, Aircraft operations
at altitudes above 25,000 feet mean sea level or Mach numbers greater than .75, 29 March 2013. The circular
uses the similar term ‘decompression’ rather than depressurisation.
32 Hypoxia is a condition of inadequate oxygen saturation in the blood and tissues.
31

Final report AO-2013-008   Page 29

 Recent Aviation Occurrence Reports published by
the Transport Accident Investigation Commission
(most recent at top of list)
AO-2013-003

Robinson R66, ZK-IHU, Mast bump and in-flight break-up, Kaweka Range,
9 March 2013

AO-2014-002

Kawasaki BK117 B-2, ZK-HJC, Double engine power loss, Near Springston,
Canterbury, 5 May 2014

AO-2013-006

Misaligned take-off at night, Airbus A340, CC-CQF, Auckland Airport, 18 May 2013

AO-2010-009

Addendum to Final Report: Walter Fletcher FU24, ZK-EUF, loss of control on take-off
and impact with terrain, Fox Glacier aerodrome, South Westland, 4 September 2010

AO-2012-002

Airbus A320 ZK-OJQ, Bird strike and subsequent engine failure, Wellington and
Auckland International Airports, 20 June 2012

AO-2013-005

In-flight loss of control, Robinson R22, ZK-HIE, near New Plymouth, 30 March 2013

AO-2013-007

Boeing 737-838, ZK-ZQG, stabiliser trim mechanism damage, 7 June 2013

AO-2013-009

RNZAF Boeing 757, NZ7571, landing below published minima, Pegasus Field,
Antarctica, 7 October 2013

AO-2013-002

Robinson R44, ZK-HAD, engine power loss and ditching, Lake Rotorua,
24 February 2013

11-007

Descent below instrument approach minima, Christchurch International Airport, 29
October 2011

11-006

Britten-Norman BN.2A Mk.III-2, ZK-LGF, runway excursion, Pauanui Beach
Aerodrome, 22 October 2011

11-003

In-flight break-up ZK-HMU, Robinson R22, near Mount Aspiring, 27 April 2011

12-001

Hot-air balloon collision with power lines, and in-flight fire, near Carterton,
7 January 2012

11-004

Piper PA31-350 Navajo Chieftain, ZK-MYS, landing without nose landing gear
extended, Nelson Aerodrome, 11 May 2011

11-005

Engine compressor surges, 18 September 2011

11-001

Bell Helicopter Textron 206L-3, ZK-ISF, Ditching after engine power decrease, Bream
Bay, Northland, 20 January 2011

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