CASA B2-13b Aircraft Structures PDF

Summary

This document is a student resource on aircraft structures, covering definitions, study resources, and introduction to airframe structures. It has information on various aircraft types and topics related to aircraft structures.

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Student Resource

Subject B2-13b:
Aircraft Structures

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 Copyright © 2017 Aviation Australia
All rights reserved. No part of this document may be reproduced, transferred, sold, or otherwise
disposed of, without the written permission of Aviation Australia
CONTROLLED DOCUMENT

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CONTENTS

Definitions 2
Study Resources 3
Introduction 5
Topic 13.2.1: Airframe Structures – General Concepts 5

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DEFINITIONS
Define
To describe the nature or basic qualities of.
To state the precise meaning of (a word or sense of a word).

State
Specify in words or writing.
To set forth in words; declare.

Identify
To establish the identity of.

List
Itemise.

Describe
Represent in words enabling hearer or reader to form an idea of an object or process.
To tell the facts, details, or particulars of something verbally or in writing.

Explain
Make known in detail.
Offer reason for cause and effect.

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STUDY RESOURCES
Jeppesen A&P Technicians General Textbook
Jeppesen A&P Technicians Airframe Textbook
Jeppesen A&P Technicians Powerplant Text book
Cessna 100 Series Airplane AMM
Boeing 737NG AMM
Boeing 747-400 AMM
Boeing 727 AMM
Fokker F28 AMM
Piper PA31 AMM
AC-43
FAR 25 (FAA USA
B2-13b Student Resource

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INTRODUCTION
The purpose of this subject is to familiarise you with the basic construction, requirements and maintenance
of aircraft structures.

On completion of the following topics you will be able to:

Topic 13.2 Airframe Structures – General Concepts
Identify airworthiness requirements for structural strength.
Identify inspection programs associated with ageing aircraft.
Identify primary, secondary and tertiary structural classifications.
Identify fail safe, safe life and damage tolerance concepts.
Describe zonal and station identification systems.
Identify the following concepts with regards to airframe structures:
Stress, strain, bending, compression, shear, torsion, tension, hoop stress and fatigue.
Identify drain and ventilation provisions used in airframe structures.
Identify provisions used in aircraft for system installations.
Describe provisions for lightning protection.
Describe aircraft electrical bonding concepts.

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TOPIC 13.2 AIRFRAME Structures – General CONCEPTS
TABLE OF CONTENTS
TABLE OF FIGURES............................................................................................................................ 3
Topic 13.2 Airframe Structures – General Concepts Part a................................................................. 5
Airworthiness requirements............................................................................................................ 5
Transport Category Aircraft.............................................................................................................. 6
FAR 25.301 Loads............................................................................................................................. 6
FAR 25.303 Factor of Safety............................................................................................................. 7
FAR 25.305 Strength and Deformation............................................................................................ 7
FAR 25.307 Proof of Structure......................................................................................................... 8
Structural classifications................................................................................................................... 9
Primary Structure.......................................................................................................................... 9
Secondary Structure..................................................................................................................... 9
Tertiary Structure........................................................................................................................ 10
Structural Design Requirement...................................................................................................... 10
Static Strength............................................................................................................................ 11
Fatigue Design Philosophy.......................................................................................................... 11
Safe Life....................................................................................................................................... 13
Safe Life Disadvantages.............................................................................................................. 13
Fail Safe....................................................................................................................................... 13
Fail Safe Disadvantages.............................................................................................................. 14
Damage Tolerance...................................................................................................................... 14
Durability.................................................................................................................................... 15
Ageing Aircraft Inspection Requirements................................................................................... 16
Task 5 – 14 CFR/JAR 25 Ageing Aircraft.......................................................................................... 16
Background................................................................................................................................. 16
Zonal and Station Identification Systems....................................................................................... 19
Aircraft Reference Zones............................................................................................................ 19
Major Zone.................................................................................................................................. 19
Sub Zone..................................................................................................................................... 20
Zone............................................................................................................................................ 20
Reference Datum........................................................................................................................ 20
Body Station Line (BS)................................................................................................................. 22
Buttock Line (BL)......................................................................................................................... 22

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 Water Line (WL).......................................................................................................................... 23
Wing............................................................................................................................................... 23
Wing Buttock Line (WBL)............................................................................................................ 23
Engine......................................................................................................................................... 24
Clock Position.............................................................................................................................. 25
Stress.............................................................................................................................................. 25
Strain.............................................................................................................................................. 26
Stress-Strain Curves.................................................................................................................... 26
Tension........................................................................................................................................... 27
Compression............................................................................................................................... 28
Shear........................................................................................................................................... 28
Torsion........................................................................................................................................ 29
Bending....................................................................................................................................... 30
Hoop Stress................................................................................................................................. 31
Fatigue............................................................................................................................................ 31
Aircraft Drainage............................................................................................................................ 32
Drainage...................................................................................................................................... 33
Pressurised Fuselage Drain Valve............................................................................................... 33
Drain Hole................................................................................................................................... 34
Ventilation...................................................................................................................................... 34
System Installation Provisions.................................................................................................... 35
Hydraulic Systems....................................................................................................................... 35
Air Conditioning System............................................................................................................. 35
Electrical/Avionics....................................................................................................................... 35
Fuel Storage................................................................................................................................ 36
Main Landing Gear (MLG).............................................................................................................. 36
Waste Disposal........................................................................................................................... 37
Potable Water............................................................................................................................. 38
Auxiliary Power Unit (APU)............................................................................................................. 38
Lightning Strikes.......................................................................................................................... 39
Aircraft Electrical Bonding.............................................................................................................. 41
Bonding....................................................................................................................................... 41
Grounding................................................................................................................................... 41
Bonding Leads............................................................................................................................. 41

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TABLE OF FIGURES
Figure 1: Regulatory Authorities.......................................................................................................... 5
Figure 2: Transport Category Aircraft.................................................................................................. 6
Figure 3: Load Analysis......................................................................................................................... 7
Figure 4: Fuselage Pressure Testing – B787......................................................................................... 8
Figure 5: Proving Structural Analysis - B787 Wing............................................................................... 9
Figure 6: Structural Classification...................................................................................................... 10
Figure 7: Static Strength Testing – B787............................................................................................ 11
Figure 8: Fatigue Testing.................................................................................................................... 12
Figure 9: Fatigue Design History........................................................................................................ 12
Figure 10: Fail Safe Design - Multi Spar Structure............................................................................. 13
Figure 11: Damage Tolerance Inspection Regime............................................................................. 14
Figure 12: Non Destructive Testing.................................................................................................... 15
Figure 13: Aircraft Durability.............................................................................................................. 15
Figure 14: Major Zones...................................................................................................................... 19
Figure 15 Sub Zones........................................................................................................................... 20
Figure 16: Reference Datum.............................................................................................................. 21
Figure 17: B737NG Datum Line.......................................................................................................... 21
Figure 18: Fuselage Station Lines....................................................................................................... 22
Figure 19: Buttock and Water Lines................................................................................................... 23
Figure 20: Wing Buttock Lines........................................................................................................... 24
Figure 21: Engine Station Lines.......................................................................................................... 24
Figure 22: Clock Position.................................................................................................................... 25
Figure 23: Stress-Strain Curves.......................................................................................................... 26
Figure 24: Compression Stresses....................................................................................................... 28
Figure 25: Rivets Under Shear Loads................................................................................................. 29
Figure 26: Torsional Stress on a Fuselage.......................................................................................... 29
Figure 27: Bending Force on a Fuselage............................................................................................ 30
Figure 28: Bending Force on Wings................................................................................................... 30
Figure 29: Hoop Stress to Fuselage.................................................................................................... 31
Figure 30: Fatigue Damage................................................................................................................ 32
Figure 31: Pressurised Fuselage Drain Valve..................................................................................... 33
Figure 32: Drain Hole......................................................................................................................... 34

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Figure 33: Ventilation......................................................................................................................... 34
Figure 34: Fuel Tank System.............................................................................................................. 36
Figure 35: Main Landing Gear Fittings............................................................................................... 36
Figure 36: A Waste Water Drain System............................................................................................ 37
Figure 37: Potable Water System...................................................................................................... 38
Figure 38: Lightning Strike on B747................................................................................................... 39
Figure 39: Bonding Strap attached to flight control.......................................................................... 39
Figure 40: Radome lightning diverter strips (F28)............................................................................. 40
Figure 41: Static Discharge Wicks...................................................................................................... 40
Figure 42: Radome Bonding Straps (F28)........................................................................................... 41

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TOPIC 13.2 AIRFRAME STRUCTURES – GENERAL CONCEPTS PART A
Airworthiness requirements
An aircraft is airworthy only when it conforms to the regulations under which it has been certified.
Regulatory authorities work closely on setting uniform requirements. Airworthiness standards are
organised into sections, called parts, and each part deals with a specific type of activity. As an
example:
Part 23 covers airworthiness standards for Normal, Utility, Acrobatic and Commuter
Aircraft
Part 25 covers airworthiness standards for Transport Category Aircraft
Part 27 covers airworthiness standards for Normal Category Rotorcraft
Part 29 covers airworthiness standards for Transport Category Rotorcraft
Part 33 covers airworthiness standards for Aircraft Engines
Part 35 covers airworthiness standards for Propellers
Part 39 covers Airworthiness Directives
Part 43 covers Maintenance, Preventive Maintenance, Rebuilding and Alteration
Part 65 (Part 66 for EASA and CASA) covers Aircraft Maintenance Engineer Licensing
Part 145 covers Aircraft Maintenance Organisations
Part 147 covers Aviation Maintenance Technicians Schools

Figure 1: Regulatory Authorities

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Transport Category Aircraft
An aircraft registered in the transport category requires that its structure meets the airworthiness
standards specified in the following regulations as applicable for the country in which the aircraft
is registered:
CASR 1998 Part 25 Subpart 25, as of the 1st Edition - January 2003 for Australia
EASA Certification Specifications CS-25 Subpart C, as of the Amendment 6 - July 2009
for Europe
FAR Part 25 Subpart C, as of the e-CFR Data – August 2009 for the USA, covers four
sections relating to the aircraft’s structure:
– 25.301 Loads
– 25.303 Factor of Safety
– 25.305 Strength and Deformation
– 25.307 Proof of Structure
The content of these four sections is repeated below.

Figure 2: Transport Category Aircraft

FAR 25.301 Loads
(a) Strength requirements are specified in terms of limit loads (the maximum loads to be expected
in service) and ultimate loads (limit loads multiplied by prescribed factors of safety). Unless
otherwise provided, prescribed loads are limit loads.
The limit load is the maximum anticipated load or combination of loads, which a structure may be
expected to experience. Ultimate load is the maximum load which a structure is designed to
withstand without failure.
(b) Unless otherwise provided, the specified air, ground, and water loads must be placed in
equilibrium with inertia forces, considering each item of mass in the aeroplane. These loads must
be distributed to conservatively approximate or closely represent actual conditions.

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Methods used to determine load intensities and distribution must be validated by flight load
measurement unless the methods used for determining those loading conditions are shown to be
reliable.
(c) If deflections under load would significantly change the distribution of external or internal
loads, this redistribution must be taken into account.

Figure 3: Load Analysis

FAR 25.303 Factor of Safety
Unless otherwise specified, a factor of safety of 1.5 must be applied to the prescribed limit load
which is considered external loads on the structure. When loading condition is prescribed in terms
of ultimate loads, a factor of safety need not be applied unless otherwise specified.
FAR 25.305 Strength and Deformation
(a) The aircraft structure must be able to support limit loads without detrimental permanent
deformation. At any load up to limit loads, the deformation may not interfere with safe operation.
(b) The structure must be able to support ultimate loads without failure for at least 3 seconds.
However, when proof of strength is shown by dynamic tests simulating actual load conditions, the
3-second limit does not apply. Static tests conducted to ultimate load must include the ultimate
deflections and ultimate deformation induced by the loading. When analytical methods are used
to show compliance with the ultimate load strength requirements, it must be shown that:
The effects of deformation are not significant
The deformations involved are fully accounted for in the analysis, or
The methods and assumptions used are sufficient to cover the effects of these deformations

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(c) Where structural flexibility is such that any rate of load application likely to occur in the
operating conditions might produce transient stresses appreciably higher than those
corresponding to static loads, the effects of this rate of application must be considered.
(d) Reserved
(e) The aircraft must be designed to withstand any vibration and buffeting that might occur in any
likely operating condition up to Vd/Md, (design dive speed), including stall and probable
inadvertent excursions beyond the boundaries of the buffet onset envelope. This must be shown
by analysis, flight tests, or other tests found necessary by the Administrator.
(f) Unless shown to be extremely improbable, the aircraft must be designed to withstand any
forced structural vibration resulting from any failure, malfunction or adverse condition in the flight
control system. These must be considered limit loads and must be investigated at airspeeds up to
Vc/Mc, (design cruise speed).

Figure 4: Fuselage Pressure Testing – B787

FAR 25.307 Proof of Structure
(a) Compliance with the strength and deformation of this subpart must be shown for each critical
loading condition. Structural analysis may be used only if the structure conforms to that for which
experience has shown this method to be reliable. The Administrator may require ultimate load
tests in cases where limit load tests may be inadequate.
(b), (c) Reserved.

(d) When static or dynamic tests are used to show compliance with the requirements of 25.305(b)
for flight structures, appropriate material correction factors must be applied to the test results,
unless the structure, or part thereof, being tested has features such that a number of elements
contribute to the total strength of the structure and the failure of one element results in the
redistribution of the load through alternate load paths.

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 Figure 5: Proving Structural Analysis - B787 Wing

Structural classifications
Aircraft structures and components are classified according to their level of importance for the
part they play in maintaining the structural integrity of the aircraft. This classification determines
the significantly different levels of intensity and frequency of inspection and maintenance
schedules, component replacement, damage assessment and repair schemes. The classifications
are:
Primary structure
Secondary structure
Tertiary structure
Primary Structure
Primary structure is that structure that is critical to the safety of the aircraft.
Should a primary structural component fail, during take-off, during flight, or during landing, there
is potential for structural collapse, or loss of control, or failure of motive power, or fatality, or
serious injury to aircrew.
Secondary Structure

Secondary structure refers to structure that, if it were to fail, may cause significant damage that
would affect the operation of the aircraft, but not lead to its loss.

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 Figure 6: Structural Classification

Tertiary Structure
Tertiary structure refers to structure that, if it were to fail, would not significantly affect the
operation of the aircraft.
Structural Design Requirement
The structural design criteria are determined by the type of aircraft and its intended use. From
this it is possible to define the structural design analysis to consider the types of manoeuvres,
speeds, useful loads and gross weights the structure will be subject to. In addition the criteria must
consider such items as inadvertent manoeuvres, effects of turbulent air, and severity of ground
contact during landing.
The strength provided in the airframe structure to meet these conditions must be adequate for
the aircraft to perform its intended mission in a safe and profitable manner as operated by
qualified personnel under regulated conditions.
Certification of airframe structure generally requires that the structure be subject to testing
and/or analysis to demonstrate the following capabilities:
Static strength
Fatigue strength

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Static Strength
The Design Limit Load (DLL) is the maximum load anticipated on the aircraft during its service life.
The aircraft structure shall be capable of supporting the limit loads without suffering detrimental
permanent deformation, and not interfere with the safe operation of the aircraft.
Design Ultimate Load (DUL) is equal to the design limit load multiplied by a factor of safety.
Generally the safety factor is 1.5.

Figure 7: Static Strength Testing – B787

Fatigue Design Philosophy
Fatigue considerations comprise an important part of aircraft structural design. The common
objective is to define aircraft life to ensure flight safety while at the same time minimising
maintenance and operating costs.
There are three distinct design approaches for protecting an aircraft structure from failure due to
fatigue damage:
Safe life – Also known as safety by retirement, was introduced in the 1940s after
fatigue was recognised as a failure mechanism. It specifies a safe lifespan within which
there is no significant risk of structural failure of a component
Fail-safe - The fail-safe design principle was introduced in the 1950s as an
improvement to safe-life. A fail-safe structure should be able to sustain the limit load
even when one of the elements has failed

Damage tolerance - Damage tolerance, or safety by inspection, was developed as a design
philosophy in the 1970s as an improvement on the fail-safe principle. Damage tolerance is the
present method of achieving structural operating safety.

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 Figure 8: Fatigue Testing

Although the objectives of three approaches are the same, they vary with regard to the
fundamental definition of service life.

Figure 9: Fatigue Design History

Note:
SSIP means Supplemental Structural Inspection Program. The establishment of a SSIP is
to reach the safety standard according to FAR 25.571 Amendment 45
MSG refers to Maintenance Steering Group and is the method that aircraft
manufacturers, operators and regulators use to develop the manufacturer’s initial
maintenance schedule, as part of the work towards aircraft certification. The process
continues throughout the aircraft type’s life. MSG-3 is the methodology that focuses
on aircraft systems and the loss of system function or functions

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Safe Life
Safe-life is an approach where a structure is designed to withstand a certain number of events
(flight cycles, landings, or flight hours) with a low probability that the strength of the structure will
degrade below its designed ultimate strength before the end of its approved life. The structural
component must remain crack free during service. This means the component must not develop
any cracks as a result of fatigue, corrosion, or accidental damage during its specified service life.
Once the service life of a component has been reached it is considered unserviceable and the
aircraft’s airworthiness can only be maintained if the component is replaced.
Safe Life Disadvantages
There are two major drawbacks to the safe life approach:
Components are taken out of service even though they may have substantial
remaining lives, creating unnecessary costs
Despite all precautions, cracks sometimes occur prematurely, creating a safety
problem
Fail Safe
Fail safe is an approach, applied to a structure, designed to retain its required residual strength for
a period of unrepaired use after a failure or partial failure of a principal structural element
To achieve this requirement, a fail-safe design uses backup structures and secondary load paths.
This principle relies on the fact that if the main load path fails, there is a secondary load path to
ensure the safety of the aircraft until the failure can be detected. For example; a multi spar
structure is a fail-safe structure – if one spar failed, the adjacent spar will support the load.

Figure 10: Fail Safe Design - Multi Spar Structure

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Fail Safe Disadvantages
Despite all precautions, cracks sometimes occur prematurely and may not be detected, creating a
safety problem. Fail safe methodologies do not consider material or manufacturing flaws.
Damage Tolerance
This approach can be applied to a structure that is able to sustain a given level of fatigue,
corrosion, manufacturing defects, or accidental damage, and still withstand design loads without
structural failure or excessive structural deformation for a predetermined period that allows for a
set number of opportunities to detect the damage.

Figure 11: Damage Tolerance Inspection Regime

The damage tolerance approach is based on the principle that while cracks due to fatigue and
corrosion will develop in the aircraft structure, the process can be understood and controlled.
A key element is the development of a comprehensive programme of inspections to detect cracks
before they can affect flight safety. That is, damage tolerant structures are designed to sustain
cracks without catastrophic failure until the damage is detected in scheduled inspections and the
damaged part is repaired or replaced.
In addition, damage tolerance takes into account initial material or manufacturing flaws by
assuming an initial crack, which the fail-safe principle does not do.
A damage tolerant design should allow cracks to be detected before they reach the critical length
that will lead to failure. To ensure that this occurs there should be at least two opportunities to
detect the crack prior to it reaching its critical length.

The damage tolerance philosophy uses testing and analysis to determine the critical crack length,
the residual strength, and the inspection intervals. Tests include flight testing to determine the
loads on the structure, and ground testing to determine the fatigue and crack growth
characteristics. From the testing and analysis, the critical sites and components susceptible to
fatigue can be determined. Fatigue analysis based on flight, ground, and pressurisation loads can
then be used to determine crack growth performance and residual strength.

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 Figure 12: Non Destructive Testing

The damage tolerance philosophy is used for transport category aircraft. For other categories of
aircraft, the damage tolerance method may be used but is not mandatory; the safe-life or fail-safe
methods may be used instead.
Durability
Durability is the ability of the structure to sustain degradation from such sources as fatigue,
accidental damage and environment deterioration, to the extent that they can be controlled by
economically acceptable maintenance and inspection programs.
Durability of an aircraft structure comes from having a slow crack growth characteristic and the
ability to contain or restrict the progress of damage.

Figure 13: Aircraft Durability

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Ageing Aircraft Inspection Requirements
The ageing aircraft program requires each transport aircraft to undergo a series of tests and
inspections after it has been in service for a specified number of years and/or has accumulated a
certain number of flight cycles. These inspections are generally a combination of visual and non-
destructive testing methods such as ultrasound, eddy current and x-rays. Corrosion control and
structural repairs are made when necessary. Since major disassembly of the aircraft is required to
complete the relevant inspections, rigging of the aircraft control system will be necessary.
The aged aircraft program must be part of the scheduled maintenance program conducted by an
approved Part 145 organisation.
Some manufacturers may require major structural disassembly after a certain number of flight
hours. For example, some Lear jet models require removal of the wing after approximately 5,000n
flight hours for a series of Inspections. The manufacturer of an aircraft may specify this type of
disassembly and inspection after a specific period of flight hours, flight cycles, months or years.
Task 5 – 14 CFR/JAR 25 Ageing Aircraft
Background
In 1988, the industry experienced a significant failure of the airworthiness system.
This system failure allowed an aeroplane to fly with significant unrepaired multiple site fatigue
damage to the point where the aeroplane experienced a rapid fracture and loss of a portion of the
fuselage. As a direct result of this accident, the FAA hosted The International Conference on
Ageing Aeroplanes on June 1-3, 1988 in Washington D. C. As a result of this conference, an
organisation of Operators, Manufacturers and Regulators was formed under the Federal Advisory
Committee Act to investigate and propose solutions to the problems evidenced as a result of the
accident. This group is now known as the Airworthiness Assurance Working Group (AAWG)
(Formally known as the Airworthiness Assurance Task Force).
During the 1988 conference, several Airline/Manufacturer recommendations were presented to
address the apparent short falls in the airworthiness system including Recommendation 3, which
stated:
"Continue to pursue the concept of teardown of the oldest airline aircraft to determine structural
condition, and conduct fatigue tests of older aeroplanes as per attached proposal"
In June 1989, the National Transportation Safety Board (NTSB) made Recommendation 89067 that
requested the FAA to pursue necessary tasks to ensure continued safe operations with probable
Widespread Fatigue Damage (WFD). WFD was noted by the NTSB to be a contributing cause of the
April 1988 Aloha Airlines 737 accident. The NTSB specifically recommended extended fatigue
testing for older aeroplanes. In November 1989, the FAA responded by issuing a ‘strawman’
Supplementary Federal Aviation Regulation (SFAR) RE: TWO-LIFE-TIME FATIGUE TEST FOR OLDER
AEROPLANES.
(The premise behind building a ‘strawman’ – creating a first draft for criticism and testing, and
then using the feedback you receive to develop a final outcome that is rock solid.)
In June 1990, the AAWG tasked the formal evaluation of the Aerospace Industries Association of
America International Air Transport Association (AIAIATA) Recommendation 3. An alternative
approach, to the strawman SFAR was developed by the AAWG and presented to the FAA in March
1991.

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The FAA accepted this alternative approach in June 1991. The AAWG was informally tasked to
institutionalize the position in July.
It is urged that any future publications on the subject of widespread fatigue damage should
include, or at least reference this standard terminology, in order to avoid possible confusion within
the industry.
Damage Tolerance is the attribute of the structure that permits it to retain its required residual
strength without detrimental structural deformation for a period of use after the structure has
sustained specific levels of fatigue, corrosion, accidental or discrete source damage.
Widespread Fatigue Damage (WFD) in a structure is characterized by the simultaneous presence
of cracks at multiple structural details that are of sufficient size and density whereby the structure
will no longer meet its damage tolerance requirement (i.e. to maintain its required residual
strength after partial structural failure).
Multiple Site Damage (MSD) is a source of widespread fatigue damage characterized by the
simultaneous presence of fatigue cracks in the same structural element (i.e. fatigue cracks that
may coalesce with or without other damage leading to a loss of required residual strength).
Multiple Element Damage (MED) is a source of widespread fatigue damage characterized by the
simultaneous presence of fatigue cracks in similar adjacent structural elements. In addition, the
AAWG proposes the adoption of the following terminology during discussion of programs to
ensure continuing structural integrity:
Fatigue Crack Initiation is that point in time when a finite fatigue crack is first expected.
Point of WFD is a point reduced from the average expected behaviour, i.e. lower bound, so that
operation up to that point provides equivalent protection to that of a two-lifetime fatigue test.
Monitoring Period is the period of time when special inspections of the fleet are initiated due to
an increased risk of MSD/MED, and ending when the point of WFD is established.
Design Service Goal (DSG) is the period of time (in flight cycles/hours) established at design
and/or certification during which:
1. The principal structure will be reasonably free from significant cracking
2. Widespread fatigue damage is not expected to occur.
Extended Service Goal (ESG) is an adjustment to the design service goal established by service
experience, analysis, and/or test during which:
1. The principal structure will be reasonably free from significant cracking
2. Widespread fatigue damage is not expected to occur.
Furthermore, certain terminology has been considered by past working groups in relation to the
problem of WFD, but was not used in the final ARAC definitions.
The following terms have been previously identified as being open to misinterpretation, and
should be avoided, or defined carefully if their use is essential.

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Threshold has been used in various contexts, such as:
Fatigue Threshold, which may be defined as the first typical fatigue crack in the fleet for
that element
Inspection Threshold, which may be defined as the start of supplemental inspections for
WFD
The AAWG believes that the real meaning of WFD in this context is MSD/MED.
Onset has been used as an alternative to Threshold, although the simultaneous use of both terms
may cause confusion.
Sub-Critical has been used in relation to certain fatigue cracks. However, this may require
clarification of what are critical fatigue cracks with reference to occurrence of WFD.
There are a number of general conditions and details that must be met in order that a monitoring
period concept can be used.
These conditions are:
No aeroplane may be operated beyond the defined Point of WFD without modification or
part replacement.
The first special inspections, to occur in the monitoring period, should be in line with the
estimation of fatigue crack initiation.
To use a monitoring period for a detail suspected of developing MSD/MED, it must be
determined that inspections will reliably detect a crack before the crack becomes
critical. If a crack cannot be reliably detected, a monitoring period cannot be used.
By empirical analysis, evaluation of test evidence and/or evaluation of in-service data, the
inspection requirements will be defined for application during the monitoring period.
The purpose of these inspections is to collect data for reassessment of WFD parameters
and to maintain structural integrity (e.g., acceptable level of risk during the monitoring
period). Inspections within the monitoring period are mandatory on every aeroplane
as well as reporting of inspection results.
In the case of MSD or MED findings, the Point of WFD will be re-established in accordance
to the inspection results. The area of concern will be repaired following a detailed
inspection of adjacent areas using NDI technology that will detect small cracks with a
high degree of confidence. The remaining aeroplanes may be operated up to the
revised Point of WFD, with application of a revised monitoring program. Prior to the
Point of WFD, the aeroplane must be repaired, modified, or retired.
If no MSD/MED cracking is detected by the time the high time aeroplane reaches the
predicted Point of WFD, the predicted Point of WFD could be re-evaluated and the
special inspection program may be continued after revalidation.
The monitoring period will terminate at the point in time at which there is sufficient
findings to confirm a MSD/MED problem exists and/or the Point of WFD is reached.
This will be recommended with the assistance of the STG using an established process.

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Zonal and Station Identification Systems
Aircraft Reference Zones
In order to facilitate maintenance and component location, an aircraft is divided into Major Zones.
Each zone is further broken down into Sub Zones and Zones. Different manufactures refer to the
term Major Sub-Zones instead of Sub Zones; however the identification principle is the same.
Each of the zones sequentially produces a three-digit identifier. The identifier is in a standard
format as defined by the ATA100 Specification.
Major Zone
The aircraft is divided into 8 major zones. Each zone is numbered from 100 to 800, with the left
hand digit from 1 to 8 and each followed by two zeros to create the three digit identifier.
For example, major zone 100 is the lower fuselage; major zone 200 is the upper fuselage; and
major zone 300 is the Empennage.

Figure 14: Major Zones

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Sub Zone
It is possible to have 9 sub zones in each major zone. A sub zone is identified by the middle digit of
the three digit identifier, using the numbers 1 to 9, and the right hand digit a zero.
For example, sub zone 820 refers to cargo compartment doors, sub zone 830 refers to the left side
passenger compartment doors, and sub zone 840 refers to the right side passenger doors.

Figure 15 Sub Zones

Zone
The third digit, comprising the numbers 1 to 9 identifies a component or group of components
that are in the subzone.
For example, zone 821 identifies the forward cargo door and zone 822 identifies the aft cargo
door.
Access doors and panels in a zone are identified by the zone number and a two or three letter
suffix. This alpha-numeric label is different for each access door or panel.
For example: 821 is the forward cargo door (RH side)
– 821AR is an access panel on the forward cargo door
– 821AZ is an access panel on the forward cargo door liner
Reference Datum
A reference datum or datum is established by the manufacturer for each aircraft model. The datum
is an imaginary vertical plane or line that sits at a right angle to the aircraft’s longitudinal axis.
The datum is the point from which all horizontal measurements are taken, with the aircraft in a
level flight attitude. The location of all items, including equipment, tanks, baggage compartments,
seats, engines, and propellers are listed as being so many inches from the datum.

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Information on the location of the datum is found in the Aircraft Specifications or Type Certificate
Data Sheets.

Figure 16: Reference Datum

There is no fixed rule for the location of a datum. It may be located on the nose of the aircraft, the
fire-wall, the leading edge of the wing, or even at a point in space ahead of the aircraft. The
manufacturer chooses a location for the datum where it is most convenient for measurement, the
location of equipment, and for weight and balance computation.
For example, the datum plane in B737NG is perpendicular to the fuselage centreline and found
130.0 inches forward of the aeroplane nose.

Figure 17: B737NG Datum Line

Position Identification and Location
Using the datum line as the prime reference point, it is possible to identify an exact point, for
example, a specific rivet, anywhere on the aircraft.

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Fuselage
For the fuselage, the three planes that give an exact location are termed:
The Fuselage Station line (FS) measured in millimetres from the datum line (Airbus), or
Body Station (BS), measured in inches from the datum line (Boeing)
The Left Buttock Line (LBL), or Right Buttock Line (RBL), measured from the
longitudinal centreline of the fuselage
The Water Line (WL), measured vertically from an imaginary water line zero, placed
some distance below the fully extended undercarriage of the aircraft
Body Station Line (BS)
A fuselage station is a vertical line perpendicular to the body centreline. In the case of the 747
aircraft, the datum line is 90 inches forward of the radome. So B STA 90 refers to the body or
fuselage station which is 90 inches back from the datum line. Likewise, it is possible to determine
that body station 2360 is where the stabiliser leading edge contacts the fuselage.

Figure 18: Fuselage Station Lines

Buttock Line (BL)
A body buttock line is a vertical line which establishes lateral distance to the left and right of the
fuselage’s vertical centreline. Buttock Line zero is the centre line of the aircraft. Distances left (LBL)
or right (RBL) identify position on the left or right side of the aircraft. Left and right designations
are always referenced facing forward in the aeroplane.

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Water Line (WL)
A waterline is a horizontal line which establishes vertical distances from the top to the bottom of
the aeroplane. Water line 0, in the case of a 747 is 91 inches below the lowest point of the
fuselage.

Figure 19: Buttock and Water Lines

Wing
Wing Buttock Line (WBL)
The use of a wing buttock line is one method of providing a location reference along the wing.
These stations are measured from the centre line of the aircraft, or buttock line zero. They
indicate the distance in inches along the wing towards the wing tip.

More accurate references are obtained using the term wing station (WS) where the reference is
against the wing’s rear spar.

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 Figure 20: Wing Buttock Lines

Engine
The engine station numbers show the locations of the structural components and features on the
engine.

Figure 21: Engine Station Lines

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Clock Position
Another position referencing system often used by engineers or flight crew is clock positions. They
are used to report faults on the aircraft or engines using a clock face as a reference, e.g. damage at
2 O’clock position. The reference for this is from within the aircraft looking forward.

Figure 22: Clock Position

Being able to identify the zone and exact point anywhere within that zone provides important
information, especially when writing up defects found during inspections.
Correctly identifying the location of components prevents the possibility of replacement of an
incorrect component.
If the defect found requires a structural repair, it ensures that the correct repair scheme
appropriate for the structural classification is selected.
Finally, the correct identification of the location of a defect ensures that the certification of the
work performed, does directly refer to that work.
Stress
Aircraft structures must be able to withstand all flight conditions and be able to operate under all
payload conditions. In aircraft structures stress is defined as the force or load (F) applied to an
element (beam, bulkhead or skin) divided by its cross sectional area (A), being: l = F/A, where the
l indicates the longitudinal direction.
The SI unit for stress is the Pascal (symbol Pa), which is equivalent to one Newton (force) per
square meter (unit area). The unit for stress is the same as that of pressure, which is also a
measure of force per unit area.

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There are five main types of stress loads that an aircraft is subjected to:
Tension
Compression
Shear
Bending
Torsion
Strain
The stresses within a structure must be kept below a defined permitted level. Where stress is, so is
strain. It is impossible to be subjected to stress without experiencing strain.
Strain is the linear deformation of the element divided by its original length/size. When
considering length deformation only the applicable formula is:
Strain = change in length / original length
Stress-Strain Curves
Stress-strain curve is used by engineers to interpret material strength. To obtain this type of curve
it is necessary to carry out a tensile test on a ductile material such as a piece of low carbon steel.

Figure 23: Stress-Strain Curves

A test piece of known dimensions is placed in the testing machine. To determine its strength, a
load (or force) is applied to “stretch” the test piece. The size of the load is measured and the stress
induced in the piece is calculated by dividing the applied load by the cross sectional area of the
test piece. The calculated value, stress, is represented on the vertical axis of the graph.

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As the load increases the material “stretches”, it elongates. The elongation is measured and
converted to strain by dividing the change in length by the original length of the test piece. The
calculated value, strain, is represented on the horizontal axis of the graph.
As the stress increases, the material stretches. Initially it is “elastic”. That is, if the load is removed
the test piece will return to its original length. This occurs until the material reaches its
“proportional limit” shown on the curve. This part is a straight line. This deformation is called
“elastic deformation” and the ratio of stress to strain is a constant known as “Young’s Modulus”,
denoted E, thus, σ = Eε.
As the stress increases beyond the proportional limit many materials show a definite ‘yield point’
and this is often used as a basis (yield stress) for design calculations. For materials without a
definite yield point (many brittle materials) an offset method is used to calculate a ‘theoretical’
yield which is used for design calculations.
After reaching the proportional limit, if the stress increases, the material continues to stretch, but
the elongation is now permanent. This is called “plastic deformation”, so if the load is removed the
material will NOT return to its original length.
The point of “ultimate stress” on the curve represents the material’s greatest ability to support a
load. In engineering it is often called the “Ultimate tensile stress” (UTS) and is the figure quoted
when we compare the strengths of different materials. Once the UTS has been reached the cross
sectional area of the test piece reduces (a process known as necking) and the applied load drops
accordingly. Fracture occurs at the end of the curve.
When aircraft are designed the size of the parts is determined by the loads those parts have to
withstand. Other factors, such as the cyclic nature of the loads, are also considered.
As mentioned earlier, depending on the design process being applied a ‘factor of safety’ can be
applied to either the ‘UTS’ or the ‘yield strength’ to provide a ‘maximum allowable stress’ from
which the minimum safe size of components can be calculated.
Tension
Tension describes forces that tend to pull an object apart. It is a stress produced in a body by
forces acting along the same line but in opposite directions, for example:
Flexible steel cable used in aircraft control systems are designed to withstand tension
loads
Wing struts of a high wing aeroplane are under tension during normal flight
The bolts used to fasten a windscreen to the fuselage are under tension stress during
normal flight

In the BAC1-111 accident in June 1990, the error was fitting the wrong bolts to the windscreen.
The accident happened when the aircraft was climbing through 17,300 feet on departure from
Birmingham. The left windscreen, which had been replaced prior to the flight, was blown out
under effects of the cabin pressure when it overcame the retention of the securing bolts, 84 of
which, out of a total of 90, were of smaller than specified diameter. The commander was sucked
halfway out of the windscreen aperture and was restrained by cabin crew whilst the co-pilot flew
the aircraft to a safe landing at Southampton Airport. This illustrates well the category of ‘wrong
parts’.

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Compression
Compression is the opposite of tension. It is the resultant stress of two forces which act along the
same line pushing against each other.
Wing struts of a high wing aeroplane are under compression while on the ground stationary or
taxiing – wings not producing lift.
Aircraft rivets are driven with a compressive force. When compression stresses are applied to a
rivet, the rivet shank expands until it fills the hole and forms a butt to hold materials together.

Figure 24: Compression Stresses

A landing gear oleo strut is under compression when an aircraft is on the ground.
Shear
Shear in an aircraft structure is a stress exerted when two pieces of fastened material tend to
separate. Shear stress is the outcome of sliding one part over the other in opposite directions.
The rivets are designed to withstand shear stresses when riveted the aluminium skin panels to the
stringers. Shear forces try to rip the rivet in two therefore, selection of rivets with adequate shear
resistance is critical.

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Generally, in aircraft structure rivets are subjected to shear only, but bolts may be stressed by
shear and tension, and in particular material, shear strength is less than tensile or compressive
strength.

Figure 25: Rivets Under Shear Loads

Torsion
Torsion is the stress applied to a material when it is twisted. It is a combination of tension and
compression loads. For example, torsional stress on the fuselage is created by the action of the
ailerons when the aircraft is manoeuvred.
Torque (also a twisting force) works against torsion.

Figure 26: Torsional Stress on a Fuselage

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Bending
Bending is the stress in an object caused by load being applied to one end while the other is
restrained. Like torsion, bending stress is also a combination of tension and compression stresses.
When an aircraft is on the ground, there is a bending force on the fuselage. This force occurs
because of the weight of the aircraft. The bending action creates a tension stress on the lower skin
of the fuselage and a compression stress on the top skin. These stresses are transmitted to the
fuselage when the aircraft is in flight.

Figure 27: Bending Force on a Fuselage

When the aircraft is in flight, lift forces act upward against the wings, tending
to bend them upward. The wings are prevented from folding over the fuselage by the
resisting strength of the wing structure. The bending action creates a tension stress on the bottom
of the wings and a compression stress on the top of the wings.

Figure 28: Bending Force on Wings

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Hoop Stress
Considering a thin cylindrical shell subjected to an internal pressure as shown in Figure, tensile
stress acting in a direction tangential to the circumference is called hoop stress or circumferential
stress.
Pressurised aircraft are subjected to hoop stress when the pressure inside the fuselage increases.
The aircraft skin tries to expand and split along the longitudinal axis. Hoses are also susceptible to
hoop stress.

Figure 29: Hoop Stress to Fuselage

Fatigue
Fatigue is progressive localized structural damage. It occurs in a material subjected to repeated or
fluctuating strains at stresses having a maximum value less than the ultimate tensile strength of
the material.
There are three requirements for a fatigue crack to form and spread in metals:
There must be a local plastic stress
There must be a tension stress
There must be a cyclic (repeated or fluctuating) stress
If we can eliminate any one of these three requirements, we can stop the fatigue process.
It should be noted that composite materials can fatigue under compression loads.
The insidious feature of fatigue failure is that there is no obvious warning, a crack forms without
appreciable deformation of structure making it difficult to detect the presence of growing cracks.
Fractures usually start from small nicks or scratches or fillets which cause a localised concentration
of stress. Failure can be influenced by a number of factors including size, shape and design of the
component, condition of the surface or operating environment.

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On April 28, 1988, Aloha Airlines Flight 243 suffered a massive structural failure as part of the
fuselage tore away from the Boeing 737 while in the air en route to Honolulu. It was later
determined that the failure was caused by widespread fatigue damage in the aluminium skin of
the fuselage. It was calculated that this particular aircraft had experienced 89,090 flight cycles
over its 19 year life span.
The investigation into this failure concluded that the widespread fatigue damage that led to the
ultimate failure was caused by the aircraft’s exceptionally large number of flight cycles and
accelerated by the exposure of the aircraft to corrosive salt water vapour during its inter-island
flights. The combination of these two factors led to the creation of small cracks throughout the
fuselage lap joints that eventually linked to form larger cracks and eventually complete failure.

Figure 30: Fatigue Damage

Aircraft Drainage
Corrosion is one of the biggest threats to the integrity of aircraft structure. Three conditions must
exist simultaneously for corrosion to take place:
An anode and a cathode
A metallic connector between the anode and cathode
An electrolyte such as water
Water cannot be avoided, but it can be controlled with drain paths, drain holes, sealants, and
corrosion-inhibiting compounds. Controlling the presence of water is usually the most effective
means of preventing corrosion
Small quantities of water collect in the cabin because of condensation. Drains are installed in the
fuselage structure to let the water out and to give more protection to the structure from
corrosion. The centre fuselage drains are located at the lowest point of the cabin, below the cabin
floor.

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Drainage
Effective drainage of all structure is vital to prevent fluids from becoming trapped in crevices. The
entire lower fuselage of a pressurized aircraft is drained by a system of valved drain holes. Fluids
are directed to these drain holes by a system of longitudinal and cross-drain paths through the
stringers and frame shear clips.
Pressurised Fuselage Drain Valve
As the cabin pressurizes, the pressure sensitive rubber seal will move down to close the drain hole.
When the hole is closed, loss of cabin pressure through the drain hole is prevented. When the
cabin pressure decreases the rubber seal will move up to its usual position and open the drain
hole. Any water that has collected will drain away through the main gear bay.
The drain valves may be electrically heated to prevent freezing in a pressurised aircraft.

Figure 31: Pressurised Fuselage Drain Valve

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Drain Hole
In non-pressurized aircraft, and non-pressurized components on pressurized aircraft, (flaps,
ailerons, rudder, elevators), small drilled holes in the aircraft skin act as moisture drainage holes.
They also allow fresh air to ventilate through the structure to help dry out any residual moisture.

Figure 32: Drain Hole

Ventilation
Although partial fuselage and wing-to-body fairings are not pressurised structures, differential
pressures can build up between the internal sections. Equal pressure in the sections is maintained
by the pressure relief valves, located in the structure. The valves open, against spring tension, to
release any overpressure build-up in the fairing sections. When the valves open, they remain open
until the pressure equalises between the sections of the structure.

Figure 33: Ventilation

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System Installation Provisions
A number of provisions are made on aircraft which help make a maintenance engineer’s job safer
and easier. System installations are designed to operate under all aircraft attitudes and flight
loads. Systems need to pass through holes in frames and bulkheads. Fluid hoses and tubes are
supported where they pass through the structure. Grommets made from nylon or rubber
compounds protect the components, moving control systems and structure from damages and
wear caused by fretting.
Hydraulic Systems
Most transport category aircraft have hydraulic systems located in dedicated panels. These panels
are commonly located in an unpressurised zone of the aircraft. Fluid leakage will drain overboard
and not contaminate the cabin. Having the components grouped together simplifies servicing and
maintenance.
Some aircraft do have hydraulic systems components located within the pressure cell. E.g.
F28/F100 and BAE146. In these aircraft, fluid leak tends to pool under the cabin floor. Hydraulic
fluid misting from a small leak under very high pressure (3000 psi) has been known to enter the air
conditioning system to the discomfort of the passengers and crew. For this reason most hydraulic
components are eliminated from the pressurised area.
Air Conditioning System
Air conditioning systems are also located in an unpressurised zone The cabin air distribution
system includes air ducts, filters, heat exchangers, silencers, non-return (check) valves,
humidifiers, and mass flow control sensors, and mass flow meters.
Components have lugs and stays which attach to brackets mounted on the aircraft structure.
Electrical/Avionics
Avionics and electrical equipment centres are commonly located in the pressurised cell of the
aircraft. Some of these systems have their own cooling and temperature monitoring systems.
Equipment centres are usually located below the cockpit or cabin floor and some equipment
centres can be accessed from the cabin. However, entry via the cabin is not intended for flight
crew access in flight, normal access is through an external door.
The battery is stowed in a compartment designed to support its weight in all aircraft attitudes and
under high “g” loads. The inside of the compartment should be adequately protected with a tar-
based paint or with polyurethane enamel to protect against corrosion. Battery cables should be
adequately supported by clips to protect them from chafing and flexing. All hardware in the
battery compartment should be corrosion resistant.

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Fuel Storage
In small aircraft the fuel tank or tanks are located near the centre of gravity so the balance
changes very little as the fuel is used. In large aircraft, fuel tanks are installed in every available
location and fuel valves allow the flight crew to keep the aircraft balanced by scheduling the use of
the fuel from the various tanks.
The weight of the fuel is a large percentage of an aircraft’s total weight, and the balance of the
aircraft in flight changes as the fuel is used. These conditions add to the complexity of the design
of an aircraft fuel system.

Figure 34: Fuel Tank System

Main Landing Gear (MLG)
Fittings for the wing mounted MLG are installed on the aft face of the rear spar and an auxiliary or
false spar. These fittings include:
The gear support rib
The trunnion fitting
The side stay attachment bracket
The actuator attachment bracket

Figure 35: Main Landing Gear Fittings

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Waste Disposal
The sub-systems of the waste disposal system which discard waste products and fluids from the
galleys and the lavatories are:
The Toilet System
The Waste Water Drain System

Figure 36: A Waste Water Drain System

The toilet system removes waste from the toilet bowl through a vacuum drain to an underfloor
waste holding tank.
The system uses potable water from the aircraft pressurised water system to flush the toilet.
During ground service, the waste holding tank is emptied, cleaned and filled with a prescribed
quantity of sanitary fluid.
The waste water drain system discards waste water from the lavatory washbasins and the sinks of
the galley through the aircrafts heated drain masts. Waste storage tanks are located in rear of the
aircraft in the pressurised zone. The support structure must support the heavy full tanks at all
aircraft attitudes and during high ‘g’ manoeuvres.

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Potable Water
The aircraft potable water system is another heavy storage system which supplies drinking water
to the galleys and the lavatory wash basins.
The potable water storage tanks are located in various locations within an aircraft’s pressurised
zone. The support structure must support the weight of the full tanks at all aircraft attitudes and
during high ‘g’ manoeuvres.

Figure 37: Potable Water System

Heating is required to prevent the water freezing where plumbing passes through unpressurised
areas. Galley and wash basin waste water is drained overboard via heated drain masts.
Auxiliary Power Unit (APU)
Each engine and auxiliary power unit mount and its supporting structure must be designed for a
limit load factor in lateral direction. For the side load on the engine and auxiliary power unit
mount must be at least equal to the maximum load factor obtained in the yawing conditions but
not less than 1.33.

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Lightning Strikes
Aircraft cannot always avoid being struck by lightning. To minimise the potential danger of a
lightning strike, principally arcing and electrical shock, the electrical current created must be able
to find a path of least resistance from the point of impact to a suitable discharge point.

Figure 38: Lightning Strike on B747

This path is normally created by the metal skin and frame of the aircraft, provided that the
individual structural components that make up the aircraft are adequately connected electrically.
Composite materials, which are not electrically conductive, must have provision to conduct
electrical current incorporated into their design and manufacture. To provide a suitable path to
dissipate a lightning strike safely, the following procedures are employed:
High capacity electrical conductors, called bonding straps, link together all parts of the
airframe to provide a low resistance path, thereby reducing the possibility of arcing.

Figure 39: Bonding Strap attached to flight control

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The radome, which must be manufactured of a non-conductive composite material, has
conductive lightning diverter strips incorporated to collect the charge built up on the radome
surface and safely transfer it to the airframe structure.

Figure 40: Radome lightning diverter strips (F28)

Static electricity or a lightning strike will generally discharge from the sharp trailing
edges of the airframe structure. To prevent arcing damage to these edges, static wicks
are placed at these locations to harmlessly dissipate the electrical charge to the
atmosphere.

Figure 41: Static Discharge Wicks

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Aircraft Electrical Bonding
Bonding
Bonding is the electrical connecting of components of an aircraft structure together which are not
otherwise adequately connected. This is to prevent static electricity (including lightning) from
building up on one part of the structure to a point where it is high enough to allow it to jump to
another part. Bonding failure has the potential to cause Electromagnetic interference (EMI),
physical damage to mechanical and electronic components, and risk of electrical shock.
Grounding
The term grounding, when used in reference to aircraft electrical circuits, is where conductive
parts of the structure are used to provide a return path, instead of using an insulated wire, for
completing an electrical circuit normally. Grounding also referred to as earthing, provides an
alternative return path should a two wire electrical circuit becomes faulty, reducing the potential
for electric shock. Bonding ensures there is a continuous path between different parts of a
conductive structure.
On an aircraft, the primary structure is commonly referred to as ground.
Bonding Leads
To accomplish the purpose of grounding, it is necessary to provide a conductive path where direct
electrical contact does not exist. Jumpers or bonding straps used for this purpose in such
applications as between moving parts, between shock-mounted equipment and structure, and
between electrically conducting objects and structure.
Bonding straps (or leads) are pre-fabricated from braided copper or aluminium terminated with
crimps. The maximum permissible resistance of a bonding strap is 0.003 ohms.

Figure 42: Radome Bonding Straps (F28)

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