Helicopter Structures Student Resource PDF

Summary

This document is a student resource covering helicopter structures, including definitions, study resources, and an introduction to airframe structures. It describes concepts like stress, strain, and fatigue, and then delves into Primary, Secondary and Tertiary structural classifications.

Full Transcript

Student Resource

Subject B1-12b:
Helicopter Structures
 Copyright © 2018 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
CONTENTS............................................................................................................................................ 3
DEFINITIONS......................................................................................................................................... 4
STUDY RESOURCES............................................................................................................................... 5
INTRODUCTION.................................................................................................................................... 6
Topic 12.5.1.1 Airframe Structures – General Concepts................................................................ 6
Topic 12.5.2.1 Airframe Structures – Primary Construction.......................................................... 6
Topic 12.5.2.2 Airframe Structures – Secondary Construction...................................................... 7
Topic 12.5.2.3 Airframe Structures – Surface Finishing................................................................. 7

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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

B1-12b Student Handout

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 INTRODUCTION
The purpose of this subject is to familiarise you with the basic construction, requirements and
maintenance of helicopter airframe structures.
On completion of the following topics you will be able to:
Topic 12.5.1.1 Airframe Structures – General Concepts
State the airworthiness requirements for structural strength.
Identify inspection programs associated with ageing aircraft.
Describe primary, secondary and tertiary structural classifications.
Describe fail safe, safe life and damage tolerance concepts.
Describe zonal and station identification systems.
Describe the following with regards to airframe structures:
Stress
Strain
Bending
Compression
Shear
Torsion
Tension
Hoop Stress
Fatigue
Describe drain and ventilation provisions used in helicopters.
Describe provisions used in helicopters for system installations.
Describe provisions for lightning protection.
Topic 12.5.2.1 Airframe Structures – Primary Construction
Identify the following airframe structures and describe their constructions:
Stressed skin fuselage.
Formers.
Stringers.
Longerons.
Bulkheads.
Frames.
Doublers.
Struts.

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 Ties.
Floor Structures.
Reinforcement.
Methods of skinning and anti-corrosion.
Cabin pressure control.
Describe the following structure assembly technique:
Riveting.
Bolting.
Bonding.
Topic 12.5.2.2 Airframe Structures – Secondary Construction
Describe the attachment methods for the following:
Pylons.
Stabilisers.
Landing gear.
Describe the general construction and installation of passenger and crew seats.
Describe the construction of doors, mechanisms, operation and safety devices.
Describe window and windscreen construction and mechanisms.
Describe construction of fuel storage tanks.
Describe the construction of nacelles and pylons.
Describe the construction of firewalls.
Describe the construction of engine mounts.
Describe methods of alignment and symmetry checks used for inspecting
airframes.
Topic 12.5.2.3 Airframe Structures – Surface Finishing
Describe methods of surface protection, such as chromating, anodising and
painting.
Describe methods of surface cleaning.

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Topic 12.5.1.1 – Airframe Structures - General Concepts
Table of Contents
List of Figures....................................................................................................................................... 3
Topic 12.5.1.1 – Airframe Structures - General Concepts............................................................. 5
Introduction......................................................................................................................................... 5
Stress.................................................................................................................................................... 5
Tension................................................................................................................................................. 6
Compression........................................................................................................................................ 6
Torsion................................................................................................................................................. 7
Bending................................................................................................................................................ 8
Shear.................................................................................................................................................... 9
Hoop Stress........................................................................................................................................ 10
Strain.................................................................................................................................................. 11
Fatigue................................................................................................................................................ 11
Identification Systems.............................................................................................................. 12
Datum................................................................................................................................................. 13
Station Lines....................................................................................................................................... 14
Water Lines........................................................................................................................................ 15
Buttock Lines...................................................................................................................................... 15
Clock Positions................................................................................................................................... 16
Aircraft Airworthiness.............................................................................................................. 17
Introduction....................................................................................................................................... 17
Aircraft Airworthiness........................................................................................................................ 17
FAR-29, CASR 29 and CS-29................................................................................................................ 18
Structural Strength Requirements..................................................................................................... 18
Fail Safe.............................................................................................................................................. 19
Safe Life.............................................................................................................................................. 20
Damage Tolerance............................................................................................................................. 21
Damage Tolerance...................................................................................................................................... 21
Negligible.................................................................................................................................................... 21
Repairable................................................................................................................................................... 21
Unrepairable............................................................................................................................................... 21
Drainage............................................................................................................................................. 22
Ageing Aircraft Inspection Requirements.................................................................................. 24
Task 5 – 14 CFR/JAR 25 Ageing Aircraft............................................................................................. 24

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Background........................................................................................................................................ 24
Structural Classifications.......................................................................................................... 27
Primary Structure............................................................................................................................... 28
Secondary Structure........................................................................................................................... 28
Tertiary Structure............................................................................................................................... 28
Installations............................................................................................................................. 29
Quick Disconnect Valves.................................................................................................................... 29
External Power Receptacles............................................................................................................... 30
Avionics Racks.................................................................................................................................... 31
Ground Locking Pins........................................................................................................................... 32
Anchor Nuts....................................................................................................................................... 33
Turnlock Fasteners............................................................................................................................. 34
Electrical Connectors......................................................................................................................... 34
Bonding.............................................................................................................................................. 35
Lightning Protection................................................................................................................................... 35
Bonding Straps............................................................................................................................................ 35
Bonding Straps (cont):................................................................................................................................ 36
Lightning Diverter Strips............................................................................................................................. 37
Lightning Strike Inspection......................................................................................................................... 37
Conditional Inspections...................................................................................................................... 38

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List of Figures
Figure-1. Formula for Stress............................................................................................................. 5
Figure-2. Tension.............................................................................................................................. 6
Figure-3. Compression...................................................................................................................... 6
Figure-4. Compression on a Rivet..................................................................................................... 7
Figure-5. Torsion............................................................................................................................... 7
Figure-6. Engine Shaft Suffering from Torsional stress.................................................................... 8
Figure-7. Bending............................................................................................................................. 8
Figure-8. Bending of Rotor Blades.................................................................................................... 9
Figure-9. Shear.................................................................................................................................. 9
Figure-10. Shear on a Clevis Bolt...................................................................................................... 10
Figure-11. Hoop Stress..................................................................................................................... 10
Figure-12. Strain............................................................................................................................... 11
Figure-13. Identification Systems..................................................................................................... 12
Figure-14. Datum.............................................................................................................................. 13
Figure-15. Station Lines.................................................................................................................... 14
Figure-16. Water Lines..................................................................................................................... 15
Figure-17. Buttock Lines................................................................................................................... 15
Figure-18. Clock Position.................................................................................................................. 16
Figure-19. Fail Safe........................................................................................................................... 19
Figure-20. Safe Life........................................................................................................................... 20
Figure-21. Damage Tolerance.......................................................................................................... 21
Figure-22. Corrosion......................................................................................................................... 22
Figure-23. Drains.............................................................................................................................. 22
Figure-24. Drain Holes...................................................................................................................... 23
Figure-25. Structural Classifications................................................................................................. 27
Figure-26. Quick Disconnect Valves................................................................................................. 29
Figure-27. External DC Power Receptacles...................................................................................... 30
Figure-28. Avionics Racks................................................................................................................. 31
Figure-29. Ground Locking Pins........................................................................................................ 32
Figure-30. Anchor Nuts..................................................................................................................... 33
Figure-31. Turnlock Fasteners.......................................................................................................... 34
Figure-32. Electrical Connectors....................................................................................................... 34
Figure-33. Bonding Straps................................................................................................................ 36

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Figure-34. Braided Bonding Straps................................................................................................... 36
Figure-35. Lightning Protection........................................................................................................ 37

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Topic 12.5.1.1 – Airframe Structures - General Concepts
Introduction
The airframe, or fundamental structure, of a helicopter can be made of either metal or organic
composite materials, or some combination of the two. Higher performance requirements will
incline the designer to favour composites with higher strength-to-weight ratio, often epoxy (a
resin) reinforced with glass, aramid (a strong, flexible nylon fibre), or carbon fibre. Typically, a
composite component consists of many layers of fibre-impregnated resins, bonded to form a
smooth panel. Tubular and sheet metal substructures are usually made of aluminium, though
stainless steel or titanium is sometimes used in areas subject to higher stress or heat. To facilitate
bending during the manufacturing process, the structural tubing is often filled with molten sodium
silicate. A helicopter's rotary wing blades are usually made of fibre-reinforced resin, which may be
adhesively bonded with an external sheet metal layer to protect edges. The helicopter's
windscreen and windows are formed of polycarbonate sheeting.
Stress
Stress is the force or load acting on or through a unit area of material. Stress is the internal force in
a body that resists the tendency of an external force to change its shape. When an external force
acts on a body, it is opposed by an internal force called stress. The English measure for stress is
pounds per square foot, or pounds per square inch. Stress is shown as the ratio:

Figure-1. Formula for Stress

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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. Flexible steel cables used in
helicopters for ties are designed to withstand tension loads. Steel cable is easily bent and has little
opposition to other types of stress; however, when subjected to a purely tensional load it
performs exceptionally well.

Figure-2. Tension

Compression
Compression is the resistance to an external force that tries to push an object together is the
resultant stress of two forces which act along the same line pushing against each other.

Figure-3. Compression

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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-4. Compression on a Rivet

Torsion
Torsion is the stress applied to a material when it is twisted. It is a combination of tension and
compression stresses. When an object is subjected to torsional stress, tensional stresses operate
diagonally across the object while compression stresses act at right angles to the tension stresses.

Figure-5. Torsion

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An engine crankshaft is a component whose primary stress is torsion. The pistons pushing down
on the connecting rods rotate the crankshaft against the opposition caused by the propeller. The
resulting stresses attempt to twist the crankshaft.

Figure-6. Engine Shaft Suffering from Torsional stress

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.

Figure-7. Bending

Helicopter blades in flight are subjected to bending stress due to lift created; the top surface is
subjected to compression and the lower skin is subjected to tension.
However when the helicopter is on the ground, bending stress is reversed because of blade sag –
top surface tension and lower surface compression.

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 Figure-8. Bending of Rotor Blades

Shear
Shear is the force that when exerted on a body, it tries to slice or slide it apart.

Figure-9. Shear

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Aircraft clevis bolts are subjected to shear stress on an aircraft when the items they are holding
together have tension or compression loads applied to them. However, when no force is present,
the clevis bolt is free to turn in its hole.

Figure-10. Shear on a Clevis Bolt

Hoop Stress
Hoop stress is stress in a pipe wall acting circumferentially in a plane perpendicular to the
longitudinal axis of the pipe produced by the pressure inside the pipe. Cooking sausages are
susceptible to hoop stress as the pressure inside the skin increases due to the heat. Cracks along
the longitudinal axis are the resultant failure of the skin. Another example is where cracks in car
radiator hoses are caused by the pressure from the heated water.

Figure-11. Hoop Stress

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Strain
Strain is the deformation or physical change in a material that is caused by stress. Hooke’s law
states that if strain does not exceed the elastic limit of a body, it is directly proportional to the
applied stress. This fact allows beams and springs to be used as measuring devices. For example,
as force is applied to a hand torque wrench, its deformation, or bending, is directly proportional to
the strain it is subjected to. Therefore, the amount of torque deflection can be measured and used
as an indication of the amount of stress applied to a bolt. Excessive bending stress causes
significant physical change (strain) as displayed by the control rod shown below.

Figure-12. Strain

Fatigue
Fatigue is the condition that exists in metal that causes it to lose some strength. It occurs when
metal is subjected to a series of stress reversals. For example, metal is bent back and forth
repeatedly. Helicopter blades are susceptible to fatigue due to different bending stresses put on
them in the air as opposed to on the ground.

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Identification Systems
The location of a part on a helicopter is typically specified by fuselage station numbers, water
lines, and buttock lines.
Another position referencing system - clock positioning often used by engineers or flight crew is to
report faults on the aircraft or engine.
To help identify specific areas of the helicopter for inspection purposes the helicopter is broken up
into zones for inspection purposes.

Figure-13. Identification Systems

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Datum
The datum is an imaginary vertical plane from which all horizontal measurements are taken with
the helicopter in a level flight attitude. The reference datum sits at a right angle to the helicopters
longitudinal axis.
For each helicopter make and model, the location of all items including equipment, tanks, baggage
compartments, seats, engines are listed in the Helicopter Specifications or Type Certificate Data
Sheets as being so many inches from the datum.
There is no fixed rule for the location of a datum. The manufacturer chooses a location for the
datum where it is most convenient for measurement, identifying the location of equipment, and
for weight-and-balance computation. It may be located on the nose of the helicopter, the fire-wall,
or even at a point in space ahead of the helicopter.

Figure-14. Datum

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Station Lines
Fuselage station numbers identify locations fore and aft along the fuselage. All station numbers
are measured from a reference called station zero. This reference, often called the datum, is
typically on the fuselage or ahead of it. Dimensions are measured aft of the datum reference point
along the length of the fuselage. All fuselage frames and bulkheads are identified by fuselage
station numbers.
For example, if the datum is six inches ahead of the fuselage nose and the centre line of the main
bulkhead is 137 inches from the datum; its fuselage station number is 137.

Figure-15. Station Lines

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Water Lines
Waterlines are used to identify structure by vertical measurement. Zero water line is the edge of
the base reference plane. Like station numbers, water lines are measured from a datum reference.
In this case the zero reference is called water line zero. Waterline zero may be located on or below
the fuselage, sometimes even below ground level. Water lines are positive above zero and
negative below zero.
For example, if the floor of the main cabin must be installed at water line -16, the floor is 16 inches
below water line zero.

Figure-16. Water Lines

Buttock Lines
Distances to the right or left of the fuselage centre line are measured by buttock lines and are
referenced from an aircraft’s longitudinal centreline (Buttock Line zero).
For example, if the tip of a horizontal surface is located at buttock line 108.88, it means that it is
108.88 inches from the fuselage centreline.

Figure-17. Buttock Lines

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Clock Positions
Used to report faults on the aircraft or engine.

Figure-18. Clock Position

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Aircraft Airworthiness
Introduction
Before a helicopter can take to the skies, they are required to have an authorised Type Certificate
and a Certificate of Airworthiness.
Procedural requirements for the issue of Type Certificates and Certificates of Airworthiness can be
found in Part 21 of the appropriate regulatory authority.
Part of the certification process is satisfying guidelines laid down in separate regulations for the
category of aircraft type being applied for. These category regulations include but are not limited
to:
General requirements
Flight requirements
Structure requirements
Design and construction requirements
Power plant requirements
Equipment requirements
Operating Limitations and Information requirements
Structural strength requirements of a helicopter, or a helicopter component, are developed in the
initial design phase of the helicopter or component, so they can withstand the operational stresses
exerted on them.
Aircraft Airworthiness
There are 5 separate aircraft categories:
Part 22 - Sailplanes and Powered Sailplanes
Part 23 - Small Aeroplanes
Part 25 - Transport Category Aeroplanes
Part 26 - Primary/Intermediate Category Aeroplanes
Part 27 - Rotorcraft
Part 29 - Rotorcraft (Transport Category)
NOTE: To maintain standardisation with ICAO, the numbering system for categories remains the
same within EASA Certification Specification (CS), Federal Aviation Authority FARs and the Civil
Aviation Safety Authority CASRs.

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FAR-29, CASR 29 and CS-29
This part prescribes airworthiness standards for the issue of type certificates, and changes to those
certificates, for transport category rotorcraft.
Transport category rotorcraft must be certificated in accordance with either the Category A or
Category B requirements of this part. A multiengine rotorcraft may be type certificated as both
Category A and Category B with appropriate and different operating limitations for each category.
Rotorcraft with a maximum weight greater than 20 000 pounds and 10 or more passenger seats
must be type certificated as:- Category A Rotorcraft.
Rotorcraft with a maximum weight greater than 20 000 pounds and nine or less passenger seats
may be type certificated as:- Category B Rotorcraft provided the Category A requirements of
Subparts C, D, E, and F of this part are met.
Rotorcraft with a maximum weight of 20 000 pounds or less but with 10 or more passenger seats
may be type certificated as:- Category B Rotorcraft provided the Category A requirements of 29.67
(a)(2), 29.87, 29.1517, and subparts C, D, E, and F of this part are met.
Rotorcraft with a maximum weight of 20 000 pounds or less and nine or less passenger seats may
be type certificated as:- Category B Rotorcraft.
Each person who applies under Part 21 for a certificate or change described in paragraphs (a)
through (f) of this section must show compliance with the applicable requirements of this part.
Structural Strength Requirements
CS-29 Section 1 - Subpart C - Structures in each aircraft category regulation contains the structural
strength requirements that an aircraft or component must adhere to in order to obtain a Type
Certificate and a Certificate of Airworthiness.
These requirements include but are not limited to:
Flight loads
Flight manoeuvring loads
Control surface and systems loads
Ground loads
Structural strength requirements are specified in terms of:
Limit load:- maximum load expected in service
Ultimate load:- limit load multiplied by prescribed factors of safety
Ultimate Factor of Safety (U.F.S.):- Ultimate Load/Limit Load
The structure must be able to support the limit load without detrimental permanent deformation.
The structure must be able to support the ultimate load without failure for at least 3 seconds.
Ultimate Factor of Safety (U.F.S.) is a design value. Normally, U.F.S = 1.5 for Aircraft.

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Fail Safe
Helicopter structural engineers design helicopters to withstand structural loads for the expected
lifetime of the airframe.
To ensure that the helicopter has a full safe life, engineers include a Fail Safe Structural Analysis in
the initial design. That means ensuring the helicopter structure as a whole has sufficient strength
to prevent complete structural failure when a component of that structure has failed.
This example of a fail-safe structure is shown. The structure is assumed to be a Fail Safe Multiple
Load Path Structure and the steps required to satisfy this requirement will be outlined. The
structure will be designed to be Fail Safe by virtue of being able to sustain the failure of one load
path and still maintain the residual strength and remaining structural guidelines.

Figure-19. Fail Safe

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Safe Life
Safe life is a measure of the useful life of the material and is determined by the number of cycles
of loading, of a specified character, that a given specimen of material can sustain before failure
occurs
In Safe-Life design products are designed to survive a specific design life with a chosen reserve.
Employed in critical systems which are either very difficult to repair or may cause severe damage
to life and property. These systems are designed to work for years without requirement of any
repairs.
Typically a Safe Life / Fatigue Life was established by conducting a fatigue test to a helicopter
design on either a complete structure or major components and applying a timeframe for life to
failure for the fleet.

Figure-20. Safe Life

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Damage Tolerance
In the 1960s it became evident that the original philosophy based on safe life was inadequate for
structural components, because it did not account for fatigue cracking arising from damage in the
structure from manufacturing processes or from in-service maintenance of the aircraft or for
different operating conditions for different aircraft.
Damage Tolerance
Damage tolerance is applied to the design and modification of aircraft and provides guidance on
the application of durability and damage tolerance requirements to aircraft structures. Aircraft
designers and manufacturers use Damage Tolerance philosophies to determine NDI schedules for
airframe components.
Damage Tolerance requires a structure to be strong enough to sustain a defect until it is detected.
Negligible
Negligible damage is damage which is allowed to exist or stay as is. It is deemed not to have any
adverse effects on the helicopter’s airworthiness.
Repairable
Repairable damage is damage which cannot remain as is. It may have adverse effects on aircraft
airworthiness but is not deemed bad enough to warrant replacement parts being installed.
Unrepairable
Unrepairable damage is damage deemed to be too severe to leave as is, or repair to a serviceable
state.

Figure-21. Damage Tolerance

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Drainage
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

Figure-22. Corrosion

Controlling the presence of the moisture is usually the most effective means of preventing
corrosion. Effective drainage of all structure is vital to prevent fluids from becoming trapped in
crevices and causing corrosion. Fluids are directed to these drain holes by a system of longitudinal
and cross-drain paths through the stringers and frame shear clips.

Figure-23. Drains

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Helicopters have small drilled holes in the skin for moisture drainage holes. They also allow fresh
air to ventilate through the structure to help dry out any residual moisture. Drain paths and drain
holes prevent galvanic corrosion from occurring.

Figure-24. Drain Holes

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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.)

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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.
The FAA accepted this alternative approach in June 1991. The AAWG was informally tasked to
institutionalise 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 characterised 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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Structural Classifications
All helicopter structural components are classified into groups according to their importance for
the structural integrity of the helicopter.
There are 3 structural classifications:
Primary structure
Secondary structure
Tertiary structure

Figure-25. Structural Classifications

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Primary Structure
The portions of the helicopter structure which if it were to fail in flight, landing or taking off, might
cause structural collapse, loss of control, failure of motive power, or serious injury to members of
the aircrew. e.g. engine mounts and landing gear.
Secondary Structure
The portions of structure which would normally be regarded primary but have reserve strength
over design requirements that appreciable weakening may be permitted without risk or failure.
Portions of the structure are also classified as secondary if their failure would not seriously
endanger the safety of the aircraft but may cause significant damage. e.g. fairings.
Tertiary Structure
The portions of the helicopter would not endanger the safety of the helicopter or cause significant
damage if they were to fail. E.g.: loom and piping attachment brackets.

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Installations
Quick Disconnect Valves
Quick-disconnect, or line-disconnect valves, are installed in hydraulic lines to prevent the loss of
fluid when units are removed. Such valves may be installed in the pressure and suction lines of the
system just in front, and immediately behind the power pump. These valves can also be used in
ways other than just for unit replacement. A power pump can be disconnected from the system
and a hydraulic test stand connected in its place.

Figure-26. Quick Disconnect Valves

The top part of the illustration above shows the valve in the disconnected position. The two
springs (A and B) hold both poppet’s C and F in the closed position as shown. This prevents loss of
fluid through the disconnected line.
The bottom part of the illustration above shows the valve in the connected position. When the
valve is being connected, the coupling nut draws the two sections together. The poppet valve
extension (D or E) forces the opposite piston back against its spring. This action moves the poppet
off its seat and permits fluid to flow through that section of the valve. As the nut is drawn up
tighter, one piston hits a stop and then the other piston moves back against its spring, opening its
poppet valve and, in turn, allows fluid to flow. Thus, fluid is allowed to continue through the valve
and on through the system.

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External Power Receptacles
Because of the heavy drain the starter puts on the battery, a battery cart or external power supply
may be plugged in to furnish power for engine starting.
Power is brought from a battery cart or rectifier through a standard three-terminal external power
plug. Two of the pins in the aircraft receptacle are larger than the third, and are also longer. When
the cart is plugged in, a solid contact is made with the two larger plugs. The external power relay
in the aircraft remains open, and no current can flow from the external source until the plug is
forced all the way into the receptacle, and the smaller pin makes contact. This small pin then
supplies power through a reverse-polarity diode to the external power relay. The relay is
energised in the closed position and connects the external power source to the aircraft bus.
The reverse-polarity diode is used in the circuit to prevent an external power source with incorrect
polarity from being connected to the aircraft’s bus. The diode simply blocks current from flowing
to the external power relay if the applied power is connected backwards or is offering reverse
polarity.

Figure-27. External DC Power Receptacles

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Avionics Racks
Avionics racks are provided on most helicopters for ease of fitment of avionics equipment. They
provide for exact positioning and safe housing of the equipment, along with quick removal and
installation of the equipment.
Several factors to consider when installing avionics equipment include:
Sufficient air circulation to prevent overheating. This might require a certain free air space
in some cases and the installation of a cooling fan in others
Adequate clearance from high temperatures and flammable materials (next to a
combustion heater would not be good place to install a radio)
Protection from water, fumes, hydraulic fluid, etc.
Protection from damage by baggage or seat deflection
Sufficient clearance to prevent rubbing or striking upon helicopter structures, control
cables, movable parts, etc.
Preventing interference and noise. Separate sensitive electronic equipment from inverters,
power supplies, strobe lights, motors, etc.
If shock mounts will be used, ensure that the equipment does not exceed the weight
carrying capability of the shock mounts and install adequate bonding jumpers or straps.

Figure-28. Avionics Racks

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Ground Locking Pins
Ground locking pins are installed into holes specifically placed in the landing gear to prevent
retraction during ground and maintenance operations.

Figure-29. Ground Locking Pins

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Anchor Nuts
Anchor nuts simplify the process of installing and removing doors and panels. They are riveted to
the aircraft structure so a spanner is not required to hold the nut while the screw is being
installed.

Figure-30. Anchor Nuts

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Turnlock Fasteners
These are used on aircraft for quick and easy removal of access panels for inspection and servicing
purposes. They include:
Camloc fasteners
Dzus fasteners
Airloc fasteners

Figure-31. Turnlock Fasteners

Electrical Connectors
Electrical connectors provide a great deal of flexibility when attaching electrical wiring to various
components. They are installed on wiring that is frequently disconnected.

Figure-32. Electrical Connectors

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Bonding
Lightning Protection
Helicopters cannot avoid being struck by lightning. They are metallic objects, often flying in storm
conditions. The adverse effects of lightning strike can be minimised. Lightning is unpredictable. It
can enter and exit the aircraft at any point. Just like a bullet, the exit damage is always greater
than the entry damage.
Bonding Straps
Bonding between structural components is essential to minimise lightning damage to structure,
electronic equipment or human occupants. Bonding or grounding is the process of providing an
equal electrical potential between different parts of the airframe.
Bonding straps prevent a difference in potential from building to the point that sparks jump from
one component to another. In the power plant compartment, shock mounted components are
also bonded to the main structure with bonding straps. Any electrical component which uses the
helicopter structure as the return path for its current must be bonded to the structure.
When selecting a bonding strap, it must be large enough to handle all the return current flow
without producing an unacceptable voltage drop. An adequately bonded structure requires
bonding straps that hold resistance readings to a negligible amount.
For example, CASA AC21-99 Sect 2 Chap 13 states “to accomplish the purpose of bonding or
grounding, it is necessary to provide a conductive path where direct electrical contact does not
exist. Jumpers are used for this purpose in such applications as between moving parts, between
shock-mounted equipment and structure, and between electrically conducting objects and
structure. Keep jumpers as short as possible; if practical, under 76mm. Do not use two or more
jumpers in series.
TESTING BONDS AND GROUNDS
Resistance Tests After Connection
NOTE
The resistance figures provided below are for general electrical and RF bonding. Specific
requirements detailed in aircraft or component publications should take precedence.
The resistance across a bonding or grounding jumper is required to be 0.1 ohms (100 milliohms) or
less for general electrical bonding whether using bonding jumpers or where metallic components
are directly attached.
Where bonding of RF components is required, the resistance should be a maximum 0.0025 ohms
(2.5 milliohms) (Reference – MIL-STD-464).
Test is made after the mechanical connection is completed, and consists of a milli-ohmmeter
reading of the overall resistance between the cleaned areas of the object and the structure.
Aluminium alloy jumpers are recommended for most cases, but copper jumpers should be used to
bond together parts made of stainless steel, cadmium plated steel, copper, brass, or bronze, the
bonding strap should have enough mechanical strength to withstand constant flexing and should
be easily installed to allow removal of the component being bonded.”

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 Figure-33. Bonding Straps

Bonding Straps (cont):
Minimise lightning damage where structure is joined or hinged
Supply ground path for electrical equipment
Reduce radio interference
Allow static charges to equalise between different parts of the airframe, reducing fire
hazard

Figure-34. Braided Bonding Straps

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Bonding straps are positioned to:
Insolate passenger cabin, fuel tanks, cargo areas and cockpit from risk of sparks or electric
shock
Divert a charge around electronic equipment
Provide a low resistance path for the electrical charge to exit
Lightning Diverter Strips
Lightning diverter strips are bonding strips mounted on the outside of fibreglass nose radomes. If
lightning hits the radome, the diverter strips conduct the charge away and into the aircraft
structure. The radome should only be painted with approved types of paint, which will not
interfere with the radar frequency signals that must pass through the radome.
Lightning Strike Inspection
An unscheduled inspection must be carried out after an aircraft has experienced a lightning strike.
Lightning damage ranges from minute burn marks to severe damage to the airframe, engine
and/or avionics equipment.
The inspection checks for damaged structure at entry and exit points, and radio and navigation
equipment operation.

Figure-35. Lightning Protection

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Conditional Inspections
A conditional inspection is an unscheduled inspection conducted as a result of a specific over-limit,
or abnormal event. Examples of events requiring special inspections include:
Hard landings
Overstress conditions
Flight into severe turbulence
Flight into volcanic ash
Over-temperature conditions
Overweight landings
Exceeding placarded speeds for flap or landing gear extension
Bird strike
Lightning strike
Foreign object damage (FOD)

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Topic 12.5.2.1 – Airframe Structures – Primary Construction
Table of Contents
List of Figures....................................................................................................................................... 2
Topic 5.2.1 – Airframe Structures – Primary Construction........................................................... 3
Structural Assembly Techniques.......................................................................................................... 3
Riveting................................................................................................................................................. 4
Rivet Codes................................................................................................................................................... 5
Rivet Head Design......................................................................................................................................... 6
Blind Rivets................................................................................................................................................... 7
Hi-Lok Fasteners........................................................................................................................................... 7
Bolting.................................................................................................................................................. 8
Lock bolts...................................................................................................................................................... 8
Construction............................................................................................................................ 10
Tubular Construction......................................................................................................................... 11
Sheet Metal Construction.................................................................................................................. 12
Stressed Skin Fuselage................................................................................................................................ 12
Bonded Construction......................................................................................................................... 13
Composite Materials and Adhesives.......................................................................................................... 13
Body Structure................................................................................................................................... 15
Bottom Structure........................................................................................................................................ 15
Cabin Section.............................................................................................................................................. 15
Rear Section................................................................................................................................................ 16
Formers.............................................................................................................................................. 16
Bulkheads........................................................................................................................................... 16
Longerons........................................................................................................................................... 17
Stringers............................................................................................................................................. 17
Doubler............................................................................................................................................... 18
Beams................................................................................................................................................. 18
Floor Structure................................................................................................................................... 19
Methods of Skinning: - Metal............................................................................................................ 19
Methods of Skinning: - Composite..................................................................................................... 20
Methods of Skinning: – Sandwich Core............................................................................................. 20
Struts.................................................................................................................................................. 21

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List of Figures
Figure-1. Riveting.............................................................................................................................. 3
Figure-2. Lockbolt Fastener.............................................................................................................. 4
Figure-3. Jo-Bolt Fastener................................................................................................................. 4
Figure-4. Cherry Fastener................................................................................................................. 5
Figure-5. Hi-Lok Fastener................................................................................................................. 5
Figure-6. Riveting.............................................................................................................................. 6
Figure-7. Blind Rivet Gun.................................................................................................................. 7
Figure-8. Hi-lok Fastener.................................................................................................................. 8
Figure-9. Lock Bolts.......................................................................................................................... 9
Figure-10. Helicopter Construction.................................................................................................. 10
Figure-11. Tubular Construction...................................................................................................... 11
Figure-12. Sheet Metal Construction............................................................................................... 12
Figure-13. Boron Patch..................................................................................................................... 14
Figure-14. Bonded Construction...................................................................................................... 15
Figure-15. Formers........................................................................................................................... 16
Figure-16. Bulkheads........................................................................................................................ 16
Figure-17. Longerons........................................................................................................................ 17
Figure-18. Stringers.......................................................................................................................... 17
Figure-19. Doubler............................................................................................................................ 18
Figure-20. Beams.............................................................................................................................. 18
Figure-21. Floor Structure................................................................................................................ 19
Figure-22. Skinning: - Metal............................................................................................................. 19
Figure-23. Fibreglass Laminate......................................................................................................... 20
Figure-24. Sandwich Core................................................................................................................. 20
Figure-25. Sandwich Core Panel....................................................................................................... 21
Figure-26. Struts............................................................................................................................... 21

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Topic 5.2.1 – Airframe Structures – Primary Construction
Structural Assembly Techniques
As aircraft components are constructed separately, there needs to be processes that are
structurally sound to tie them all together.
The most common assembly techniques are:
Riveting
Bolting
Bonding

Figure-1. Riveting

The integrity of a helicopter joint depends upon the fasteners selected and used to secure its parts
together. However, not all helicopter joints are made using fasteners. Some joints on newer
helicopters are made with composite materials that are held together by adhesives. Although this
construction technique is gaining popularity, this method of construction will probably never
completely take the place of using fasteners in helicopter assemblies.
It is therefore important for a helicopter technician to be thoroughly familiar with the different
types of fasteners that are encountered in industry. Although this section provides general
guidelines in the selection and installation of various types of hardware and fasteners, it is always
advisable to get acquainted with the fastener manufacturer’s technical information before using
its product on a helicopter.

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Riveting
Riveting is the process of installing structural fasteners to tie structure together.
The fasteners include but are not limited to:
Solid rivets
Lockbolt fasteners
Hi-Lok fasteners
Cherry fasteners
Jo-bolt fasteners

Figure-2. Lockbolt Fastener

Figure-3. Jo-Bolt Fastener

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 Figure-4. Cherry Fastener

Figure-5. Hi-Lok Fastener

The solid shank rivet has been used since sheet metal was first utilized in aircraft, and remains the
single most commonly used aircraft fastener today. Unlike other types of fasteners, rivets change
in dimension to fit the size of a hole during installation. When a rivet is driven, the cross sectional
area increases along with its bearing and shearing strengths. Solid shank rivets are available in a
variety of materials, head designs, and sizes to accommodate different applications.
Rivet Codes
Rivets are given part codes that indicate their size, head style, and alloy material. Two systems are
in use today: the Air Force - Navy, or AN system; and the Military Standards 20 system, or MS2O.
While there are minor differences between the two systems, both use the same method for
describing rivets.
As an example, consider the rivet designation, AN47OAD4-5 the first component of a rivet part
number denotes the numbering system used. As discussed, this can either be AN or MS20. The
second part of the code is a three-digit number that describes the style of rivet head. The two
most common rivet head styles are the universal head, which is represented by the code 470, and
the countersunk head, which is rep resented by the code 426. Following the head designation is a
one- or two-digit letter code representing the alloy material used in the rivet. After the alloy code,
the shank diameter is indicated in 1/32 inch increments, and the length in increments of 1/16 inch.
Therefore, in this example, the rivet has a diameter of 4/32 inch and is 5/16 of an inch long.

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The disadvantage of riveting is that each type requires its own specialist tools to install them. E.g.
Solid rivets are installed with a rivet hammer gun and require access from both sides of the
component.

Figure-6. Riveting

Rivet Head Design
As mentioned, solid shank rivets are available in two standard head styles, universal and
countersunk, or flush. The AN470 universal head rivet now replaces all previous protruding head
styles such as AN430 round, AN442 flat, AN455 brazier, and AN456 modified brazier. AN426
countersunk rivets were developed to streamline aerofoils and permit a smooth flow over an
aircraft’s wings or control surfaces.
However, before a countersunk rivet can be installed, the metal must be countersunk or dimpled.
Countersinking is a process in which the metal in the top sheet is cut away in the shape of the rivet
head. On the other hand, dimpling is a process that mechanically ‘dents’ the sheets being joined to
accommodate the rivet head. Sheet thickness and rivet size determine which method is best
suited for a particular application.
Joints utilising countersunk rivets generally lack the strength of protruding head rivet joints. One
reason is that a portion of the material being riveted is cut away to allow for the countersunk
head. Another reason is that, when riveted, the gun set may not make direct contact with the rivet
head if the rivet hole was not countersunk or dimpled correctly, resulting in the rivet not
expanding to fill the entire hole.
To ensure head-to-gun set contact, it is recommended that countersunk heads be installed with
the manufactured head protruding above the skin’s surface about.005 to.007 inch. This ensures
that the gun set makes direct contact with the rivet head. To provide a smooth finish after the
rivet is driven, the protruding rivet head is removed using a micro-shaver. This rotary cutter shaves
the rivet head flush with the skin, leaving an aerodynamically clean surface.

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Blind Rivets
A rivet is any type of fastener that obtains its clamping action by having one of its ends
mechanically upset. Conventional solid shank rivets require access to both ends to be driven.
However, special rivets, often called blind rivets, are installed with access to only one end of the
rivet. While consider ably more expensive than solid shank rivets, blind rivets find many
applications in today’s aircraft industry.

Figure-7. Blind Rivet Gun

Hi-Lok Fasteners
Hi-Lok Fasteners are used in high strengths application and sometimes replace a solid rivet where
access is limited.
Hi-Lok bolts are manufactured in several different alloys such as titanium, stainless steel, steel,
and aluminium. They possess sufficient strength to with stand bearing and shearing loads, and is
available with flat and countersunk heads.
A conventional Hi-Lok has a straight shank with standard threads. Although wrenching lock nuts
are usually used, the threads are compatible with standard AN bolts and nuts.
To install Hi-Lok fasteners, access is required on both sides of the component. The hole is first
drilled with an interference fit. The Hi-Lock is then tapped into the hole and a locking collar is
installed. An Allen wrench holds the Hi-Lok bolt in place while a combination wrench is used to
tighten the locking collar with the attached shear nut. Once the collar is tightened to the
appropriate torque value the shear nut breaks away, leaving the locking collar in place.

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 Figure-8. Hi-lok Fastener

Bolting
Different bolt types use the same spanners, sockets and socket wrenches for installation saving on
cost for tools required. A torque wrench may be required to set the correct tension of the installed
bolt. Bolting also utilises safetying devices such as lock nuts, lock washers, split pins and lock wire
to ensure the fasteners do not become loose.
Lock bolts
Lock bolts are manufactured by several companies and conform to Military Standards. These
standards describe the size of a lock bolt’s head in relation to its shank diameter, as well as the
alloy used. Lock bolts are used to permanently assemble two materials. They are lightweight and
as strong as standard bolts.
There are three types of lock bolts used in aviation:
The pull-type lock bolt
The blind-type lock bolt
The stump-type lock bolt
The pull-type lock bolt has a pulling stem on which a pneumatic installation gun fits. The gun pulls
the materials together and then drives a locking collar into the grooves of the lock bolt. Once
secure, the gun fractures the pulling pin at its break point.

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The blind-type lock bolt is similar to most other types of blind fasteners. To install a blind-type lock
bolt, it is placed into a blind hole and an installation gun is placed over the pulling stem. As the gun
pulls the stem, a blind head forms and pulls the materials together. Once the materials are pulled
tightly together, a locking collar locks the bolt in place and the pulling stem is broken off. Unlike
other blind fasteners that typically break off flush with the surface, blind lock bolts protrude above
the surface.
The stump-type lock bolt is installed in places where there is not enough room to use the standard
pulling tool. Instead, the stump-type lock bolt is installed using an installation tool similar to that
used to install Hi-Shear rivets.
Lock bolts are available for both shear and tension applications:
Shear lock bolts:- the head is kept thin and there are only two grooves provided for the
locking collar
Tension lock bolts:- the head is thicker and four or five grooves are provided to allow for
higher tension values
The locking collars used on both shear and tension lock bolts are colour coded for easy
identification.

Figure-9. Lock Bolts

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Construction
Helicopter structures consist of doors, fuselage, vertical stabilizer, fairings, tail cone, and windows.
Doors are for entrance and exit and access to baggage compartments and fuselage structure.
Fairings can be opened or removed to get to system components.
The framework of the fuselage is of semi-monocoque construction, using the framing and skin
plating as structural members. The framing consists of longitudinal beams, longerons, and
stringers, which are supported laterally with bulkheads, frames and formers.

Figure-10. Helicopter Construction

The airframe of the helicopter covers a wide range of materials, mainly due to the advances in
technology that have taken place in recent years. For the most part, the materials used in
helicopter construction are the same as those used on fixed-wing aircraft.

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Tubular Construction
Some of the early helicopters used the typical tubular-truss fuselage construction. Although this
construction type had a high strength-to-weight ratio, manufacturing such an airframe was quite
costly. Each tube was cut, fitted, and welded into place. In addition to these disadvantages, it was
difficult to hold dimensions to a close tolerance. The big advantage of this type of construction
was the way in which it could be repaired in the field; unless there was severe airframe damage,
which would require jigging in order to hold alignment. The criteria for these repairs are all
contained in the maintenance manual and the FAA’s AC43.13.

Figure-11. Tubular Construction

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Sheet Metal Construction
At the same time, several of the manufacturers went to aluminium structures. These were of
monocoque and semi-monocoque design. This construction type had a high strength-to-weight
ratio. In fact, the ratio was higher than the tubular construction of the same size. Sheet metal
construction had some advantages in the manufacturing process. Parts could be stamped out and
compound curves made rapidly. Helicopters could be constructed in jigs with closer tolerances
than those of the tubular fuselage construction. In the field, few additional tools were required for
repairs. In general, the structure was slightly more delicate. If large repairs were required, the
fuselage required jigs to obtain proper alignment for the various sections. A few helicopters are
built using a combination of the sheet metal construction and the tubular construction. Tubular
design is used in areas where high strength is required. Sheet metal is used when the strength
requirements are not as critical.

Figure-12. Sheet Metal Construction

Stressed Skin Fuselage
The basic structure of the helicopter varies somewhat from that of a fixed-wing aircraft, although
they both use the same construction techniques. This is due to the loads and stresses that are
placed on the airframes in different locations. It is these differences that should be understood by
helicopter maintenance personnel in order to inspect and repair the helicopter airframe properly.
The next advance in structural designs came with the development of a construction technique
that allowed the helicopter to be formed without a truss frame. This design, generally known as a
stressed-skin structure, allowed the helicopter to be built with a more streamlined shape and
provided further reductions in weight because the skin itself carried the structural loads. When
constructed in this fashion, the helicopter was referred to as having a monocoque design.

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The term monocoque is derived from the French meaning ‘single-shell’. Thin aluminium-alloy
sheets are used for the exterior of monocoque stressed-skin structures. These sheets have
compound curves formed in them by using hydro presses or drop hammers. The formed skins
were then riveted onto thin sheet metal formers.
The designs provided a lightweight and reasonably durable structure that manufacturers used for
many years. In fact, many aircraft constructed in this manner remain in service today. A
disadvantage of monocoque designs is that they can fail once subjected to relatively minor dents
or creases.
To further increase the strength of the structure, manufacturers improved their designs by
developing semi-monocoque construction techniques. In these helicopters, the skin is fastened to
a sub-structure or skeletal framework, which allows the loads to be distributed between the
structural components and the skin of the helicopter. These designs proved to be so successful
that they continue to be the primary method of modern helicopter construction.
Bonded Construction
The third type of construction is the use of fibreglass, honeycomb, and bonded structures. All of
these materials and methods are of high strength-to-weight ratios. Honeycomb and bonded
structures have reduced construction costs by eliminating some of the riveting and welding. Today
most airframes are a combination of various materials and methods of construction obtaining the
greatest advantages of each.
Composite Materials and Adhesives
Some joints on newer helicopters are made with composite materials that are held together by
adhesives. The function of the matrix in a composite is to hold the reinforcing fibres in a desired
position. It also gives the composite strength and transfers external stresses to the fibres. The
ability of the matrix to transfer stress is the key to the strength of a composite structure. A wide
range of resin systems are used for the matrix portion of fibre reinforced composites. Resin is an
organic polymer used as a matrix to contain the reinforcing fibres in a composite material.
Polyester resin, an example of an earlier matrix, used in conjunction with fibreglass has been used
in many non-structural applications such as fairings and spinners, The old polyester/fibreglass
formulas did not offer sufficient strength to fabricate primary structural members. Newer matrix
materials display remarkably improved stress distributing characteristics, heat resistance, chemical
resistance, and durability. Resin matrix systems are a type of plastic and include two general
categories: thermoplastic and thermosetting.
Thermoplastic and thermosetting resins by themselves do not have sufficient strength for use in
structural applications. However, plastic matrixes reinforced with other materials form high-
strength, lightweight structural composites.
Some materials used, like epoxy resins, require to be applied in a temperature and humidity
controlled environment using expensive heating and vacuum pressure equipment to cure. The
components also need to be extremely clean for the adhesives/resins to stick.

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The illustration below is of an F111 upper wing surface. The boron patch was fitted to the wing to
strengthen the structure to prevent cracking of the main spar which is attached to the skins
through bolting and riveting.

Figure-13. Boron Patch

In order to minimise the weight in the Tiger helicopter, approximately 80% of the airframe is
constructed of composite materials. The frames and beams have been fabricated from Kevlar and
carbon laminates. Panels are composed of Nomex honeycomb material with carbon and Kevlar
skins. The helicopter blades are of fibre composite construction. Radar reflective structures and
surfaces have been minimised. Low infra-red reflection paints have been used and an infra-red (IR)
suppressor has been fitted to the engine exhaust.

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The self-sealing tanks are equipped with an inert gas system to avoid the danger of an explosive
fuel vapour and air mix. The engines are separated by armour plate to prevent the loss of both
engines in the event of a single direction hit. The helicopter has nuclear, biological and chemical
warfare (NBC) and nuclear electromagnetic pulse protection.

Figure-14. Bonded Construction

Body Structure
The body structure is the main structural member of the fuselage. It not only carries the lift and
thrust loads, but also the landing loads. The body structure supports all other members of the
fuselage either directly or indirectly. All the forces applied to these other members will be
transmitted to the body structure. In actuality; the body structure is a reinforced box with ‘X’
members placed in each side. The transmission assembly, which is connected to the main rotor
and absorbs the compression loads of landing, is attached to the bottom of the box. In the middle
of this structure is placed the fuel tanks, which should be in the most protected area of the
helicopter.
Bottom Structure
Attached to the body structure on the front of the box is the bottom structure and cabin floor.
This section is made of two cantilevered beams extending from the box that are connected to the
cross members of the box. These two beams will actually carry the weight of the cabin and
transmit it to the box. Cross members are added to these two beams to support the floor and the
lower skin panels. The cabin section attaches directly to the floor.
Cabin Section
The canopy, or cabin section, is made almost exclusively from synthetic materials. This portion is
made of subassemblies which are the cabin roof; nose, and vertical members. All of the
components are made of polycarbonate reinforced with glass fibres. They are heat moulded and
assembled by banding and ultrasonic spot welding. The canopy frame is then bolted to the cabin
floor and the body bulkhead. Added to this frame are the upper windows, windshields, and lower
window; which are all made of polycarbonate. The transparent polycarbonate is known for its
superior strength properties.

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Rear Section
The rear section of the fuselage connects to the body section. The rear section is made of three
frames connected by beams to the body section. This frame, covered with a stainless steel
firewall, acts as an attachment point for the engine. The inside of this section acts as a baggage
area. The tail boom section is bolted to the rear frame.
Formers
Formers give the fuselage or wing its shape and the skin is attached to the outside. A series of
frames in the shape of the fuselage cross sections are held in position on a rigid fixture. These
frames are then joined with lightweight longitudinal elements called stringers. These are in turn
covered with a skin of sheet aluminium, attached by riveting or by bonding with special adhesives.

Figure-15. Formers

Bulkheads
Are used as structural partitions to divide the fuselage or wings into bays or compartments, and
provide additional strength as well as giving the fuselage shape.

Figure-16. Bulkheads

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Longerons
Longerons give a helicopter capability to carry heavy loads longitudinally. Longerons tie frames
together and provide strength to cockpit construction.

Figure-17. Longerons

Stringers
Stringers give the fuselage its longitudinal strengths. They connect the frames (formers) and are
joined to the skin. Stringers are manufactured by forming sheet metal into strong cross-sectional
shapes or by using extruded aluminium alloy.

Figure-18. Stringers

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Doubler
A doubler is a piece of metal used to strengthen skin structure where a component is attached.
Doublers are also used as strengthening repair plates, either on their own or in conjunction with a
patch. Any repair shall be done as per the helicopter’s Structural Repair Manual (SRM).

Figure-19. Doubler

Beams
Beams are long structural members in any structure that support/carry loads in bending and
shear.

Figure-20. Beams

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Floor Structure
The floor structure of a helicopter consists of a network of longerons and floor beams. The
longerons within the floor structure of the passenger cabin often incorporate the seat tracks.
Flooring panels are fitted on top of the longerons and beams. They are generally manufactured
from composite sandwich constructed materials. The underfloor structure often accommodates
an uninterrupted passage for control cable runs and fluid lines.

Figure-21. Floor Structure

Methods of Skinning: - Metal
Helicopters are fitted with formed metal skins for extra strength and less weight.

Figure-22. Skinning: - Metal

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Methods of Skinning: - Composite
As technology progressed, composite fibre skins were introduced to aircraft in positions where the
strength of formed metal skins was not required.
Composite fibre skins are manufactured by impregnating a fibre (glass, carbon/graphite, Kevlar)
with a resin and allowing it to cure.
Multiple layers of fibre are impregnated and glued together with a resin matrix, to form a thick
fibre skin.

Figure-23. Fibreglass Laminate

Methods of Skinning: – Sandwich Core
Another method used to obtain strength from composite skins is by bonding a thinner fibre or
metal skin to a honeycomb core.

Figure-24. Sandwich Core

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This type of skinning is generally used for removable doors and panels as a high strength low
weight alternative to thick metal or fibre composite skins.

Figure-25. Sandwich Core Panel

Struts
Struts are compression resistant member which prevents crushing. Sponson to fuselage struts on a
helicopter resists both compression and tension loads. The attached undercarriage strut resists
compression loads.

Figure-26. Struts

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Topic 12.5.2.2 – Airframe Structures – Secondary Construction

Table of Contents
List of Figures....................................................................................................................................... 3
Topic 5.2.2 – Airframe Structures – Secondary Construction....................................................... 4
Undercarriage...................................................................................................................................... 4
Skids..................................................................................................................................................... 5
Wheeled Landing Gear.................................................................................