CASAModB07b_MaintenancePracticesGeneralB07bSR20240606_sml.pdf

Transcript

MODULE 07

Category B1 and B2 Licences

CASA B-07b
Maintenance Practices -
General
 Copyright © 2024 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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 Knowledge Levels
Category A, B1, B2 and C Aircraft Maintenance Licence

Basic knowledge for categories A, B1 and B2 are indicated by the allocation of knowledge levels indicators (1, 2
or 3) against each applicable subject. Category C applicants must meet either the category B1 or the category
B2 basic knowledge levels.

The knowledge level indicators are defined as follows:

LEVEL 1

Objectives:

The applicant should be familiar with the basic elements of the subject.
The applicant should be able to give a simple description of the whole subject, using common
words and examples.
The applicant should be able to use typical terms.

LEVEL 2

A general knowledge of the theoretical and practical aspects of the subject.

An ability to apply that knowledge.

Objectives:

The applicant should be able to understand the theoretical fundamentals of the subject.
The applicant should be able to give a general description of the subject using, as appropriate,
typical examples.
The applicant should be able to use mathematical formulae in conjunction with physical laws
describing the subject.
The applicant should be able to read and understand sketches, drawings and schematics
describing the subject.
The applicant should be able to apply his knowledge in a practical manner using detailed
procedures.

LEVEL 3

A detailed knowledge of the theoretical and practical aspects of the subject.

A capacity to combine and apply the separate elements of knowledge in a logical and comprehensive manner.

Objectives:

The applicant should know the theory of the subject and interrelationships with other subjects.
The applicant should be able to give a detailed description of the subject using theoretical
fundamentals and specific examples.
The applicant should understand and be able to use mathematical formulae related to the subject.
The applicant should be able to read, understand and prepare sketches, simple drawings and
schematics describing the subject.
The applicant should be able to apply his knowledge in a practical manner using manufacturer's
instructions.
The applicant should be able to interpret results from various sources and measurements and
apply corrective action where appropriate.

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 Table of Contents
Workshop Practices (7.2) 17
Learning Objectives 17
Standards of Workmanship 18
Workmanship 18
Standards of Workmanship 18
Tool Control 20
Care of Tools 20
Tool Control 21
Tool Control and Foreign Object Damage 23
Individual Toolboxes 24
Shadow Boards 25
Tool Identification 26
Tool Inventory 27
Missing Tool Reporting 28
Workshop Practices 30
Workshop Materials 30
Material Storage 30
Dimensions, Tolerances and Allowances 33
Dimensions 33
Sheet Metal Working 33
Precision Cylindrical Parts 34
Tolerances and Allowances 34
Calibration Standards 36
Precision Tools and Test Equipment 36
Measuring Equipment 36
Torque Wrenches 36
Pressure Gauges and Transmitters 37
Micrometers 37
Calibration Tags 38
Common Hand Tools I (7.3.1) 40
Learning Objectives 40
Summary 40
Hammers 41
The Hammer 41

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 Ball Pein Hammers 41
Cross Pein 42
Straight Pein 42
Sledgehammers 43
Panel or Body Hammers 43
Special Purpose Hammers 44
Slide Hammer 46
Hammer Safety 46
Punches 48
The Punch 48
Mushrooming 48
Prick Punches 49
Centre Punches 50
Starter Drift and Pin Punches 51
Letter and Figure Punches 53
Holding Tools 54
Pliers 54
Multi-Grips 54
Vise-Grip Locking Pliers 55
Duckbill Pliers 55
Lockwire Pliers/Safety Wire Pliers 56
Needle Nose Pliers 56
Circlip Pliers 57
Chisels 59
Cold Chisels 59
Files 60
Files and Filing 60
File Characteristics 61
File Types and Profiles 63
Sheet Metal Shears 68
Aviation Snips 68
Cutting Pliers 68
Common Hand Tools II (7.3.1) 70
Learning Objectives 70
Summary 70
Hacksaws 71
The Hacksaw 71

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 Types of Hacksaws 71
Hacksaw Blades 73
Use of the Hacksaw 77
Drills (Part 1) 80
Twist Drill Bits 80
Twist Drill Sizing 83
Twist Drill Materials 85
Drill Speed and Feed 87
Centre Punching and Centre Drilling 89
Drills (Part 2) 92
Standard Drill 92
Drill Shanks 94
Countersinking Tools 94
Straight-Fluted Drills 96
Step Drills 97
Centre, Combination or Slocombe Drill 98
Special Drills 99
Countersink Drills 100
Counterbores 101
Tank Cutters and Hole Saws 102
Drill Usage 105
Sharpening Twist Drills 105
Drill Grinding Machines 105
Marking Out For Drilling 106
Drilling Thin Sheet and Point Alteration 108
Twist Drill Faults, Causes and Remedies 110
Holding Work for Drilling 114
Machine Vice 115
Clamping Plates 115
Vee Blocks 117
The Vee Block 117
Angle Plates 118
Reamers 121
The Reamer 121
Reaming Practices 125
Thread Cutting 128
Internal Screw Thread Cutting Taps 128

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 Preparing and Cutting Threads 129
Cutting Internal Threads 131
Tap Breakage 132
External Screw Thread Cutting Dies 133
Cutting External Threads (Using Circular Die) 136
Die Nuts 136
Tap and Die Precautions 137
Common Hand Tools III (7.3.1) 138
Learning Objectives 138
Summary 138
Screwdrivers 139
The Screwdriver 139
Recessed Screw Heads 139
Ratchet Screwdrivers 141
Pump Action Screwdrivers 141
Offset Screwdriver 142
Use and Selection of Screwdrivers 142
Tri-Wing 144
Pozidriv 144
Torx 145
Jewellers’ Screwdrivers 145
Other Screw Bit Types 146
Spanners 147
The Spanner 147
Spanner Sizing Systems 148
Types of Spanners 149
Socket Spanners and Drive Accessories 153
Handles and Adapters 156
Other Common Hand Tools 159
Crowfoot Spanner 159
C-Spanner and Adjustable C-Spanner 159
Peg Spanners 159
Strap Wrench 160
Allen Key 160
Spanner Selection 161
Broken Tap, Bolt and Stud Removal 163
Broken Taps 163

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 Punch Method 163
Metal Disintegrator 163
Broken Bolts and Studs 164
Screw Extractors 164
Thread Penetrants 166
Clamps and Vices 167
The Vice 167
Vice Precautions 169
Vice Jaws 169
Clamps 172
Power Tools (7.3.2) 176
Learning Objectives 176
Tool Safety 177
Power Tool Work Practices 177
Hand Tool Misuse 177
Spark-Resistant Tools 178
Power Tool Safety 180
Safe Work Practices 180
Safety Guidelines 180
General Safety Precautions 181
Electric Power Tools Safety Precautions 182
Power Tool Accessory Precautions 183
Powered Abrasive Wheel Tools 184
Portable Drills 185
Bench Grinders 187
The Bench Grinder 187
Abrasive or Grinding Wheels 188
Grinding Wheel Inspection 188
Grinding Wheel Speed 189
Grinding Wheel Direction of Rotation 190
Abrasive Wheel Grinding Conditions 191
Grinding Wheel Loading 192
Grinding Wheel Glazing 193
Grinding Wheel Grooving 194
Dressing and Truing the Grinding Wheel 196
Selecting a Fixed Grinder 198
Protective Equipment (Grinding) 198

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 Grinding Operations 199
Grinding Small Work 201
Sharpening Cutting Tools 202
Drilling Machines 204
Bench Drill 204
Upright (Column) Drill Press 204
Drill Speeds 206
Drill Feeds 208
Drill Lubricants 208
Drilling Procedures 209
Electric Power Tools 211
Electric Power Tools (Wired and Cordless) 211
Bandsaws 211
Hand Grinders 212
Electric Nibblers and Jigsaws 214
Pneumatic Power Tools 215
Pneumatic Tools (Compressed Air Tools) 215
Compressed Air Supply 216
Air Hose 217
Compressor System Care 218
The Riveting Gun and Set 221
The Rivet Gun 221
Squeeze Riveting 222
Soldering Irons 224
The Soldering Iron 224
Soldering Stations 224
Aircraft Maintenance Measuring Tools (7.3.3) 226
Learning Objectives 226
Torque Mechanics 227
Definition of Torque 227
Torque Loading 228
Torque Wrenches 230
The Torque Wrench 230
Deflecting Beam Type Wrench 230
Deflecting-Beam Dual Indication Type Wrench 230
Break-Over Type Wrench 231
Torsion Bar Torque Wrench 231

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 Torque Wrench Use 232
Calibration of Torque Wrenches 232
Torque Loading Techniques 232
Torque Load Tables 234
Progressive or Step Torquing 234
Pattern Torquing 235
Torque Multipliers 235
Torque Wrench Extensions 236
Torquing Considerations 239
Useful Conversions 239
Checking a Torque Wrench Prior to Use 240
Other Methods of Obtaining a Desired Preload 240
Calibration Requirements 242
Measuring Tools 244
Common Measuring Tools 244
Mark-Out Tools 245
Straight Edge 246
Engineer’s Square 247
Bevel Protractor 248
Inclinometer 249
Feeler Gauge 250
Micrometers 252
The Micrometer 252
Micrometer Construction 253
Using a Micrometer 255
Checking and Adjusting the Micrometer 257
Precautions for Using and Caring for a Micrometer 258
Standard English Micrometer 259
English Vernier Micrometer 261
Metric Micrometer 263
Metric Vernier Micrometer 265
Electronic Micrometers 265
Internal Micrometer 266
Depth Micrometer 268
Specialist Micrometers 270
Vernier Slide Caliper 275

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 Reading Scales 277
Reading an Imperial Vernier Scale 277
Reading a Metric Vernier Scale 278
Vernier Height Gauge 280
Other Measuring Devices 282
Introduction to Other Measuring Devices 282
Dial Indicators 282
Dial Test Indicators 284
Bore Gauges 285
Digital Instruments 286
Go/No-Go Gauges 287
Lubrication Equipment and Methods (7.3.4) 289
Learning Objectives 289
Aircraft Lubrication Equipment 290
Aircraft Servicing 290
Aviation Lubricants 290
Lubricant Properties 291
Types of Lubricating Oil 292
Fluid Servicing Equipment 294
Aircraft Lubricating Grease 296
Widely Used Airframe Lubrication Greases 297
Lubricant Methods of Application 300
Grease Lubrication Equipment 302
Grease Guns 304
Penetrants and Inhibitors 307
Anti-Seize Compounds 308
Engineering Drawings, Diagrams and Standards (7.5) 310
Learning Objectives 310
Engineering Drawing Symbols 311
Electromechanical Valve Symbols 311
Hydraulic and Pneumatic Symbols 311
Electrical Symbols 312
Welding Symbols 313
Types of Drawings 314
Engineering Drawings 314
Working Drawings 314

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 Exploded Views 319
Sectional Drawings 320
Block Diagrams 323
Logic Flow Charts 324
Electrical Wiring Diagrams 325
Schematic Diagrams 326
Pictorial Diagrams 327
Methods of Illustrating 329
Introduction to Methods of Illustrating 329
Orthographic Projection 329
Isometric Drawings 330
Oblique Drawings 330
Allowance and Tolerance 331
Tolerance 331
Allowance 332
Title Blocks 335
Engineering Drawing Title Block 335
Drawing Number 335
Scale 336
Size 336
Tolerances 337
Bill of Material 337
Application 338
Notes 338
Revision Block 339
Zones 340
Dimensioning 341
Dimensions 341
Placement of Dimensions 341
Manufacturer’s Publications 343
Aircraft Maintenance Manual 343
Power Plant Manuals 344
Illustrated Parts Catalogue 345
Overhaul Manual 346
Wiring Manuals 346
Structural Repair Manuals 347
Service Bulletins and Notes 347

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 Aircraft Maintenance Manual Storage 348
Microform and Microfiche 348
Aircraft Manual Digital Formats 350
ATA Specification 100 353
ATA Specification 353
Manual Arrangement and Numbering Systems 354
List of Chapters 356
Aviation Standards in Aircraft Maintenance 359
International Standards and ISO 359
Airworthiness Standards 359
AN Specifications 361
MS Specifications 361
NAS Specifications 361
MIL Specifications 361
NSO Specifications 361
Fits and Clearances (7.6) 363
Learning Objectives 363
Drill Bits and Sizes 364
Drill Bits 364
Drill Sizing 364
Jobber-Length Drill 368
Aircraft Length Drill 368
Centre Drill Bit Sizes 369
Bolt Tolerance 370
Classes of Fit 373
Fits 373
Clearance Fits 373
Interference Fits 374
Transition Fits 376
List of Assembly Fits 376
Aircraft Engine Assembly 377
Fit Tolerances and Allowances 379
Tolerances of Size 379
Fit Definitions 380
Effects of Limits on Allowance 382
Calculating Tolerances 383

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 Methods of Expressing Tolerance 384
Calculating Clearances 385
Acceptable Component Limits 386
Press / Interference Fits 387
Force Fits 388
Shrink / Freeze Fitting 389
Inspecting for Maintenance Limits 393
Part Limits 393
Inspection Methods 394
Springs (7.10) 396
Learning Objectives 396
Inspection and Testing 397
Inspection Requirements 397
Testing Methods 397
Bearings (7.11) 400
Learning Objectives 400
Bearing Defect Identification 401
Bearing Maintenance 401
Brinelling 401
Spalling 403
Galling 404
Flaking 405
Wear 406
Rust and Corrosion 407
Electrical Pitting 408
Burnishing 409
Cracking 410
Rolling Path Skewing 411
Damage to Retainers 411
Peeling 412
Fretting and Fretting Corrosion 413
Smearing 414
Speckles and Discolouration 415
Bearing Inspection and Testing 417
Inspecting Plain Bearings 417
Inspecting Rolling Element Bearings 417
De‑magnetising 417

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 Bearing Cleaning 419
Bearing Inspection 421
Testing Bearings 422
Lubrication 424
Introduction to Lubrication 424
Lubricant Selection 424
Grease 424
Oil 427
Storage of Bearings 430
Introduction to Storage of Bearings 430
Short-Term Storage 430
Long-Term Storage 430
Transmissions (7.12) 432
Learning Objectives 432
Gears 433
Gear Wear and Inspection 433
Gear Backlash 439
Gear Wear Patterns 440
Pulleys 444
Introduction to Pulleys 444
Pulley Inspection 444
Chains 447
Introduction to Chains 447
Chain Inspection 449
Sprockets 452
Introduction to Sprockets 452
Idler Sprocket 452
Sprocket Inspection 453
Belts 455
Introduction to Belts 455
Belt Drive Inspection 456
Screw Jacks 459
Introduction to Screw Jacks 459
The Worm and Peg Mechanism 459
The Worm and Nut Mechanism 460
The Recirculating Ball Mechanism 460
Screw Jack Inspection 461

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 Control Rods 463
Introduction to Control Rods 463
Push-Pull Rod Inspection 464
Bell Cranks 467
Introduction to Bell Cranks 467
Aircraft Control Cables (7.13) 469
Learning Objectives 469
Cable Systems 470
Introduction to Cable Systems 470
Cable Construction 470
Cable Termination 473
Cable Inspection 477
Cable Installation Practices 482
Travel Adjustment and Cable Tension 486
Turnbuckle Locking 489
Bowden and Teleflex Control Cables 492

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 Workshop Practices (7.2)
Learning Objectives
7.2.1.1 Describe in detail the correct care of tools in the workshop (Level 3).
7.2.1.2 Describe in detail the correct control of tools in the workshop (Level 3).
7.2.1.3 Describe in detail the correct use of workshop materials (Level 3).
7.2.2.1 Analyse dimensions (Level 3).
7.2.2.2 Analyse allowances (Level 3).
7.2.2.3 Analyse tolerances (Level 3).
7.2.2.4 Describe in detail standards of workmanship (Level 3).
7.2.3.1 Describe in detail the calibration of tools and equipment (Level 3).
7.2.3.2 Analyse calibration standards (Level 3).

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 Standards of Workmanship
Workmanship
Workmanship is the degree of skill with which a product is made or a job done.

Within the aircraft maintenance environment, it is a term that takes into account the following
factors:

The art of skill of a worker.
The quality of the product.
The product or result of the labour and skill of a worker.
Attitudes of the AME, team and organisation.
Duty of care (self).
Duty of care (others).
Duty of care (equipment).
Working done according to a standard.

Workmanship is important for an AME - people put their lives in the
hands of AME's every time they fly

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 Standards of Workmanship
Standards are so much a part of our daily routine that we use them without even being aware of
doing so, and without giving thought to how they are created or the benefits they provide.

A standard is an agreed way of doing something. It can be recorded and published formally, or may
simply be a company's informal unwritten procedure.

Standards provide benefits to business and to individuals, by defining accurate measurements and
lowering production costs; improving product performance, quality, uniformity, interoperability and
functionality; and providing a method to improve health, safety, the environment, communications,
competition, international trade, and improving the quality of life.

Examples of standards may be one of the following types:

Private standards are only used by the organisation that developed them.
National standards (e.g. Australian Standards [AS]) are produced by a country's National
Standards Body (NSB). In Australia, standards are developed together with industry,
government and society. Most standards are enforced by regulation and some are voluntary.
International standards are produced by the International Organisation for Standardisation
(ISO), whose members are the national standards bodies of countries all over the world.

Documented standards consult several stakeholders

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 Tool Control
Care of Tools
Tools are designed to make a job easier and enable you to work more efficiently. If they are not
properly used and cared for, their advantages are lost to you. Regardless of the type of work to be
done, you must have, choose and use the correct tools in order to do your work quickly, accurately
and safely. Without the proper tools and the knowledge of how to use them, you waste time, reduce
your efficiency and may even injure yourself or others.

Tools are expensive and vital equipment. When the need for their use arises, common sense plus a
little preventative maintenance prolongs their usefulness.

Tool control

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 In general, the following precautions for the care of tools should be observed:

Use each tool only for the job it was designed to do. Each type of tool has a specific purpose. If
you use the wrong tool when performing maintenance or repairs, you may damage the
equipment you are working on or the tool itself. Remember: Improper use of tools results in
improper maintenance. Improper maintenance results in damage to equipment and possible
injury or death to you or others.
Never leave tools scattered about. Always avoid placing tools on or above machinery or on
electrical equipment. Never leave tools unattended where machinery or aircraft engines are
running. When they are not in use, stow them neatly on racks or in toolboxes.
Never use damaged tools. A battered screwdriver may slip and spoil the screw slot, damage
other parts or cause painful injury. A gauge strained out of shape results in inaccurate
measurements.
Clean tools after each use. Oily, dirty and greasy tools are slippery and dangerous to use.
Conduct a thorough inventory of tools after use to prevent loss.

Remember: The efficiency of aircraft maintenance engineers and the tools they use is determined to
a great extent by the way they keep their tools. Likewise, you will be frequently judged by the manner
in which you handle and care for your tools; anyone watching will notice the care and precision with
which you use the tools of your trade.

The care of hand tools should follow the same pattern as for personal articles, that is, always keep
hand tools clean and free from dirt, grease and foreign matter. After use, return tools promptly to
their proper place in the toolbox. Improve your own efficiency by organising your tools so that those
used most frequently can be reached easily without digging through the entire contents of the box.
Avoid accumulating unnecessary junk.

Tool Control
It is a matter of fact – tool control affects safety. When a tool is misplaced on the job, the
repercussions can be as minor as investing the dollars to replace it, or as major as the permanent
damage that occurs to an engine or aircraft. However, what about the safety risk?

The National Aerospace FOD Prevention Inc. estimates the cost of foreign object damage (FOD) to
the global aerospace industry at $4 billion annually. These dollars are spent largely repairing aircraft
engine damage caused by the ingestion of foreign objects from runways.

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 Realising this, in an effort to prevent the problem of FOD caused by misplaced tools and the possible
cost involved, most aircraft maintenance organisations establish and enforce a Tool Control Program.
Tool control procedures are governed by the organisation’s Maintenance Organisation Exposition
(MOE), which must be approved in accordance with the CASR 42, 145 and 145 MOSs. The MOE must
detail all management procedures for tooling, distribution and return of tooling after use. The issue of
tools includes:

Record of user;
Location of use; and
Verification that the aircraft or component is clear of all tools after completion of maintenance.

Aviation Australia utilises a shadow-board-and-tool-tag tool control system whereby instructors and
trainees are issued a number of ‘tool tags’ and a tag is placed on the ‘shadow’ when a tool is removed.
Once the trainee is finished using the tool, it is placed back on the shadow board and the tag is
retrieved. Like all good systems, it relies on the honesty and integrity of the workforce to make it a
success. The goals of a Tool Control Program are as follows.

Objective
The primary objective of a tool control program is the safety of personnel and the prevention of
aircraft damage which may result from:

Lost tools;
Damaged hardware; and
Miscellaneous rubbish.

Responsibility
The primary responsibility for the control of tools is with the user. Management should ensure
adequate procedures are in place to assist with the control of company and personal tools:

Area control;
Tool identification; and
A FOD critical zone/area.

Area Control Helps Tool Control
Areas where work controls are implemented should be designated by:

Appropriate signs;
Floor striping and access;
Limitations on personnel required to perform tasks; and
A system accounting for all items entering or removed.

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 Identification of Tools
Only tools that have been permanently identified should be allowed or used in a tool control area.
This may include colour coding, engraving or other prominent markings.

© Aviation Australia
Tool order and placement

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 Tool Control and Foreign Object Damage
FOD Critical Zones/Areas
Be aware of where you are working. For example, are you working on or near flight controls or engine
controls or near engine inlets? Will misplaced tools be a hazard to the safe operation of the aircraft?

Control in FOD Critical Areas
All items taken into FOD critical areas must be accounted for. Employees’ personal tools should be
documented on a tool list, and tools should be transported in a bag or small case.

Whether you use tools from a tool board or operate from your own toolbox, a Tool Control Program
should be designed and implemented to track tools from the minute they leave the tool board or
toolbox to the moment they are returned.

For different workplaces, the details of tool control can vary depending on the needs and parts the
workshop uses, but usually the basics remain the same.

Foreign object damage

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 Individual Toolboxes
Individual toolboxes, at a minimum, should have a method to quickly determine that all tools are
accounted for at the end of a maintenance task. This can only be done if each tool has a specific
storage location that allows for quick identification if the tool is missing. One method utilises custom
foam toolbox inserts that allow technicians to instantly see if a tool is missing. When a tool is removed
for use from its perfectly shaped resting place that matches its size, a colour (yellow or red) is
revealed beneath to signal that it is out of the toolbox. As long as the top colour of the foam (blue or
black) is visible, all tools are present. The foam can be sized to fit any toolbox, and it has the added
benefit of reducing tool damage due to improper storage.

Individual toolboxes

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 Shadow Boards
Shadow boards are one of the most popular forms of visual management tool control. Many aviation
organisations are installing shadow boards, or boards marked with the shapes of tools, to indicate
proper tool locations. The shadow board visually conveys two pieces of information:

Where the tool belongs
Whether the tool is missing from its designated location.

This at-a-glance visual indicator can be a real time saver, as it eliminates the need to search through
toolboxes, tool drawers or cabinets to find a tool. Posting the shadow board in plain sight of all who
use the tools provides immediate feedback as to the status of the tool.

Some organisations have taken the shadow board concept a step further by introducing colour-
coding. The shadow boards themselves are painted a certain colour, and a matching colour is applied
to the tools that belong on them (usually either with paint or durable tape). Typically, each work area
is assigned a dedicated colour for its shadow board and tools. One area, for example, may have blue
colour-coded tools, another red colour-coded tools and yet another black colour-coded tools. In such
a system, it is easy to see if a tool is in the wrong location because a black tool on a red tool board
stands out.

Photo by Cesar Carlevarino Aragon on Unsplash
Tool order and placement - shadow boards

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 Tool Identification
Some maintenance organisations require employees to permanently mark their tools for
identification purposes. This provides a way to quickly identify a tool’s owner when one is found.
Tools can be marked using a Vibra Peen tool or laser etching. Some other marking methods, such as
permanent marker, may not be very effective in a hangar environment.

Tool identification - laser etching

If your company requires mechanics to mark their personal tools in a uniform method, consider the
requirement carefully. For example, it would be better to use engineers’ initials as a tool identification
marking rather than company-specific numbers such as employee numbers. If you change to another
company, these numbers will not be relevant and you may have to mark them all over again.

If employees are required to mark their personal tools, it can be useful to maintain a tool
identification log in a central location (Maintenance Control or Quality Assurance, for instance). This
log could list all the employees and the identification they are using to mark their tools. This way, if a
tool is found, the log can be referenced to find out who owns it.

Marking tools serves two purposes. First, it ensures that a found tool is returned to the owner.
Second, it helps ensure compliance with missing tool reporting. It makes employees more vigilant in
reporting missing tools instead of just going to the closest tool truck or store to buy a replacement.

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 Tool Inventory
A tool inventory should be accomplished regularly so that any missing tools can quickly be identified
and searched for before they affect the safety of an aircraft. This can be done after each work task or
at least once a day. Many aircraft maintenance organisations choose to do it at the beginning and end
of each shift.

Tool inventory

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 Missing Tool Reporting
An important part of any tool control program is a process for missing tool reporting. In order to
achieve the goal of accounting for all tools to ensure a safe product for the customer, the
maintenance culture must encourage employees to report any missing tool. This procedure should be
clear about how often tools need to be inventoried, how employees should report a missing tool and
the steps to be taken once a missing tool is reported. An important part of this is designating the
person who has the authority to release the aircraft in the event a missing tool is not found.

Missing tool reporting

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 Workshop Practices
Workshop Materials
Many types of workshop materials are available.

These include:

Greases
Oils
Solvents
Sealants
Contact cements
Paints
Paint strippers.

It is important to ensure that a Material Safety Data Sheet (MSDS) and a specification sheet are
available for all materials used in the workshop.

Workshop materials

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 Material Storage
Storage of flammable materials is an important factor when ensuring safety and maximum usage.

Flammable materials such as solvents, paints, paint strippers, contact cements, greases and oils
should be stored in an appropriate flammable storage facility when not in use.

Some materials are highly toxic, so it is vital to comply with the MSDS for individual materials. This
involves, among other things, using PPE and working in a well-ventilated environment.

Toxic materials

Many aircraft sealants require refrigerated storage to ensure they stay usable for their shelf life.

It is important to check the expiry date/shelf life before use. Failure to do so could compromise the
integrity of the job being performed.

When you have finished using the product, always ensure the container is properly sealed to enable
its re-use at a later date.

Mixed two-pack sealants need to cure completely before disposal, and then they can be disposed of
in accordance with local council/authority regulations.

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 Sealants

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 Dimensions, Tolerances and Allowances
Dimensions
Most aircraft drawings are dimensioned using a reference edge from which all dimensions are made.
There are two ways of placing dimensions on an aircraft drawing:

1. Write all dimensions perpendicular to the dimension lines.
2. Write all dimensions parallel to the bottom of the drawing (more conventional method).

Dimensions

The illustration shows a typical layout of an aircraft drawing. The nominal dimension of an aircraft
part is the size stated on the drawing.

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 Sheet Metal Working
A part fabricated from aircraft sheet metal has a maximum and a minimum allowable size. The part is
considered acceptable if its size falls within that range.

Please note that the double prime symbol (″) represents inches in drawings and dimensional
specifications.

Tolerance is the difference between the nominal dimension and the upper and lower limits of size, e.g.
if the nominal dimension is 5.300 in. and the upper and lower limits are +0.010 and -0.010 in., then
the tolerance is said to be ±0.010 in. (± means plus or minus). This tolerance can also be expressed as
0.020 in. This is the upper limit of size minus the lower limit of size (5.310 in. – 5.290 in. = 0.020 in.).

In aircraft drawings, any dimension given as a common fraction normally assumes a dimension
tolerance of ±1/64 in.

Allowance for sheet metal work is the difference between the nominal dimension of a part and its
upper limit OR lower limit. The examples below of upper limit and lower limit allowance specify the
same dimensional values as above.

Upper limit allowance: 5.300 in. + 0.010 in. – 0.000 in.

OR

Lower limit allowance: 5.300 in. + 0.000 in. – 0.010 in.

Precision Cylindrical Parts
A precision cylindrical part (e.g. close-tolerance bolt) has a maximum and a minimum allowable size.
The part is considered acceptable if its size falls within that range. However, the acceptable range is
usually much smaller for mating cylindrical parts than it is for sheet metal repairs.

Bolt tolerances

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 Tolerances and Allowances
Tolerance
Tolerance is the difference between the nominal dimension and the upper and lower limit of size, e.g.
if the nominal dimension is 0.3125 in. and the upper and lower limits are +0.0005 in. and -0.0005 in.,
then the tolerance is said to be ±0.0005 in. This tolerance can also be expressed as 0.0010 in. This is
the upper limit of size minus the lower limit of size (0.3130 in. – 0.3120 in. = 0.0010 in.).

Allowance
For fits between mating cylindrical parts, allowance is the prescribed difference between the
maximum material limits of mating parts. A maximum material limit is the limit of size that provides
the maximum amount of material for the part, e.g. the maximum limit of diameter of a bolt and the
minimum limit of diameter of its hole.

Tolerance

Allowance
Tolerance

Hole Shaft

Lower limit
Lower limit
Upper limit Upper limit

© Aviation Australia
Allowances and tolerances

If the maximum diameter of the bolt is 0.001 in. less than the minimum diameter of the hole, there is a
minimum ‘clearance’ of 0.001 in. This is a positive allowance.

If the maximum diameter of the bolt is 0.001 in. greater than the minimum diameter of the hole, there
is a maximum ‘interference’ of 0.001 in. This is a negative allowance.

Note: Tolerance, allowance and types of fit (including clearance and interference fits) are discussed in
greater depth in 7.5 and 7.6.

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 Calibration Standards
Precision Tools and Test Equipment
Aircraft maintenance organisations are required to regularly inspect and calibrate their precision
tooling and equipment.

A clear system of labelling indicates to users that the item is within the inspection or calibration
period. The label should show:

The date last tested
When the next inspection or calibration is due, and
The authorised person’s signature or stamp.

Also, a register should be maintained for all precision tooling and equipment, together with a record
of the calibrations and standards used.

Inspections and calibrations should be done in accordance with the manufacturers’ instructions
except where the organisation can show by results that a different time period is appropriate.
Usually, this involves inspections and calibrations being conducted at more frequent intervals but
rarely at less frequent intervals.

Measuring Equipment
Because accurate measurement is essential, engineers and technicians must learn to use various
measuring tools correctly and efficiently. Before using a precision measuring tool, ensure that it is
within its calibration period for required accuracy checks. (Refer to the calibration tag.)

The tool must be calibrated by an approved person or organisation and have a prescribed life limit
between calibrations.

Before use, it is necessary to ensure the tool will ‘zero’ correctly.

It is an offence in the regulated civil aviation industry to use personally owned measuring tools unless
they are maintained by an approved organisation and the aircraft operator or maintenance, repair
and overhaul (MRO) organisation agrees to the use of such measuring equipment.

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 Torque Wrenches
Torque wrenches are precision measuring tools and should be periodically checked for accuracy –
calibration. This is achieved using a torque analyser, which is a mechanical loader that applies a true
force at 90° to ensure maximum accuracy. Calibration of torque wrenches and other measuring
equipment is carried out by manufacturer-approved organisations employing certified technicians.

© Jeppesen
Torque wrenches

Pressure Gauges and Transmitters
Pressure gauges and transmitters are calibrated by hydraulic pumps which use either water or oil, or
by pressure generators that use oil or gas.

Pressure gauge tester

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 Micrometers
It is possible for a micrometer to slip out of calibration; however, most micrometers can be
recalibrated by inserting a precision block – test piece – between the anvil and the spindle. The
micrometer is then carefully calibrated by rotating the sleeve with a special wrench until its
longitudinal line exactly aligns with the zero mark on the thimble.

Note that temperature extremes during the day can affect the calibration process.

© Jeppesen
Micrometers outside

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 Calibration Tags
Upon completion of calibration checks on all precision tools, a calibration label or tag should be
attached to the tool. The label or tag should always be checked prior to using the tool.

Calibration labels

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 Common Hand Tools I (7.3.1)
Learning Objectives
7.3.1 Examine common hand tool types (Level 3).

Summary
This subtopic is part 1 of 3 introducing some of the common hand tools used in aircraft maintenance.

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 Hammers
The Hammer
Hammers include different types and weights of hammers and mallets, each with a very specific use.
Since misuse of pounding tools can result in damage to aircraft components and injury to personnel, it
is important that you always use these tools properly.

Before using any hammer or mallet, you should make sure you have the appropriate eye and face
protection. Furthermore, you should inspect the tool for any damage that could affect safety. For
example, before using a hammer or mallet, make sure the handle is secure and in good condition.
When striking a blow with a hammer, think of your forearm as an extension of the handle. In other
words, swing the hammer by bending your elbow, not your wrist. Always strike the work squarely
using the full face of the hammer. To avoid marring the work, keep the face of a hammer or mallet
smooth and free of dents.

Hammers

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 Ball Pein Hammers
The ball pein hammer ranges in weight from 28 grams (1 oz) to 1 - 1.5 kg (2–3 lb). One hammer face is
always flat, while the other is formed into the shape of a ball. The flat hammer face is used for working
metal and driving, but should not be used to drive a nail. The ball end of the hammer is typically used
to peen over rivets in commercial sheet metal work. However, this is not the method used for
securing rivets in aircraft sheet metal work.

Ball pein hammers

Cross Pein
The narrow cross pein helps gain access to limited working surfaces.

Cross pein hammer

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 Straight Pein
The straight pein has a similar form and function to the cross pein, but with a vertical rather than
horizontal edge.

Straight pein hammer

Sledgehammers
The metal head of a sledgehammer has two flat faces and is sized according to the weight of the head
without the handle. For example, the head of a 5-lb sledgehammer weighs 5 lb.

This tool is sometimes used in aircraft maintenance, typically when a lot of heavy driving force is
needed, such as when driving heavy pins and stakes.

Sledgehammer

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 Panel or Body Hammers
Body or panel hammers have large, smooth faces and are lightweight. They are specifically used to
remove small dents and to smooth (planish) or stretch sheet metal.

Planishing (from the Latin planus, "flat") is a metalworking technique that involves finishing the
surface by finely shaping and smoothing sheet metal.

Other types of body hammers include riveting, setting and stretching hammers.

Panel hammer

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 Special Purpose Hammers
There are many types of special purpose hammer. The most common in engineering workshops are
soft head/face hammers.

Soft head hammers are used:

to seat or position work for machining
to strike surfaces without damaging them
to strike full impact blows without danger from rebound.

Materials used with soft head hammers include:

brass
copper
aluminium
wood
rubber
plastic
rawhide.

Copper face rawhide hammer

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 Plastic soft faced hammer

Slide Hammer
Slide hammers are used with pullers to ‘shock’ components apart. They are common in aircraft
maintenance and range in weight from a few grams to several kilograms.

Slide hammer kit

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 Hammer Safety
Safety First
Before using any hammer:

Ensure that the head is secure and the wedge is in place.
Check the head for splits or burrs, which could allow fragments to fly.
Check that there are no splits in the handle.
Use a clean, dry cloth to wipe your hands and the handle of the hammer.
Remove any oil, grease or dampness, which can cause the handle to slip from your hand or the
striking face to slip from the work.

Top view of ball pein hammers

Caution: Never strike one hammer against another because they may shatter. Flying particles may
cause injury, especially to the eyes.

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 Punches
The Punch
Punches are hand tools that you hit with a hammer. Different punches are made:

To mark positions in work
To stamp identification marks
To drive parts that cannot be hit directly with a hammer
To cut holes in thin or soft material.

Safe use of punches depends particularly on:

Hitting them squarely
Keeping their heads free of burrs that lead to mushrooming.

Toolbox containing hammers, punches and chisels

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 Mushrooming
After a punch shank has been continuously hammered, the shank end typically deforms to the shape
of a mushroom. When this happens, the mushroom shape should be removed and returned to its
original crowned shape using a bench grinder. The crowned shape minimises the chance of the punch
splitting or chipping by allowing the hammer to hit it squarely.

Original crowned shape of a punch shank end

Mushroom due to repeated hammering on a punch shank end

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 Prick Punches
Prick punches are small, sharp-pointed punches used to transfer dimensions and locations onto sheet
metal for drilling. To mark sheet metal work, place the prick punch in the desired position and then
tap the head of the punch with a small hammer. Because prick punches scar the material and have
relatively delicate points, they should never be used to drive a pin or rivet from a hole. For example,
the witness marks may be used to locate pivot points of dividers for scribing lines or arcs.

Prick punch

Prick punch use

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 Centre Punches
Centre punches are similar to prick punches, but they are generally larger, are ground to a shallower
angle and are hit harder.

Centre punches are used to:

Make deeper witness marks on scribed lines
Locate a centre position and make it easier for a drill point to start cutting accurately in that
position
Mark relative positions of adjacent parts that have to be removed and replaced.

Automatic centre punch (left) and solid steel centre punch (right)

Centre punch use

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 Starter Drift and Pin Punches
A starter drift punch is hit hard with a hammer to jar loose taper and parallel pins.

A starter drift punch tapers towards a slightly concave end that will not spread the end of a pin.

A pin punch is hit with a hammer to drive loosened locating or locking pins, dowels and rivets out of
their holes. The ends of these punches are circular and flat.

Parallel pin punch set

Pin punch use

When working on aircraft, care must be taken not to damage the component by using steel punches
and drifts – a better choice is a soft drift material such brass, aluminium or nylon.

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 Brass (left) and Nylon (right) punches

Letter and Figure Punches
These hardened and tempered steel punches are used to stamp identifying symbols, letters or
numbers, as required, on work.

Number/letter punches

Caution: All working edges of punches should be kept sharp. All mushroomed material should be
ground off the shank end to prevent eye injury.

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 Holding Tools
Pliers
Pliers include a group of tools which have a pair of legs joined by a pivot, hinge or fulcrum pin. These
tools may have three types of joints:

Fixed
Toggle or compound
Slip.

Pliers are:

Made of high-carbon tool steel or alloy steel that is forged, machined and heat treated
Classified by type and length
Provided with handles shaped to give an efficient grip for the hand
Made with a great variety of jaw shapes designed for cutting, holding, gripping, pulling, pushing,
twisting or turning.

Pliers

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 Multi-Grips
Multi-grips pliers are used to tighten the packing gland nut around a water pump shaft. They have
several curved grooves that make up a series of interlocking joints. Furthermore, the length of the
handles allows a great deal of force to be applied to the jaws. Interlocking joint pliers are available in
lengths from around 5 in. up to about 20 in.

Multi-grips

Vise-Grip Locking Pliers
Vise-Grip is the registered trade name of the Petersen Manufacturing Company for a special
compound-action type pliers. The opening of these jaws is adjustable by a knurled screw located in
the end of the pliers’ handles. When these handles are squeezed together, compound leverage
multiplies the effort and applies a tremendous force to the jaws. A toggle action clamps the jaws
together so they will not open when the handles are released. The jaws are released by a small lever
in one of the handles.

Vise-Grip pliers come in a wide variety of lengths and jaw styles. Some are designed to hold pipes,
some to cut wire and others to pinch off hoses. Special forms of Vise-Grip pliers are made with sheet
metal bending jaws, while others are made with jaws that serve as welding clamps or C-clamps.

Locking pliers

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 Duckbill Pliers
A special type of pliers used in aviation is the duckbill pliers. These long-handled, flat-nosed pliers are
typically used to twist and help remove safety wire. The jaws of duckbill pliers have serrations to grip
safety wire, while the handles are long enough to provide a good tight grip on the wire while it is
being twisted.

Duckbill pliers

Lockwire Pliers/Safety Wire Pliers
A special tool used by aircraft engineers is the lockwire pliers. This tool combines the features of side-
cutters with those of the duckbills. Lockwire pliers have a special twister built into the handle that
quickly and efficiently twists lockwire.

To lockwire something, cut the length of wire needed and insert it into whatever is being safetied.
Cross the wire close to the head of the object being safetied and grip the ends of wire with the flat
serrated jaws. After locking the handles together, pull the knob in the pliers handle and a spiral rod in
the handle will rotate the pliers, twisting the wire. When twisting is completed and the wire is
secured, cut off the ends of the wire with the built-in cutters and put a ‘pig tail’ or curl on the end of
the wire to avoid injury to personnel.

Lockwire pliers/safety wire pliers

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 Needle Nose Pliers
Several different designs of needle nose pliers are used in aviation maintenance. Needle nose pliers
come in handy for electrical and electronic work because they are typically small enough to grip and
hold small components and wires. Some needle nose pliers have long, thin jaws that are bent at a right
angle to the handle. This allows the pliers to grip a component and hold it while keeping your hand out
of the way.

Needle nose pliers

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 Circlip Pliers
The circlip pliers shown below are used for fitting and removing circlips in assembly and maintenance
work. Some types are made to suit inside or outside circlips, and the noses can be straight or bent.

Circlip pliers

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 Chisels
Cold Chisels
Flat cold chisels are made from square or octagonal stock, ranging from 8 - 17 mm (5/16 - 11/16 in.)
across. The cutting edge of a flat chisel is forged so it is slightly wider than the shank and is ground to
an angle of approximately 70°.

To use a cold chisel, hold the cutting edge flat against the material and control the depth of the cut by
varying the angle between the chisel and the work. The cutting edge of a flat chisel is ground slightly
convex so that the greatest stress from a hammer blow is directed into the centre of the chisel. This
reduces the stresses that are transmitted to the sides of the cutting edge.

Flat cold chisel set

Cold chisels are not regularly used in aircraft maintenance as they are not suited to most aviation
maintenance tasks. In fact, most engineers probably do not have one in their toolbox and have not
used one in their careers.

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 Files
Files and Filing
Next to the chisel, the simplest cutting tool is the file. A file differs from a chisel in that it has a large
number of cutting edges or points rather than a single cutting edge. A file is pushed across a material
by hand, and as it moves, the teeth act like small chisels, removing small chips of material.

Files are generally manufactured from high-carbon steel. They are available in a variety of lengths,
sections, cuts and grades to suit almost every requirement.

A file’s large numbers of small teeth can cut softer materials. Pressure on the file makes its teeth
penetrate the surface to be filed. When the file is moved in the cutting direction, small particles are
removed from the surface being filed.

The file is one of the most commonly used tools, but as there is such a large range of types, shapes and
sizes, you must know the correct file for the job at hand.

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 Parts of a File
To obtain the best results, you should be familiar with the parts of a file:

The tang, on which a handle should always be fitted, is not hardened like the body of the file.
The heel is the portion between the tang and the teeth.
The faces are the main surfaces on which the teeth are cut.
The edges are two sides, mainly on flat files, on which teeth may or may not be cut.
The point is the end opposite the tang.
The back is the convex side of a half-round or similar file.
A safe edge is an edge on which no teeth are cut. This permits a corner to be cleaned out
without damage to adjacent faces.

Parts of a file

Files can provide either:

A roughing process to alter the size of a part by removing a considerable amount of material
A finishing process to smooth a surface without removing much material.

Flat or curved surfaces may be produced by varying the direction of the cutting motion. Both the
shape of the teeth and the number of teeth affect the surface finish obtained by filing.

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 File Characteristics
The rate of cutting and the finish given to the work are mainly determined by the depth and spacing
of the file’s cutting teeth.

Grade of Cut
The cut of the file refers to how fine its teeth are. They are defined as (from roughest to smoothest):
rough, middle, bastard, second cut, smooth, and dead smooth.

Type of Cut
Various arrangements of cutting teeth are provided to give the most satisfactory results when you
work on different metals. These arrangements are known as cuts.

Details of the more widely used cuts are as follows:

Single-cut
Double-cut
Dreadnaught (curved teeth)
Rasp.

Single-cut file has one set of parallel teeth while a cross-cut or double-cut file has a second set of cuts
forming diamond shaped cutting surfaces.

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 Cut Usages
Although there are rougher cuts, the following are the three standard cuts in regular use.

Bastard Cut
The coarse bastard grade of file removes material quickly. It is intended for roughing out.

Second Cut
The second cut grade is finer than the bastard grade. It cuts more slowly, but gives a smoother finish
to the work.

Smooth Cut
A smooth file cuts quite slowly and imparts a good finish to the work. It should be used for finishing
work.

File cuts and cut types

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 File Types and Profiles
Flat Files
The flat is the most commonly used section for general filing. In most cases, the blade is a rectangular
shape, but tapered and bellied blades are also available if required.

© Commonwealth of Australia 2009
Flat file

Hand Safe Edge Files
The only differen