Theory and Practice of Aircraft Performance » książka
Theory and Practice of Aircraft Performance
ISBN-13: 9781119074175 / Angielski / Twarda / 2016 / 704 str.
Theory and Practice of Aircraft Performance
ISBN-13: 9781119074175 / Angielski / Twarda / 2016 / 704 str.
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Textbook introducing the fundamentals of aircraft performance using industry standards and examples: bridging the gap between academia and industry
- Provides an extensive and detailed treatment of all segments of mission profile and overall aircraft performance
- Considers operating costs, safety, environmental and related systems issues
- Includes worked examples relating to current aircraft (Learjet 45, Tucano Turboprop Trainer, Advanced Jet Trainer and Airbus A320 types of aircraft)
- Suitable as a textbook for aircraft performance courses
Preface xix
Series Preface xxi
Road Map of the Book xxiii
Acknowledgements xxvii
Nomenclature xxxi
1 Introduction 1
1.1 Overview 1
1.2 Brief Historical Background 1
1.3 Current Aircraft Design Status 8
1.4 Future Trends 11
1.5 Airworthiness Requirements 14
1.6 Current Aircraft Performance Analyses Levels 16
1.7 Market Survey 17
1.8 Typical Design Process 19
1.9 Classroom Learning Process 23
1.10 Cost Implications 25
1.11 Units and Dimensions 26
1.12 Use of Semi‐empirical Relations and Graphs 26
1.13 How Do Aircraft Fly? 26
1.14 Anatomy of Aircraft 27
1.15 Aircraft Motion and Forces 30
References 36
2 Aerodynamic and Aircraft Design Considerations 37
2.1 Overview 37
2.2 Introduction 37
2.3 Atmosphere 39
2.4 Airflow Behaviour: Laminar and Turbulent 51
2.5 Aerofoil 56
2.6 Generation of Lift 64
2.7 Types of Stall 71
2.8 Comparison of Three NACA Aerofoils 72
2.9 High‐Lift Devices 73
2.10 Transonic Effects – Area Rule 74
2.11 Wing Aerodynamics 76
2.12 Aspect Ratio Correction of 2D‐Aerofoil Characteristics for 3D‐Finite Wing 79
2.13 Wing Definitions 81
2.14 Mean Aerodynamic Chord 84
2.15 Compressibility Effect: Wing Sweep 86
2.16 Wing‐Stall Pattern and Wing Twist 87
2.17 Influence of Wing Area and Span on Aerodynamics 88
2.18 Empennage 92
2.19 Fuselage 98
2.20 Nacelle and Intake 100
2.21 Speed Brakes and Dive Brakes 106
References 106
3 Air Data Measuring Instruments, Systems and Parameters 109
3.1 Overview 109
3.2 Introduction 109
3.3 Aircraft Speed 110
3.4 Air Data Instruments 122
3.5 Aircraft Flight‐Deck (Cockpit) Layout 128
3.6 Aircraft Mass (Weights) and Centre of Gravity 133
3.7 Noise Emissions 141
3.8 Engine‐Exhaust Emissions 145
3.9 Aircraft Systems 146
3.10 Low Observable (LO) Aircraft Configuration 150
References 152
4 Equations of Motion for a Flat Stationary Earth 153
4.1 Overview 153
4.2 Introduction 154
4.3 Definitions of Frames of Reference (Flat Stationary E arth) and Nomenclature Used 154
4.4 Eulerian Angles 158
4.5 Simplified Equations of Motion for a Flat Stationary Earth 161
Reference 167
5 Aircraft Load 169
5.1 Overview 169
5.2 Introduction 169
5.3 Flight Manoeuvres 171
5.4 Aircraft Loads 171
5.5 Theory and Definitions 172
5.6 Limits – Loads and Speeds 173
5.7 V‐n Diagram 174
5.8 Gust Envelope 179
Reference 183
6 Stability Considerations Affecting Aircraft Performance 185
6.1 Overview 185
6.2 Introduction 185
6.3 Static and Dynamic Stability 186
6.4 Theory 192
6.5 Current Statistical Trends for Horizontal and Vertical Tail Coefficients 197
6.6 Inherent Aircraft Motions as Characteristics of Design 198
6.7 Spinning 202
6.8 Summary of Design Considerations for Stability 203
References 207
7 Aircraft Power Plant and Integration 209
7.1 Overview 209
7.2 Background 209
7.3 Definitions 214
7.4 Air‐Breathing Aircraft Engine Types 215
7.5 Simplified Representation of Gas Turbine (Brayton/Joule) Cycle 219
7.6 Formulation/Theory – Isentropic Case 221
7.7 Engine Integration to Aircraft – Installation Effects 226
7.8 Intake/Nozzle Design 231
7.9 Exhaust Nozzle and Thrust Reverser 233
7.10 Propeller 234
References 246
8 Aircraft Power Plant Performance 247
8.1 Overview 247
8.2 Introduction 248
8.3 Uninstalled Turbofan Engine Performance Data – Civil Aircraft 250
8.4 Uninstalled Turbofan Engine Performance Data – Military Aircraft 254
8.5 Uninstalled Turboprop Engine Performance Data 255
8.6 Installed Engine Performance Data of Matched Engines to Coursework Aircraft 257
8.7 Installed Turboprop Performance Data 261
8.8 Piston Engine 264
8.9 Engine Performance Grid 267
8.10 Some Turbofan Data 272
Reference 273
9 Aircraft Drag 275
9.1 Overview 275
9.2 Introduction 275
9.3 Parasite Drag Definition 277
9.4 Aircraft Drag Breakdown (Subsonic) 278
9.5 Aircraft Drag Formulation 279
9.6 Aircraft Drag Estimation Methodology 281
9.7 Minimum Parasite Drag Estimation Methodology 281
9.8 Semi‐Empirical Relations to Estimate Aircraft Component Parasite Drag 284
9.9 Notes on Excrescence Drag Resulting from Surface Imperfections 295
9.10 Minimum Parasite Drag 296
9.11 ΔCDp Estimation 296
9.12 Subsonic Wave Drag 296
9.13 Total Aircraft Drag 298
9.14 Low‐Speed Aircraft Drag at Takeoff and Landing 298
9.15 Propeller‐Driven Aircraft Drag 304
9.16 Military Aircraft Drag 304
9.17 Supersonic Drag 305
9.18 Coursework Example – Civil Bizjet Aircraft 306
9.19 Classroom Example – Subsonic Military Aircraft (Advanced Jet Trainer) 315
9.20 Classroom Example – Turboprop Trainer 319
9.21 Classroom Example – Supersonic Military Aircraft 325
9.22 Drag Comparison 332
9.23 Some Concluding Remarks and Reference Figures 334
References 338
10 Fundamentals of Mission Profile, Drag Polar and Aeroplane Grid 339
10.1 Overview 339
10.2 Introduction 340
10.3 Civil Aircraft Mission (Payload–Range) 342
10.4 Military Aircraft Mission 345
10.5 Aircraft Flight Envelope 349
10.6 Understanding Drag Polar 351
10.7 Properties of Parabolic Drag Polar 354
10.8 Classwork Examples of Parabolic Drag Polar 363
10.9 Bizjet Actual Drag Polar 366
10.10 Aircraft and Engine Grid 372
References 378
11 Takeoff and Landing 379
11.1 Overview 379
11.2 Introduction 380
11.3 Airfield Definitions 380
11.4 Generalized Takeoff Equations of Motion 384
11.5 Friction – Wheel Rolling and Braking Friction Coefficients 389
11.6 Civil Transport Aircraft Takeoff 391
11.7 Worked Example – Bizjet 396
11.8 Takeoff Presentation 404
11.9 Military Aircraft Takeoff 405
11.10 Checking Takeoff Field Length (AJT) 406
11.11 Civil Transport Aircraft Landing 409
11.12 Landing Presentation 417
11.13 Approach Climb and Landing Climb 418
11.14 Fuel Jettisoning 418
References 418
12 Climb and Descent Performance 419
12.1 Overview 419
12.2 Introduction 420
12.3 Climb Performance 422
12.4 Other Ways to Climb (Point Performance) – Civil Aircraft 428
12.5 Classwork Example – Climb Performance (Bizjet) 435
12.6 Hodograph Plot 440
12.7 Worked Example – Bizjet 443
12.8 Integrated Climb Performance – Computational Methodology 444
12.9 Specific Excess Power (SEP) – High‐Energy Climb 447
12.10 Descent Performance 454
12.11 Worked Example – Descent Performance (Bizjet) 459
References 462
13 Cruise Performance and Endurance 463
13.1 Overview 463
13.2 Introduction 464
13.3 Equations of Motion for the Cruise Segment 466
13.4 Cruise Equations 466
13.5 Specific Range 470
13.6 Worked Example (Bizjet) 471
13.7 Endurance Equations 478
13.8 Options for Cruise Segment (Turbofan Only) 481
13.9 Initial Maximum Cruise Speed (Bizjet) 487
13.10 Worked Example of AJT – Military Aircraft 488
References 489
14 Aircraft Mission Profile 491
14.1 Overview 491
14.2 Introduction 492
14.3 Payload‐Range Capability 493
14.4 The Bizjet Payload‐Range Capability 495
14.5 Endurance (Bizjet) 502
14.6 Effect of Wind on Aircraft Mission Performance 502
14.7 Engine Inoperative Situation at Climb and Cruise – Drift‐Down Procedure 503
14.8 Military Missions 506
14.9 Flight Planning by the Operators 507
References 508
15 Manoeuvre Performance 509
15.1 Overview 509
15.2 Introduction 509
15.3 Aircraft Turn 510
15.4 Classwork Example – AJT 520
15.5 Aerobatics Manoeuvre 522
15.6 Combat Manoeuvre 528
15.7 Discussion on Turn 530
References 531
16 Aircraft Sizing and Engine Matching 533
16.1 Overview 533
16.2 Introduction 534
16.3 Theory 535
16.4 Coursework Exercises: Civil Aircraft Design (Bizjet) 541
16.5 Sizing Analysis: Civil Aircraft (Bizjet) 543
16.6 Classroom Exercise – Military Aircraft (AJT) 546
16.7 Sizing Analysis – Military Aircraft 551
16.8 Aircraft Sizing Studies and Sensitivity Analyses 553
16.9 Discussion 554
References 558
17 Operating Costs 559
17.1 Overview 559
17.2 Introduction 560
17.3 Aircraft Cost and Operational Cost 561
17.4 Aircraft Direct Operating Cost (DOC) 567
17.5 Aircraft Performance Management (APM) 574
References 577
18 Miscellaneous Considerations 579
18.1 Overview 579
18.2 Introduction 579
18.3 History of the FAA 580
18.4 Flight Test 583
18.5 Contribution of the Ground Effect on Takeoff 585
18.6 Flying in Adverse Environments 586
18.7 Bird Strikes 590
18.8 Military Aircraft Flying Hazards and Survivability 591
18.9 Relevant Civil Aircraft Statistics 591
18.10 Extended Twin‐Engine Operation (ETOP) 597
18.11 Flight and Human Physiology 598
References 599
Appendices
Appendix A Conversions 601
Appendix B International Standard Atmosphere Table 605
Appendix C Fundamental Equations 609
Appendix D Airbus 320 Class Case Study 615
Appendix E Problem Sets 627
Appendix F Aerofoil Data 647
Index 655
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