Description

Book Synopsis

Introduction to Aircraft Aeroelasticity and Loads, Second Edition is an updated new edition offering comprehensive coverage of the main principles of aircraft aeroelasticity and loads. For ease of reference, the book is divided into three parts and begins by reviewing the underlying disciplines of vibrations, aerodynamics, loads and control, and then goes on to describe simplified models to illustrate aeroelastic behaviour and aircraft response and loads for the flexible aircraft before introducing some more advanced methodologies. Finally, it explains how industrial certification requirements for aeroelasticity and loads may be met and relates these to the earlier theoretical approaches used.

Key features of this new edition include:

  • Uses a unified simple aeroelastic model throughout the book
  • Major revisions to chapters on aeroelasticity
  • Updates and reorganisation of chapters involving Finite Elements
  • Some reorganisation of load

    Trade Review

    “I strongly recommend this textbook to under­graduates and researchers, not only due to how principles and concepts are explained, but also because it clearly shows the multidisciplinary nature of modern engineering techniques.” (The Aeronautical Journal, 1 November 2015)



    Table of Contents

    Series Preface xxi

    Preface to the Second Edition xxiii

    Preface to the First Edition xxv

    Abbreviations xxix

    Introduction 1

    PART I BACKGROUND MATERIAL 7

    1 Vibration of Single Degree of Freedom Systems 9

    1.1 Setting up Equations of Motion for SDoF Systems 9

    1.2 Free Vibration of SDoF Systems 11

    1.3 Forced Vibration of SDoF Systems 13

    1.4 Harmonic Forced Vibration – Frequency Response Functions 14

    1.5 Transient/Random Forced Vibration – Time Domain Solution 17

    1.6 Transient Forced Vibration – Frequency Domain Solution 21

    1.7 Random Forced Vibration – Frequency Domain Solution 23

    1.8 Examples 24

    2 Vibration of Multiple Degree of Freedom Systems 27

    2.1 Setting up Equations of Motion 27

    2.2 Undamped Free Vibration 29

    2.3 Damped Free Vibration 31

    2.4 Transformation to Modal Coordinates 34

    2.5 Two-DoF Rigid Aircraft in Heave and Pitch 38

    2.6 ‘Free–Free’ Systems 40

    2.7 Harmonic Forced Vibration 41

    2.8 Transient/Random Forced Vibration – Time Domain Solution 43

    2.9 Transient Forced Vibration – Frequency Domain Solution 44

    2.10 Random Forced Vibration – Frequency Domain Solution 44

    2.11 Examples 45

    3 Vibration of Continuous Systems – Assumed Shapes Approach 49

    3.1 Continuous Systems 49

    3.2 Modelling Continuous Systems 49

    3.3 Elastic and Flexural Axes 51

    3.4 Rayleigh–Ritz ‘Assumed Shapes’ Method 52

    3.5 Generalized Equations of Motion – Basic Approach 53

    3.6 Generalized Equations of Motion – Matrix Approach 58

    3.7 Generating Whole Aircraft ‘Free–Free’ Modes from ‘Branch’ Modes 61

    3.8 Whole Aircraft ‘Free–Free’ Modes 64

    3.9 Examples 65

    4 Introduction to Steady Aerodynamics 69

    4.1 The Standard Atmosphere 69

    4.2 Effect of Air Speed on Aerodynamic Characteristics 71

    4.3 Flows and Pressures Around a Symmetric Aerofoil 73

    4.4 Forces on an Aerofoil 74

    4.5 Variation of Lift for an Aerofoil at an Angle of Incidence 76

    4.6 Pitching Moment Variation and the Aerodynamic Centre 77

    4.7 Lift on a Three-dimensional Wing 78

    4.8 Drag on a Three-dimensional Wing 82

    4.9 Control Surfaces 83

    4.10 Transonic Flows 84

    4.11 Examples 85

    5 Introduction to Loads 87

    5.1 Laws of Motion 88

    5.2 D’Alembert’s Principle – Inertia Forces and Couples 90

    5.3 External Loads – Applied and Reactive 94

    5.4 Free Body Diagrams 95

    5.5 Internal Loads 96

    5.6 Internal Loads for a Continuous Member 96

    5.7 Internal Loads for a Discretized Member 101

    5.8 Intercomponent Loads 103

    5.9 Obtaining Stresses from Internal Loads – Structural Members with Simple Load Paths 103

    5.10 Examples 104

    6 Introduction to Control 109

    6.1 Open and Closed Loop Systems 109

    6.2 Laplace Transforms 110

    6.3 Modelling of Open and Closed Loop Systems using Laplace and Frequency Domains 112

    6.4 Stability of Systems 114

    6.5 PID Control 121

    6.6 Examples 122

    PART II INTRODUCTION TO AEROELASTICITY AND LOADS 123

    7 Static Aeroelasticity – Effect of Wing Flexibility on Lift Distribution and Divergence 125

    7.1 Static Aeroelastic Behaviour of a Two-dimensional Rigid Aerofoil with a Torsional Spring Attachment 126

    7.2 Static Aeroelastic Behaviour of a Fixed Root Flexible Wing 130

    7.3 Effect of Trim on Static Aeroelastic Behaviour 133

    7.4 Effect of Wing Sweep on Static Aeroelastic Behaviour 137

    7.5 Examples 142

    8 Static Aeroelasticity – Effect of Wing Flexibility on Control Effectiveness 143

    8.1 Rolling Effectiveness of a Flexible Wing – Fixed Wing Root Case 144

    8.2 Rolling Effectiveness of a Flexible Wing – Steady Roll Case 147

    8.3 Effect of Spanwise Position of the Control Surface 151

    8.4 Full Aircraft Model – Control Effectiveness 152

    8.5 Effect of Trim on Reversal Speed 153

    8.6 Examples 153

    9 Introduction to Unsteady Aerodynamics 155

    9.1 Quasi-steady Aerodynamics 156

    9.2 Unsteady Aerodynamics related to Motion 156

    9.3 Aerodynamic Lift and Moment for an Aerofoil Oscillating Harmonically in Heave and Pitch 161

    9.4 Oscillatory Aerodynamic Derivatives 162

    9.5 Aerodynamic Damping and Stiffness 163

    9.6 Approximation of Unsteady Aerodynamic Terms 164

    9.7 Unsteady Aerodynamics related to Gusts 164

    9.8 Examples 168

    10 Dynamic Aeroelasticity – Flutter 171

    10.1 Simplified Unsteady Aerodynamic Model 172

    10.2 Binary Aeroelastic Model 173

    10.3 General Form of the Aeroelastic Equations 176

    10.4 Eigenvalue Solution of the Flutter Equations 176

    10.5 Aeroelastic Behaviour of the Binary Model 177

    10.6 Aeroelastic Behaviour of a Multiple Mode System 185

    10.7 Flutter Speed Prediction for Binary Systems 185

    10.8 Divergence of Dynamic Aeroelastic Systems 188

    10.9 Inclusion of Unsteady Reduced Frequency Effects 189

    10.10 Control Surface Flutter 193

    10.11 Whole Aircraft Model – Inclusion of Rigid Body Modes 199

    10.12 Flutter in the Transonic Regime 202

    10.13 Effect of Non-Linearities – Limit Cycle Oscillations 202

    10.14 Examples 204

    11 Aeroservoelasticity 207

    11.1 Mathematical Modelling of a Simple Aeroelastic System with a Control Surface 208

    11.2 Inclusion of Gust Terms 209

    11.3 Implementation of a Control System 210

    11.4 Determination of Closed Loop System Stability 211

    11.5 Gust Response of the Closed Loop System 213

    11.6 Inclusion of Control Law Frequency Dependency in Stability Calculations 214

    11.7 Response Determination via the Frequency Domain 215

    11.8 State Space Modelling 216

    11.9 Examples 217

    12 Equilibrium Manoeuvres 219

    12.1 Equilibrium Manoeuvre – Rigid Aircraft under Normal Acceleration 221

    12.2 Manoeuvre Envelope 226

    12.3 Equilibrium Manoeuvre – Rigid Aircraft Pitching 227

    12.4 Equilibrium Manoeuvre – Flexible Aircraft Pitching 235

    12.5 Representation of the Flight Control System (FCS) 250

    12.6 Examples 250

    13 Dynamic Manoeuvres 253

    13.1 Aircraft Axes 255

    13.2 Motion Variables 257

    13.3 Axes Transformations 257

    13.4 Velocity and Acceleration Components for Moving Axes in 2D 259

    13.5 Flight Mechanics Equations of Motion for a Rigid Symmetric Aircraft in 2D 262

    13.6 Representation of Disturbing Forces and Moments 265

    13.7 Modelling the Flexible Aircraft 267

    13.8 Solution of Flight Mechanics Equations for the Rigid Aircraft 272

    13.9 Dynamic Manoeuvre – Rigid Aircraft in Longitudinal Motion 273

    13.10 Dynamic Manoeuvre – Flexible Aircraft Heave/Pitch 279

    13.11 General Form of Longitudinal Equations 287

    13.12 Dynamic Manoeuvre for Rigid Aircraft in Lateral Motion 288

    13.13 Bookcase Manoeuvres for Rigid Aircraft in Lateral Motion 289

    13.14 Flight Control System (FCS) 293

    13.15 Representation of the Flight Control System (FCS) 295

    13.16 Examples 295

    14 Gust and Turbulence Encounters 299

    14.1 Gusts and Turbulence 300

    14.2 Gust Response in the Time Domain 301

    14.3 Time Domain Gust Response – Rigid Aircraft in Heave 303

    14.4 Time Domain Gust Response – Rigid Aircraft in Heave/Pitch 310

    14.5 Time Domain Gust Response – Flexible Aircraft 316

    14.6 General Form of Equations in the Time Domain 321

    14.7 Turbulence Response in the Frequency Domain 321

    14.8 Frequency Domain Turbulence Response – Rigid Aircraft in Heave 324

    14.9 Frequency Domain Turbulence Response – Rigid Aircraft in Heave/Pitch 329

    14.10 Frequency Domain Turbulence Response – Flexible Aircraft 330

    14.11 General Form of Equations in the Frequency Domain 333

    14.12 Representation of the Flight Control System (FCS) 334

    14.13 Examples 334

    15 Ground Manoeuvres 337

    15.1 Landing Gear 337

    15.2 Taxi, Take-Off and Landing Roll 342

    15.3 Landing 351

    15.4 Braking 359

    15.5 Turning 360

    15.6 Shimmy 361

    15.7 Representation of the Flight Control System (FCS) 363

    15.8 Examples 363

    16 Aircraft Internal Loads 367

    16.1 Limit and Ultimate Loads 368

    16.2 Internal Loads for an Aircraft 368

    16.3 General Internal Loads Expressions – Continuous Wing 370

    16.4 Effect of Wing-mounted Engines and Landing Gear 372

    16.5 Internal Loads – Continuous Flexible Wing 373

    16.6 General Internal Loads Expressions – Discretized Wing 379

    16.7 Internal Loads – Discretized Fuselage 384

    16.8 Internal Loads – Continuous Turbulence Encounter 387

    16.9 Loads Generation and Sorting to yield Critical Cases 388

    16.10 Aircraft Dimensioning Cases 390

    16.11 Stresses derived from Internal Loads – Complex Load Paths 391

    16.12 Examples 391

    17 Vibration of Continuous Systems – Finite Element Approach 395

    17.1 Introduction to the Finite Element Approach 395

    17.2 Formulation of the Beam Bending Element 397

    17.3 Assembly and Solution for a Beam Structure 401

    17.4 Torsion Element 406

    17.5 Combined Bending/Torsion Element 407

    17.6 Concentrated Mass Element 408

    17.7 Stiffness Element 408

    17.8 Rigid Body Elements 409

    17.9 Other Elements 410

    17.10 Comments on Modelling 411

    17.11 Examples 413

    18 Potential Flow Aerodynamics 415

    18.1 Components of Inviscid, Incompressible Flow Analysis 415

    18.2 Inclusion of Vorticity 420

    18.3 Numerical Steady Aerodynamic Modelling of Thin Two-dimensional Aerofoils 422

    18.4 Steady Aerodynamic Modelling of Three-Dimensional Wings using a Panel Method 425

    18.5 Unsteady Aerodynamic Modelling of Wings undergoing Harmonic Motion 429

    18.6 Aerodynamic Influence Coefficients in Modal Space 432

    18.7 Examples 436

    19 Coupling of Structural and Aerodynamic Computational Models 437

    19.1 Mathematical Modelling – Static Aeroelastic Case 438

    19.2 2D Coupled Static Aeroelastic Model – Pitch 439

    19.3 2D Coupled Static Aeroelastic Model – Heave/Pitch 440

    19.4 3D Coupled Static Aeroelastic Model 441

    19.5 Mathematical Modelling – Dynamic Aeroelastic Response 446

    19.6 2D Coupled Dynamic Aeroelastic Model – Bending/Torsion 447

    19.7 3D Flutter Analysis 448

    19.8 Inclusion of Frequency Dependent Aerodynamics for State–Space Modelling – Rational Function Approximation 450

    PART III INTRODUCTION TO INDUSTRIAL PRACTICE 455

    20 Aircraft Design and Certification 457

    20.1 Aeroelastics and Loads in the Aircraft Design Process 457

    20.2 Aircraft Certification Process 459

    21 Aeroelasticity and Loads Models 465

    21.1 Structural Model 465

    21.2 Aerodynamic Model 471

    21.3 Flight Control System 473

    21.4 Other Model Issues 474

    21.5 Loads Transformations 474

    22 Static Aeroelasticity and Flutter 475

    22.1 Static Aeroelasticity 475

    22.2 Flutter 478

    23 Flight Manoeuvre and Gust/Turbulence Loads 481

    23.1 Evaluation of Internal Loads 481

    23.2 Equilibrium/Balanced Flight Manoeuvres 481

    23.3 Dynamic Flight Manoeuvres 485

    23.4 Gusts and Turbulence 489

    24 Ground Manoeuvre Loads 495

    24.1 Aircraft/Landing Gear Models for Ground Manoeuvres 495

    24.2 Landing Gear/Airframe Interface 496

    24.3 Ground Manoeuvres – Landing 496

    24.4 Ground Manoeuvres – Ground Handling 497

    24.5 Loads Processing 498

    25 Testing Relevant to Aeroelasticity and Loads 501

    25.1 Introduction 501

    25.2 Wind Tunnel Tests 501

    25.3 Ground Vibration Test 502

    25.4 Structural Coupling Test 503

    25.5 Flight Simulator Test 504

    25.6 Structural Tests 504

    25.7 Flight Flutter Test 505

    25.8 Flight Loads Validation 507

    Appendices 509

    A Aircraft Rigid Body Modes 511

    B Table of Longitudinal Aerodynamic Derivatives 513

    C Aircraft Symmetric Flexible Modes 517

    D Model Condensation 527

    E Aerodynamic Derivatives in Body Fixed Axes 531

    References 535

    Index 539

Introduction to Aircraft Aeroelasticity and Loads

    Product form

    £83.55

    Includes FREE delivery

    RRP £87.95 – you save £4.40 (5%)

    Order before 4pm today for delivery by Wed 1 Jul 2026.

    A Hardback by Jan R. Wright, Jonathan Cooper, Peter Belobaba

      Trusted by thousands of customers. See 2,385+ Customer Reviews

      View other formats and editions of Introduction to Aircraft Aeroelasticity and Loads by Jan R. Wright

      Publisher: John Wiley & Sons Inc
      Publication Date: 06/02/2015
      ISBN13: 9781118488010, 978-1118488010
      ISBN10: 1118488016
      Also in:
      Technology, Engineering & Agriculture Aerospace and aviation technology

      Description

      Book Synopsis

      Introduction to Aircraft Aeroelasticity and Loads, Second Edition is an updated new edition offering comprehensive coverage of the main principles of aircraft aeroelasticity and loads. For ease of reference, the book is divided into three parts and begins by reviewing the underlying disciplines of vibrations, aerodynamics, loads and control, and then goes on to describe simplified models to illustrate aeroelastic behaviour and aircraft response and loads for the flexible aircraft before introducing some more advanced methodologies. Finally, it explains how industrial certification requirements for aeroelasticity and loads may be met and relates these to the earlier theoretical approaches used.

      Key features of this new edition include:

      • Uses a unified simple aeroelastic model throughout the book
      • Major revisions to chapters on aeroelasticity
      • Updates and reorganisation of chapters involving Finite Elements
      • Some reorganisation of load

        Trade Review

        “I strongly recommend this textbook to under­graduates and researchers, not only due to how principles and concepts are explained, but also because it clearly shows the multidisciplinary nature of modern engineering techniques.” (The Aeronautical Journal, 1 November 2015)



        Table of Contents

        Series Preface xxi

        Preface to the Second Edition xxiii

        Preface to the First Edition xxv

        Abbreviations xxix

        Introduction 1

        PART I BACKGROUND MATERIAL 7

        1 Vibration of Single Degree of Freedom Systems 9

        1.1 Setting up Equations of Motion for SDoF Systems 9

        1.2 Free Vibration of SDoF Systems 11

        1.3 Forced Vibration of SDoF Systems 13

        1.4 Harmonic Forced Vibration – Frequency Response Functions 14

        1.5 Transient/Random Forced Vibration – Time Domain Solution 17

        1.6 Transient Forced Vibration – Frequency Domain Solution 21

        1.7 Random Forced Vibration – Frequency Domain Solution 23

        1.8 Examples 24

        2 Vibration of Multiple Degree of Freedom Systems 27

        2.1 Setting up Equations of Motion 27

        2.2 Undamped Free Vibration 29

        2.3 Damped Free Vibration 31

        2.4 Transformation to Modal Coordinates 34

        2.5 Two-DoF Rigid Aircraft in Heave and Pitch 38

        2.6 ‘Free–Free’ Systems 40

        2.7 Harmonic Forced Vibration 41

        2.8 Transient/Random Forced Vibration – Time Domain Solution 43

        2.9 Transient Forced Vibration – Frequency Domain Solution 44

        2.10 Random Forced Vibration – Frequency Domain Solution 44

        2.11 Examples 45

        3 Vibration of Continuous Systems – Assumed Shapes Approach 49

        3.1 Continuous Systems 49

        3.2 Modelling Continuous Systems 49

        3.3 Elastic and Flexural Axes 51

        3.4 Rayleigh–Ritz ‘Assumed Shapes’ Method 52

        3.5 Generalized Equations of Motion – Basic Approach 53

        3.6 Generalized Equations of Motion – Matrix Approach 58

        3.7 Generating Whole Aircraft ‘Free–Free’ Modes from ‘Branch’ Modes 61

        3.8 Whole Aircraft ‘Free–Free’ Modes 64

        3.9 Examples 65

        4 Introduction to Steady Aerodynamics 69

        4.1 The Standard Atmosphere 69

        4.2 Effect of Air Speed on Aerodynamic Characteristics 71

        4.3 Flows and Pressures Around a Symmetric Aerofoil 73

        4.4 Forces on an Aerofoil 74

        4.5 Variation of Lift for an Aerofoil at an Angle of Incidence 76

        4.6 Pitching Moment Variation and the Aerodynamic Centre 77

        4.7 Lift on a Three-dimensional Wing 78

        4.8 Drag on a Three-dimensional Wing 82

        4.9 Control Surfaces 83

        4.10 Transonic Flows 84

        4.11 Examples 85

        5 Introduction to Loads 87

        5.1 Laws of Motion 88

        5.2 D’Alembert’s Principle – Inertia Forces and Couples 90

        5.3 External Loads – Applied and Reactive 94

        5.4 Free Body Diagrams 95

        5.5 Internal Loads 96

        5.6 Internal Loads for a Continuous Member 96

        5.7 Internal Loads for a Discretized Member 101

        5.8 Intercomponent Loads 103

        5.9 Obtaining Stresses from Internal Loads – Structural Members with Simple Load Paths 103

        5.10 Examples 104

        6 Introduction to Control 109

        6.1 Open and Closed Loop Systems 109

        6.2 Laplace Transforms 110

        6.3 Modelling of Open and Closed Loop Systems using Laplace and Frequency Domains 112

        6.4 Stability of Systems 114

        6.5 PID Control 121

        6.6 Examples 122

        PART II INTRODUCTION TO AEROELASTICITY AND LOADS 123

        7 Static Aeroelasticity – Effect of Wing Flexibility on Lift Distribution and Divergence 125

        7.1 Static Aeroelastic Behaviour of a Two-dimensional Rigid Aerofoil with a Torsional Spring Attachment 126

        7.2 Static Aeroelastic Behaviour of a Fixed Root Flexible Wing 130

        7.3 Effect of Trim on Static Aeroelastic Behaviour 133

        7.4 Effect of Wing Sweep on Static Aeroelastic Behaviour 137

        7.5 Examples 142

        8 Static Aeroelasticity – Effect of Wing Flexibility on Control Effectiveness 143

        8.1 Rolling Effectiveness of a Flexible Wing – Fixed Wing Root Case 144

        8.2 Rolling Effectiveness of a Flexible Wing – Steady Roll Case 147

        8.3 Effect of Spanwise Position of the Control Surface 151

        8.4 Full Aircraft Model – Control Effectiveness 152

        8.5 Effect of Trim on Reversal Speed 153

        8.6 Examples 153

        9 Introduction to Unsteady Aerodynamics 155

        9.1 Quasi-steady Aerodynamics 156

        9.2 Unsteady Aerodynamics related to Motion 156

        9.3 Aerodynamic Lift and Moment for an Aerofoil Oscillating Harmonically in Heave and Pitch 161

        9.4 Oscillatory Aerodynamic Derivatives 162

        9.5 Aerodynamic Damping and Stiffness 163

        9.6 Approximation of Unsteady Aerodynamic Terms 164

        9.7 Unsteady Aerodynamics related to Gusts 164

        9.8 Examples 168

        10 Dynamic Aeroelasticity – Flutter 171

        10.1 Simplified Unsteady Aerodynamic Model 172

        10.2 Binary Aeroelastic Model 173

        10.3 General Form of the Aeroelastic Equations 176

        10.4 Eigenvalue Solution of the Flutter Equations 176

        10.5 Aeroelastic Behaviour of the Binary Model 177

        10.6 Aeroelastic Behaviour of a Multiple Mode System 185

        10.7 Flutter Speed Prediction for Binary Systems 185

        10.8 Divergence of Dynamic Aeroelastic Systems 188

        10.9 Inclusion of Unsteady Reduced Frequency Effects 189

        10.10 Control Surface Flutter 193

        10.11 Whole Aircraft Model – Inclusion of Rigid Body Modes 199

        10.12 Flutter in the Transonic Regime 202

        10.13 Effect of Non-Linearities – Limit Cycle Oscillations 202

        10.14 Examples 204

        11 Aeroservoelasticity 207

        11.1 Mathematical Modelling of a Simple Aeroelastic System with a Control Surface 208

        11.2 Inclusion of Gust Terms 209

        11.3 Implementation of a Control System 210

        11.4 Determination of Closed Loop System Stability 211

        11.5 Gust Response of the Closed Loop System 213

        11.6 Inclusion of Control Law Frequency Dependency in Stability Calculations 214

        11.7 Response Determination via the Frequency Domain 215

        11.8 State Space Modelling 216

        11.9 Examples 217

        12 Equilibrium Manoeuvres 219

        12.1 Equilibrium Manoeuvre – Rigid Aircraft under Normal Acceleration 221

        12.2 Manoeuvre Envelope 226

        12.3 Equilibrium Manoeuvre – Rigid Aircraft Pitching 227

        12.4 Equilibrium Manoeuvre – Flexible Aircraft Pitching 235

        12.5 Representation of the Flight Control System (FCS) 250

        12.6 Examples 250

        13 Dynamic Manoeuvres 253

        13.1 Aircraft Axes 255

        13.2 Motion Variables 257

        13.3 Axes Transformations 257

        13.4 Velocity and Acceleration Components for Moving Axes in 2D 259

        13.5 Flight Mechanics Equations of Motion for a Rigid Symmetric Aircraft in 2D 262

        13.6 Representation of Disturbing Forces and Moments 265

        13.7 Modelling the Flexible Aircraft 267

        13.8 Solution of Flight Mechanics Equations for the Rigid Aircraft 272

        13.9 Dynamic Manoeuvre – Rigid Aircraft in Longitudinal Motion 273

        13.10 Dynamic Manoeuvre – Flexible Aircraft Heave/Pitch 279

        13.11 General Form of Longitudinal Equations 287

        13.12 Dynamic Manoeuvre for Rigid Aircraft in Lateral Motion 288

        13.13 Bookcase Manoeuvres for Rigid Aircraft in Lateral Motion 289

        13.14 Flight Control System (FCS) 293

        13.15 Representation of the Flight Control System (FCS) 295

        13.16 Examples 295

        14 Gust and Turbulence Encounters 299

        14.1 Gusts and Turbulence 300

        14.2 Gust Response in the Time Domain 301

        14.3 Time Domain Gust Response – Rigid Aircraft in Heave 303

        14.4 Time Domain Gust Response – Rigid Aircraft in Heave/Pitch 310

        14.5 Time Domain Gust Response – Flexible Aircraft 316

        14.6 General Form of Equations in the Time Domain 321

        14.7 Turbulence Response in the Frequency Domain 321

        14.8 Frequency Domain Turbulence Response – Rigid Aircraft in Heave 324

        14.9 Frequency Domain Turbulence Response – Rigid Aircraft in Heave/Pitch 329

        14.10 Frequency Domain Turbulence Response – Flexible Aircraft 330

        14.11 General Form of Equations in the Frequency Domain 333

        14.12 Representation of the Flight Control System (FCS) 334

        14.13 Examples 334

        15 Ground Manoeuvres 337

        15.1 Landing Gear 337

        15.2 Taxi, Take-Off and Landing Roll 342

        15.3 Landing 351

        15.4 Braking 359

        15.5 Turning 360

        15.6 Shimmy 361

        15.7 Representation of the Flight Control System (FCS) 363

        15.8 Examples 363

        16 Aircraft Internal Loads 367

        16.1 Limit and Ultimate Loads 368

        16.2 Internal Loads for an Aircraft 368

        16.3 General Internal Loads Expressions – Continuous Wing 370

        16.4 Effect of Wing-mounted Engines and Landing Gear 372

        16.5 Internal Loads – Continuous Flexible Wing 373

        16.6 General Internal Loads Expressions – Discretized Wing 379

        16.7 Internal Loads – Discretized Fuselage 384

        16.8 Internal Loads – Continuous Turbulence Encounter 387

        16.9 Loads Generation and Sorting to yield Critical Cases 388

        16.10 Aircraft Dimensioning Cases 390

        16.11 Stresses derived from Internal Loads – Complex Load Paths 391

        16.12 Examples 391

        17 Vibration of Continuous Systems – Finite Element Approach 395

        17.1 Introduction to the Finite Element Approach 395

        17.2 Formulation of the Beam Bending Element 397

        17.3 Assembly and Solution for a Beam Structure 401

        17.4 Torsion Element 406

        17.5 Combined Bending/Torsion Element 407

        17.6 Concentrated Mass Element 408

        17.7 Stiffness Element 408

        17.8 Rigid Body Elements 409

        17.9 Other Elements 410

        17.10 Comments on Modelling 411

        17.11 Examples 413

        18 Potential Flow Aerodynamics 415

        18.1 Components of Inviscid, Incompressible Flow Analysis 415

        18.2 Inclusion of Vorticity 420

        18.3 Numerical Steady Aerodynamic Modelling of Thin Two-dimensional Aerofoils 422

        18.4 Steady Aerodynamic Modelling of Three-Dimensional Wings using a Panel Method 425

        18.5 Unsteady Aerodynamic Modelling of Wings undergoing Harmonic Motion 429

        18.6 Aerodynamic Influence Coefficients in Modal Space 432

        18.7 Examples 436

        19 Coupling of Structural and Aerodynamic Computational Models 437

        19.1 Mathematical Modelling – Static Aeroelastic Case 438

        19.2 2D Coupled Static Aeroelastic Model – Pitch 439

        19.3 2D Coupled Static Aeroelastic Model – Heave/Pitch 440

        19.4 3D Coupled Static Aeroelastic Model 441

        19.5 Mathematical Modelling – Dynamic Aeroelastic Response 446

        19.6 2D Coupled Dynamic Aeroelastic Model – Bending/Torsion 447

        19.7 3D Flutter Analysis 448

        19.8 Inclusion of Frequency Dependent Aerodynamics for State–Space Modelling – Rational Function Approximation 450

        PART III INTRODUCTION TO INDUSTRIAL PRACTICE 455

        20 Aircraft Design and Certification 457

        20.1 Aeroelastics and Loads in the Aircraft Design Process 457

        20.2 Aircraft Certification Process 459

        21 Aeroelasticity and Loads Models 465

        21.1 Structural Model 465

        21.2 Aerodynamic Model 471

        21.3 Flight Control System 473

        21.4 Other Model Issues 474

        21.5 Loads Transformations 474

        22 Static Aeroelasticity and Flutter 475

        22.1 Static Aeroelasticity 475

        22.2 Flutter 478

        23 Flight Manoeuvre and Gust/Turbulence Loads 481

        23.1 Evaluation of Internal Loads 481

        23.2 Equilibrium/Balanced Flight Manoeuvres 481

        23.3 Dynamic Flight Manoeuvres 485

        23.4 Gusts and Turbulence 489

        24 Ground Manoeuvre Loads 495

        24.1 Aircraft/Landing Gear Models for Ground Manoeuvres 495

        24.2 Landing Gear/Airframe Interface 496

        24.3 Ground Manoeuvres – Landing 496

        24.4 Ground Manoeuvres – Ground Handling 497

        24.5 Loads Processing 498

        25 Testing Relevant to Aeroelasticity and Loads 501

        25.1 Introduction 501

        25.2 Wind Tunnel Tests 501

        25.3 Ground Vibration Test 502

        25.4 Structural Coupling Test 503

        25.5 Flight Simulator Test 504

        25.6 Structural Tests 504

        25.7 Flight Flutter Test 505

        25.8 Flight Loads Validation 507

        Appendices 509

        A Aircraft Rigid Body Modes 511

        B Table of Longitudinal Aerodynamic Derivatives 513

        C Aircraft Symmetric Flexible Modes 517

        D Model Condensation 527

        E Aerodynamic Derivatives in Body Fixed Axes 531

        References 535

        Index 539

      Recently viewed products

      © 2026 Book Curl

        • American Express
        • Apple Pay
        • Diners Club
        • Discover
        • Google Pay
        • Maestro
        • Mastercard
        • PayPal
        • Shop Pay
        • Union Pay
        • Visa

        Login

        Forgot your password?

        Don't have an account yet?
        Create account