Mechanics of Aircraft Structures - C. T. Sun, Ashfaq Adnan

Mechanics of Aircraft Structures

, (Autoren)

Buch | Hardcover
320 Seiten
2021 | 3rd edition
John Wiley & Sons Inc (Verlag)
978-1-119-58391-2 (ISBN)
149,75 inkl. MwSt
MECHANICS OF AIRCRAFT STRUCTURES Explore the most up-to-date overview of the foundations of aircraft structures combined with a review of new aircraft materials

The newly revised Third Edition of Mechanics of Aircraft Structures delivers a combination of the fundamentals of aircraft structure with an overview of new materials in the industry and a collection of rigorous analysis tools into a single one-stop resource. Perfect for a one-semester introductory course in structural mechanics and aerospace engineering, the distinguished authors have created a textbook that is also ideal for mechanical or aerospace engineers who wish to stay updated on recent advances in the industry.

The new edition contains new problems and worked examples in each chapter and improves student accessibility. A new chapter on aircraft loads and new material on elasticity and structural idealization form part of the expanded content in the book. Readers will also benefit from the inclusion of:



A thorough introduction to the characteristics of aircraft structures and materials, including the different types of aircraft structures and their basic structural elements
An exploration of load on aircraft structures, including loads on wing, fuselage, landing gear, and stabilizer structures
An examination of the concept of elasticity, including the concepts of displacement, strain, and stress, and the equations of equilibrium in a nonuniform stress field
A treatment of the concept of torsion

Perfect for senior undergraduate and graduate students in aerospace engineering, Mechanics of Aircraft Structures will also earn a place in the libraries of aerospace engineers seeking a one-stop reference to solidify their understanding of the fundamentals of aircraft structures and discover an overview of new materials in the field.

C. T. Sun, PhD, is Neil A. Armstrong Distinguished Professor Emeritus of Aeronautics and Astronautics at Purdue University. Dr. Sun was the inaugural recipient of the AIAA-ASC James H. Starnes Award and the 2007 ASME Warner T. Koiter Medal. Ashfaq Adnan, PhD, is Professor in the Mechanical and Aerospace Engineering Department at the University of Texas at Arlington and a Fellow of ASME. His research focus is on deformation, damage, and failure of biological, bioinspired, and engineered materials at multiple length scales.

Preface to the Third Edition xiii

Preface to the Second Edition xv

Preface to the First Edition xvii

About the Companion Website xix

1 Characteristics of Aircraft Structures and Materials 1

1.1 Introduction, 1

1.2 Types of Aircraft Structures, 1

1.2.1 Fixed-Wing Aircraft, 2

1.2.2 Rotorcraft, 2

1.2.3 Lighter-than-Air Vehicles, 2

1.2.4 Drones, 2

1.3 Basic Structural Elements in Aircraft Structure, 3

1.3.1 Fuselage, 3

1.3.2 Wing, 3

1.3.3 Landing Gear, 4

1.3.4 Control Surfaces, 4

1.4 Aircraft Materials, 5

1.4.1 Steel Alloys, 5

1.4.2 Aluminum Alloys, 6

1.4.3 Titanium Alloys, 6

1.4.4 Fiber-Reinforced Composites, 6

Problems, 7

2 Loads on Aircraft Structures 9

2.1 Introduction, 9

2.2 Basic Structural Elements, 9

2.2.1 Axial Member, 9

2.2.2 Shear Panel, 11

2.2.3 Bending Member (Beam), 12

2.2.4 Torsion Member, 13

2.3 Wing and Fuselage, 15

2.3.1 Load Transfer, 15

2.3.2 Wing Structure, 16

2.3.3 Fuselage, 17

Problems, 20

3 Introduction to Elasticity 23

3.1 Introduction, 23

3.2 Concept of Displacement, 24

3.3 Strain, 26

3.3.1 Rigid Body Motion, 28

3.4 Stress, 30

3.5 Equations of Equilibrium in a Uniform Stress Field, 31

3.6 Equations of Equilibrium in a Nonuniform Stress Field, 33

3.7 Stress Vector and Stress Components Relations, 35

3.8 Principal Stress, 37

3.9 Shear Stress, 40

3.10 Stress Transformation, 41

3.11 Linear Stress–Strain Relations, 44

3.11.1 Strains Induced by Normal Stress, 45

3.11.2 Strains Induced by Shear Stress, 47

3.11.3 Three-Dimensional Stress–Strain Relations, 47

3.11.3.1 Orthotropic Materials, 49

3.11.3.2 Isotropic Materials, 50

3.12 Plane Elasticity, 51

3.12.1 Stress–Strain Relations for Plane Isotropic Solids, 52

3.12.1.1 Plane Strain, 52

3.12.1.2 Plane Stress, 53

3.12.2 Stress–Strain Relations for Orthotropic Solids in Plane Stress, 54

3.12.3 Governing Equations, 55

3.12.3.1 Equilibrium Equations, 55

3.12.3.2 Boundary Conditions, 55

3.12.3.3 Compatibility Equation, 56

3.12.4 Solution by Airy Stress Function for Plane Isotropic Solids, 57

3.12.5 Plane Elasticity Solutions in Polar Coordinate System, 59

3.12.5.1 Strain–Displacement Relations, 59

3.12.5.2 Stresses in Polar Coordinates and Equilibrium Equations, 60

3.12.5.3 Stress–Strain Relations, 61

3.12.5.4 Stress Function Formulations, 61

3.13 Formulations Beyond 2-D Plane Elasticity, 62

Problems, 64

References, 71

4 Torsion 73

4.1 Introduction, 73

4.2 Torsion of Uniform Bars With Arbitrary Cross-Section, 73

4.2.1 Governing Equations, 74

4.2.2 Boundary Conditions, 76

4.2.3 Torque–Stress Relations, 77

4.2.4 Warping Displacement, 78

4.2.5 Torsion Constant, 79

4.3 Bars With Circular Cross-Sections, 79

4.3.1 Elasticity Approach Using Prandtl Stress Function, 79

4.3.2 Mechanics of Solid Approach, 82

4.4 Bars With Narrow Rectangular Cross-Sections, 85

4.5 Closed Single-Cell Thin-Walled Sections, 88

4.5.1 The s–n Coordinate System, 88

4.5.2 Prandtl Stress Function, 90

4.5.3 Shear Flow q, 91

4.5.4 Shear Flow–Torque Relation, 91

4.5.5 Twist Angle, 93

4.5.5.1 Method 1, 93

4.5.5.2 Method 2 for Constant Shear Flow, 94

4.5.6 Torsion Constant J, 95

4.6 Multicell Thin-Walled Sections, 98

4.7 Warping in Open Thin-Walled Sections, 102

4.8 Warping in Closed Thin-Walled Sections, 106

4.9 Effect of End Constraints, 108

Problems, 114

References, 119

5 Bending and Flexural Shear 121

5.1 Introduction, 121

5.2 Bernoulli–Euler Beam Theory, 121

5.2.1 Unidirectional Bending on Beams with a Symmetric Section, 121

5.2.2 Bidirectional Bending on Beams with an Arbitrary Section, 127

5.3 Structural Idealization, 131

5.4 Transverse Shear Stress Due to Transverse Force in Symmetric Sections, 139

5.4.1 Narrow Rectangular Cross-Section, 139

5.4.2 General Symmetric Sections, 141

5.4.3 Thin-Walled Sections, 142

5.4.4 Shear Deformation in Thin-Walled Sections, 143

5.5 Timoshenko Beam Theory, 146

5.6 Saint-Venant’s principle, 149

5.7 Shear Lag, 152

Problems, 155

Reference, 160

6 Flexural Shear Flow in Thin-Walled Sections 161

6.1 Introduction, 161

6.2 Flexural Shear Flow in Open Thin-Walled Sections, 161

6.2.1 Symmetric Thin-Walled Sections, 161

6.2.1.1 Stringer–Web Sections, 164

6.2.2 Unsymmetric Thin-Walled Sections, 166

6.2.3 Multiple Shear Flow Junctions, 168

6.2.4 Selection of Shear Flow Contour, 169

6.3 Shear Center in Open Sections, 169

6.4 Closed Thin-Walled Sections and Combined Flexural and Torsional Shear Flow, 175

6.4.1 Shear Center, 176

6.4.2 Statically Determinate Shear Flow, 179

6.5 Closed Multicell Sections, 182

Problems, 186

7 Failure Criteria for Isotropic Materials 193

7.1 Introduction, 193

7.2 Strength Criteria for Brittle Materials, 193

7.2.1 Maximum Principal Stress Criterion, 193

7.2.2 Coulomb–Mohr Criterion, 194

7.3 Yield Criteria for Ductile Materials, 196

7.3.1 Maximum Shear Stress Criterion (Tresca Yield Criterion) in Plane Stress, 196

7.3.2 Maximum Distortion Energy Criterion (von Mises Yield Criterion), 197

7.4 Fracture Mechanics, 203

7.4.1 Stress Concentration, 203

7.4.2 Concept of Cracks and Strain Energy Release Rate, 204

7.4.3 Fracture Criterion, 205

7.4.3.1 Strain Energy in Structural Members, 205

7.4.3.2 Axial Element, 206

7.4.3.3 Beam Element, 206

7.4.3.4 Torsion Member, 206

7.5 Stress Intensity Factor, 210

7.5.1 Symmetric Loading (Mode I Fracture), 210

7.5.2 Antisymmetric Loading (Mode II Fracture), 212

7.5.3 Relation between K and G, 213

7.5.4 Mixed Mode Fracture, 217

7.6 Effect of Crack Tip Plasticity, 218

7.7 Fatigue Failure, 220

7.7.1 Constant Stress Amplitude, 220

7.7.2 S–N Curves, 221

7.7.3 Variable Amplitude Loading, 221

7.8 Fatigue Crack Growth, 222

Problems, 224

References, 228

8 Elastic Buckling 229

8.1 Introduction, 229

8.2 Eccentrically Loaded Beam-Column, 229

8.3 Elastic Buckling of Straight Bars, 230

8.3.1 Pinned–Pinned Bar, 232

8.3.2 Clamped–Free Bar, 235

8.3.3 Clamped–Pinned Bar, 236

8.3.4 Clamped–Clamped Bar, 237

8.3.5 Effective Length of Buckling, 238

8.4 Initial Imperfection, 239

8.5 Postbuckling Behavior, 241

8.6 Bar of Unsymmetric Section, 246

8.7 Torsional–Flexural Buckling of Thin-Walled Bars, 248

8.7.1 Nonuniform Torsion, 248

8.7.2 Torsional Buckling of Doubly Symmetric Section, 249

8.7.3 Torsional–Flexural Buckling, 252

8.8 Elastic Buckling of Flat Plates, 256

8.8.1 Governing Equation for Flat Plates, 256

8.8.1.1 Boundary Conditions, 257

8.8.1.2 Clamped Edge, 258

8.8.1.3 Simply Supported Edge, 258

8.8.1.4 Free Edge, 258

8.8.2 Cylindrical Bending, 258

8.8.3 Buckling of Rectangular Plates, 259

8.8.3.1 Simply Supported Edges, 259

8.8.3.2 Other Boundary Conditions, 262

8.8.4 Buckling Under Shearing Stresses, 262

8.9 Local Buckling of Open Sections, 263

Problems, 265

9 Analysis of Composite Laminates 271

9.1 Plane Stress Equations for Composite Lamina, 271

9.2 Off-Axis Loading, 276

9.3 Notation for Stacking Sequence in Laminates, 278

9.3.1 Symmetry, 279

9.3.2 Repetition, 279

9.4 Symmetric Laminate Under In-Plane Loading, 279

9.5 Effective Moduli for Symmetric Laminates, 281

9.5.1 Quasi-Isotropic Laminate, 283

9.6 Laminar Stresses, 284

9.7 [±45 ] Laminate, 286

9.7.1 Determination of G 12 Using ±45 Laminates, 287

Problems, 288

Index 291

Erscheinungsdatum
Verlagsort New York
Sprache englisch
Maße 180 x 257 mm
Gewicht 771 g
Themenwelt Technik Fahrzeugbau / Schiffbau
Technik Luft- / Raumfahrttechnik
Technik Maschinenbau
ISBN-10 1-119-58391-8 / 1119583918
ISBN-13 978-1-119-58391-2 / 9781119583912
Zustand Neuware
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