ISBN-13: 9781118929841 / Angielski / Twarda / 2018 / 288 str.
ISBN-13: 9781118929841 / Angielski / Twarda / 2018 / 288 str.
Preface xi
Introduction to Impact Dynamics xiii
Part 1 Stress Waves in Solids 1
1 Elastic Waves 3
1.1 Elastic Wave in a Uniform Circular Bar 3
1.1.1 The Propagation of a Compressive Elastic Wave 3
1.2 Types of Elastic Wave 6
1.2.1 Longitudinal Waves 6
1.2.2 Transverse Waves 7
1.2.3 Surface Wave (Rayleigh Wave) 7
1.2.4 Interfacial Waves 8
1.2.5 Waves in Layered Media (Love Waves) 8
1.2.6 Bending (Flexural) Waves 8
1.3 Reflection and Interaction of Waves 9
1.3.1 Mechanical Impedance 9
1.3.2 Waves When they Encounter a Boundary 10
1.3.3 Reflection and Transmission of 1D Longitudinal Waves 11
Questions 1 17
Problems 1 18
2 Elastic–Plastic Waves 19
2.1 One–Dimensional Elastic–Plastic Stress Wave in Bars 19
2.1.1 A Semi–Infinite Bar Made of Linear Strain–Hardening Material Subjected to a Step Load at its Free End 21
2.1.2 A Semi–Infinite Bar Made of Decreasingly Strain–Hardening Material Subjected to a Monotonically Increasing Load at its Free End 22
2.1.3 A Semi–Infinite Bar Made of Increasingly Strain–Hardening Material Subjected to a Monotonically Increasing Load at its Free End 23
2.1.4 Unloading Waves 25
2.1.5 Relationship Between Stress and Particle Velocity 26
2.1.6 Impact of a Finite–Length Uniform Bar Made of Elastic–Linear Strain–Hardening Material on a Rigid Flat Anvil 28
2.2 High–Speed Impact of a Bar of Finite Length on a Rigid Anvil (Mushrooming) 31
2.2.1 Taylor s Approach 31
2.2.2 Hawkyard s Energy Approach 36
Questions 2 38
Problems 2 38
Part 2 Dynamic Behavior of Materials under High Strain Rate 39
3 Rate–Dependent Behavior of Materials 41
3.1 Materials Behavior under High Strain Rates 41
3.2 High–Strain–Rate Mechanical Properties of Materials 44
3.2.1 Strain Rate Effect of Materials under Compression 44
3.2.2 Strain Rate Effect of Materials under Tension 44
3.2.3 Strain Rate Effect of Materials under Shear 47
3.3 High–Strain–Rate Mechanical Testing 48
3.3.1 Intermediate–Strain–Rate Machines 48
3.3.2 Split Hopkinson Pressure Bar (SHPB) 53
3.3.3 Expanding–Ring Technique 61
3.4 Explosively Driven Devices 62
3.4.1 Line–Wave and Plane–Wave Generators 63
3.4.2 Flyer Plate Accelerating 65
3.4.3 Pressure–Shear Impact Configuration 66
3.5 Gun Systems 67
3.5.1 One–Stage Gas Gun 67
3.5.2 Two–Stage Gas Gun 68
3.5.3 Electric Rail Gun 69
Problems 3 69
4 Constitutive Equations at High Strain Rates 71
4.1 Introduction to Constitutive Relations 71
4.2 Empirical Constitutive Equations 72
4.3 Relationship between Dislocation Velocity and Applied Stress 76
4.3.1 Dislocation Dynamics 76
4.3.2 Thermally Activated Dislocation Motion 81
4.3.3 Dislocation Drag Mechanisms 85
4.3.4 Relativistic Effects on Dislocation Motion 85
4.3.5 Synopsis 86
4.4 Physically Based Constitutive Relations 87
4.5 Experimental Validation of Constitutive Equations 90
Problems 4 90
Part 3 Dynamic Response of Structures to Impact and Pulse Loading 91
5 Inertia Effects and Plastic Hinges 93
5.1 Relationship between Wave Propagation and Global Structural Response 93
5.2 Inertia Forces in Slender Bars 94
5.2.1 Notations and Sign Conventions for Slender Links and Beams 95
5.2.2 Slender Link in General Motion 96
5.2.3 A Summary of the Methodology 102
5.3 Plastic Hinges in a Rigid–Plastic Free Free Beam under Pulse Loading 102
5.3.1 Dynamic Response of Rigid–Plastic Beams 102
5.3.2 A Free Free Beam Subjected to a Concentrated Step Force 104
5.3.3 Remarks on a Free Free Beam Subjected To A Step Force At Its Midpoint 108
5.4 A Free Ring Subjected to a Radial Load 109
5.4.1 Comparison between a Supported Ring and a Free Ring 112
Questions 5 112
Problems 5 112
6 Dynamic Response of Cantilevers 115
6.1 Response to Step Loading 115
6.2 Response to Pulse Loading 120
6.2.1 Rectangular Pulse 120
6.2.2 General Pulse 125
6.3 Impact on a Cantilever 126
6.4 General Features of Traveling Hinges 133
Problems 6 136
7 Effects of Tensile and Shear Forces 139
7.1 Simply Supported Beams with no Axial Constraint at Supports 139
7.1.1 Phase I 139
7.1.2 Phase II 142
7.2 Simply Supported Beams with Axial Constraint at Supports 144
7.2.1 Bending Moment and Tensile Force in a Rigid–Plastic Beam 144
7.2.2 Beam with Axial Constraint at Support 146
7.2.3 Remarks 151
7.3 Membrane Factor Method in Analyzing the Axial Force Effect 151
7.3.1 Plastic Energy Dissipation and the Membrane Factor 151
7.3.2 Solution using the Membrane Factor Method 153
7.4 Effect of Shear Deformation 155
7.4.1 Bending–Only Theory 156
7.4.2 Bending–Shear Theory 158
7.5 Failure Modes and Criteria of Beams under Intense Dynamic Loadings 161
7.5.1 Three Basic Failure Modes Observed in Experiments 161
7.5.2 The Elementary Failure Criteria 163
7.5.3 Energy Density Criterion 165
7.5.4 A Further Study of Plastic Shear Failures 166
Questions 7 168
Problems 7 168
8 Mode Technique, Bound Theorems, and Applicability of the Rigid–Perfectly Plastic Model 169
8.1 Dynamic Modes of Deformation 169
8.2 Properties of Modal Solutions 170
8.3 Initial Velocity of the Modal Solutions 172
8.4 Mode Technique Applications 174
8.4.1 Modal Solution of the Parkes Problem 174
8.4.2 Modal Solution for a Partially Loaded Clamped Beam 176
8.4.3 Remarks on the Modal Technique 179
8.5 Bound Theorems for RPP Structures 180
8.5.1 Upper Bound of Final Displacement 180
8.5.2 Lower Bound of Final Displacement 181
8.6 Applicability of an RPP Model 183
Problems 8 186
9 Response of Rigid–Plastic Plates 187
9.1 Static Load–Carrying Capacity of Rigid–Plastic Plates 187
9.1.1 Load Capacity of Square Plates 188
9.1.2 Load Capacity of Rectangular Plates 190
9.1.3 Load–Carrying Capacity of Regular Polygonal Plates 192
9.1.4 Load–Carrying Capacity of Annular Plate Clamped at its Outer Boundary 194
9.1.5 Summary 196
9.2 Dynamic Deformation of Pulse–Loaded Plates 196
9.2.1 The Pulse Approximation Method 196
9.2.2 Square Plate Loaded by Rectangular Pulse 197
9.2.3 Annular Circular Plate Loaded by Rectangular Pulse Applied on its Inner Boundary 201
9.2.4 Summary 204
9.3 Effect of Large Deflection 204
9.3.1 Static Load–Carrying Capacity of Circular Plates In Large Deflection 205
9.3.2 Dynamic Response of Circular Plates with Large Deflection 209
Problems 9 210
10 Case Studies 213
10.1 Theoretical Analysis of Tensor Skin 213
10.1.1 Introduction to Tensor Skin 213
10.1.2 Static Response to Uniform Pressure Loading 213
10.1.3 Dynamic Response of Tensor Skin 217
10.1.4 Pulse Shape 218
10.2 Static and Dynamic Behavior of Cellular Structures 219
10.2.1 Static Response of Hexagonal Honeycomb 221
10.2.2 Static Response of Generalized Honeycombs 223
10.2.3 Dynamic Response of Honeycomb Structures 228
10.3 Dynamic Response of a Clamped Circular Sandwich Plate Subject to Shock Loading 233
10.3.1 An Analytical Model for the Shock Resistance of Clamped Sandwich Plates 234
10.3.2 Comparison of Finite Element and Analytical Predictions 238
10.3.3 Optimal Design of Sandwich Plates 239
10.4 Collision and Rebound of Circular Rings and Thin–Walled Spheres on Rigid Target 241
10.4.1 Collision and Rebound of Circular Rings 241
10.4.2 Collision and Rebound of Thin–Walled Spheres 249
10.4.3 Concluding Remarks 257
References 259
Index 265
T.X. Yu, PhD, is Professor Emeritus at the Department of Mechanical Engineering, The Hong Kong University of Science and Technology, Hong Kong.
XinMing Qiu, PhD, is Professor at the School of Aerospace Engineering, Tsinghua University, Beijing, China.
Fundamental guidance including concepts, models, and methodology for better understanding the dynamic behavior of materials and for designing for objects and structures under impact or intensive dynamic loading
This book introduces readers to the dynamic response of structures with important emphasis on the material behavior under dynamic loadings. It utilizes theoretical modelling and analytical methods in order to provide readers with insight into the various phenomena. The content of the book is an introduction to the fundamental aspects, which underpin many important industrial areas. These areas include the safety of various transportation systems and a range of different structures when subjected to various impact and dynamic loadings, including terrorist attacks.
Presented in three parts Stress Waves in Solids, Dynamic Behaviors of Materials Under High Strain Rate, and Dynamic Response of Structures to Impact and Pulse Loading Introduction to Impact Dynamics covers elastic waves, rate dependent behaviors of materials, effects of tensile force, inertial effects, and more. The book also features numerous case studies to aid in facilitating learning. The strength of the book is its clarity, balanced coverage, and practical examples, which allow students to learn the overall knowledge of impact dynamics in a limited time whilst directing them to explore more advanced technical knowledge and skills.
Introduction to Impact Dynamics is the perfect textbook for graduate and postgraduate students, and will work as a reference for engineers in the fields of solid mechanics, automotive design, aerospace, mechanical, nuclear, marine, and defense.
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