非均匀材料断裂力学（英文版）

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作　者：	果立成，于红军，吴林志著
出版社：	科学出版社
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标　签：	暂缺

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ISBN：	9787030700711	出版时间：	2022-10-01	包装：	精装
开本：	16开	页数：	342	字数：

内容简介

　　《Fracture Mechanics of Nonhomogeneous Materials》包含了作者近20年在非均匀材料断裂力学领域的重要研究成果。这些工作主要针对国际非均匀材料断裂力学领域理论模型的不足以及复杂界面条件下断裂力学领域能量积分理论的理论空白开展了系统、深入的研究，从基础理论到仿真方法提出了有特色的研究思想。具体工作包括：非均匀材料的断裂力学基本理论、非均匀材料的传统特殊指数型模型、具有一般属性的非均匀材料断裂力学模型、含复杂界面非均匀材料的区域无关积分方法、考虑界面残余应力的一般性区域无关积分模型等内容。这些工作，克服了一般属性非均匀材料（梯度材料）的断裂力学难题，澄清了近30年来人们对传统指数模型的质疑，拓展并完善了非均质材料断裂力学的理论体系。相关工作得到了国际权威学术期刊和相关领域权威专家的好评。

作者简介

暂缺《非均匀材料断裂力学（英文版）》作者简介

图书目录

目录
Contents
Preface
Chapter 1　Fundamental theory of fracture mechanics of nonhomogeneous
materials　1
1.1　Internal crack　2
1.1.1　Basic equations for nonhomogeneous materials　2
1.1.2　Crack-tip fields for homogeneous materials　3
1.1.3　Crack-tip fields for nonhomogeneous materials　6
1.1.4　Crack-tip fields for nonhomogeneous orthotropic materials　12
1.2　Interface crack　14
1.2.1　Crack-tip fields of an interface crack　14
1.2.2　Crack-tip fields of an interface crack between two nonhomogeneous media　19
1.3　Three-dimensional curved crack　23
1.3.1　Internal crack　23
1.3.2　Interface crack　25
References　26
Chapter 2　Exponential models for crack problems in nonhomogeneous materials　28
2.1　Crack model for nonhomogeneous materials with an arbitrarily oriented crack　29
2.1.1　Basic equations and boundary conditions　29
2.1.2　Full field solution for a crack in the nonhomogeneous medium　31
2.1.3　Stress intensity factors (SIFs) and strain energy release rate (SERR)　36
2.2　Crack problems in nonhomogeneous coating-substrate or double-layered structures　38
2.2.1　Interface crack in nonhomogeneous coating-substrate structures　38
2.2.2　Cross -interface crack parallel to the gradient of material properties　45
2.2.3　Arbitrarily oriented crack in a double-layered structure　54
2.3　Crack problems in orthotropic nonhomogeneous materials　69
2.3.1　Basic equations and boundary conditions　69
2.3.2　Solutions to stress and displacement fields　71
2.3.3　Crack-tip SIFs　77
2.4　Transient crack problem of a coating-substrate structure　78
2.4.1　Basic equations and boundary conditions　78
2.4.2　Solutions to stress and displacement fields　79
2.4.3　Crack-tip SIFs　84
2.5　Representative examples　85
2.5.1　Example 1: Arbitrarily oriented crack in an infinite nonhomogeneous medium　85
2.5.2　Example 2: Interface crack between the coating and the substrate　88
2.5.3　Example 3: Crossing-interface crack perpendicular to the interface in a double-layered structure　89
2.5.4　Example 4: Inclined crack crossing the interface　94
2.5.5　Example 5: Vertical crack in a nonhomogeneous coating-substrate structure subjected to impact loading　96
Appendix 2A　98
References　99
Chapter 3　General model for nonhomogeneous materials with general elastic properties　101
3.1　Piecewise-exponential model for the mode I crack problem　102
3.1.1　Piecewise-exponential model (PE model)　102
3.1.2　Solutions to stress and displacement fields　105
3.1.3　Crack-tip SIFs　111
3.2　PE model for mixed-mode crack problem　112
3.2.1　Basic equations and boundary conditions　112
3.2.2　Solutions to stress and displacement fields　114
3.2.3　Crack-tip SIFs　119
3.3　PE model for dynamic crack problem　119
3.3.1　Basic equations and boundary conditions　119
3.3.2　Solutions to stress and displacement fields　123
3.3.3　Crack-tip SIFs　126
3.4　Representative examples　127
3.4.1　Example 1: Mode I crack problem for nonhomogeneous materials with general elastic properties　127
3.4.2　Example 2: Mixed-mode crack problem for nonhomogeneous materials with general elastic properties and an arbitrarily oriented crack　134
3.4.3　Example 3: Dynamic Mode I crack problem for nonhomogeneous materials with general elastic properties　139
Appendix 3A　145
References　151
Chapter 4　Fracture mechanics of nonhomogeneous materials based on piecewise-exponential model　153
4.1　Thermomechanical crack models of nonhomogeneous materials　154
4.1.1　Crack model for nonhomogeneous materials under steady thermal loads　154
4.1.2　Crack model for nonhomogeneous materials under thermal shock load　157
4.2　Viscoelastic crack model of nonhomogeneous materials　170
4.2.1　The correspondence principle for viscoelastic FGMs　170
4.2.2　Viscoelastic models for nonhomogeneous materials　173
4.2.3　PE model for the viscoelastic nonhomogeneous materials　174
4.3　Crack model for nonhomogeneous materials with stochastic properties　177
4.3.1　Stochastic micromechanics-based model for effective properties　177
4.3.2　Probabilistic characteristics of effective properties at transition region　182
4.3.3　Crack in nonhomogeneous materials with stochastic mechanical properties　183
4.4　Examples　188
4.4.1　Example 1: Steady thermomechanical crack problem　188
4.4.2　Example 2: Viscoelastic crack problem　195
4.4.3　Example 3: Crack problem in FGMs with stochastic mechanical properties　198
References　202
Chapter 5　Fracture of nonhomogeneous materials with complex interfaces　205
5.1　Interaction integral (I-integral)　207
5.1.1　J-integral　207
5.1.2　I-integral　208
5.1.3　Auxiliary field　208
5.1.4　Extraction of the SIFs　210
5.2　Domain-independent I-integral (DII-integral)　211
5.2.1　Domain form of the I-integral　211
5.2.2　DII-integral　214
5.3　DII-integral for orthotropic materials　220
5.4　Consideration of dynamic process　223
5.5　Calculation of the T-st