熱障涂層破壞理論與評價技術(shù)（英文版）

定　價：￥499.00

作　者：	周益春，楊麗著
出版社：	科學(xué)出版社
叢編項：
標(biāo)　簽：	暫缺

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ISBN：	9787030733290	出版時間：	2022-10-01	包裝：	精裝
開本：	16開	頁數(shù)：	934	字?jǐn)?shù)：

內(nèi)容簡介

　　整書內(nèi)容分為三篇，共15章。第一篇即第1～6章，介紹熱障涂層的破壞理論，其中第1章和第2章分別介紹熱力化耦合的理論框架和非線性有限元理論，第3～6章分別介紹熱障涂層界面氧化、CMAS腐蝕、沖蝕熱力化耦合的破壞理論與機(jī)制。第二篇即第7～12章，介紹熱障涂層性能與損傷的表征技術(shù)，第7～9章凝練熱障涂層基本力學(xué)性能、斷裂韌性、殘余應(yīng)力的各種先進(jìn)表征方法，第10～12章介紹裂紋、界面氧化、應(yīng)力應(yīng)變場等關(guān)鍵損傷參量的無損實時表征方法。第三篇即第13～15章，介紹熱障涂層性能評價技術(shù)，包括隔熱與強(qiáng)度綜合效果的評價、可靠性與服役壽命的評價以及模擬考核方法與試驗平臺方面的進(jìn)展。

作者簡介

暫缺《熱障涂層破壞理論與評價技術(shù)（英文版）》作者簡介

圖書目錄

目錄
Contents
1　Introduction　1
1.1　TBCs and the Corresponding Preparation Methods　2
1.1.1　TBC Materialsand Structures　2
1.1.2　TBC Preparation Methods　4
1.2　TBC Spallation Failure and Its MainIn.uencingFactors　9
1.2.1　Service Conditions for TBCs　9
1.2.2　TBC Spallation Failure and Its MainIn.uencing Factors　10
1.3　Solid Mechanics Requirements and Challenges Generated by TBC Failure　14
1.3.1　Solid Mechanics Requirements Generated by TBC Failure　14
1.3.2　Solid Mechanics Challenges Presented by TBC Failure　17
1.4　Content Overview　21
References　23
2　Basic Theoretical Frameworks for Thermo–Mechano-Chemical Coupling in TBCs　27
2.1　Continuum Mechanics　27
2.2　Theoretical Frameworkfor Thermo–Mechano-Chemical Coupling Basedon Small Deformation　30
2.2.1　Strain and Stress Measures BasedonSmall Deformation[5，6]　30
2.2.2　Stress–Strain Constitutive Relations Based onSmall Deformation[5，6]　47
2.2.3　Constitutive Theoryfor Thermomechanical CouplingBased on Small Deformation[11]　52
2.2.4　Constitutive Theory forThermo–Mechano-Chemical Coupling Basedon Small Deformation[16]　61
2.3　Theoretical Frameworkfor Thermo–Mechano-Chemical Coupling BasedonLarge Deformation　68
2.3.1　Kinematic Description[9]　68
2.3.2　Stressand StrainMeasures　71
2.3.3　Mass Conservation and Force Equilibrium Equations　74
2.3.4　Constitutive Theoryfor Thermomechanical Coupling Basedon Large Deformation[18，25，26]　80
2.3.5　Constitutive Theory for Thermo–Mechano-Chemical Coupling BasedonLarge Deformation　85
2.4　Summary and Out look　93
References　97
3　Nonlinear FEA of TBCs on Turbine Blades　99
3.1　FEAPrinciples　100
3.1.1　Functional Variational Principle　100
3.1.2　WeakFormof theEulerianFormulation　105
3.1.3　FEDiscretizati on of the Eulerian Formulation　108
3.1.4　WeakFormof theLagrangian Formulation　111
3.1.5　FE Discretizati on of the Lagrangian Formulation　113
3.1.6　WeakFormof the Arbitrary Lagrangian–Eulerian Formulation　116
3.1.7　Initial and Boundary Conditions　121
3.2　FE Modeling of TBCs on Turbine Blades　122
3.2.1　Geometric Characteristicsof Turbine Blades　122
3.2.2　Parametric Modelingof Turbine Blades　124
3.3　Mesh Generationfor Turbine Blades　140
3.3.1　Generationof Unstructured Meshes　141
3.3.2　Structured Meshes for Turbine Blades　145
3.4　Image-Based FE Modeling　150
3.4.1　Image-BasedFEM　151
3.4.2　2D TGO Interface Modeling　153
3.4.3　Porous Ceramic Layer Modeling　156
3.4.4　D3TGO Interface Modeling Method　157
3.5　Summaryand Outlook　158
References　159
4　Geometric Nonlinearity Theory for the Interfacial Oxidation of TBCs　163
4.1　Interfacial Oxidation Phenomenon andFailure　164
4.1.1　Characteristics and Patterns of Interfacial Oxidation　164
4.1.2　StressField Inducedby Interfacial Oxidation　167
4.1.3　Coating SpallationInducedby Interfacial Oxidation　170
4.2　TGO Growth Model Basedon Diffusion Reaction　172
4.2.1　Governing Equations　172
4.2.2　FESimulation　178
4.3　Thermo–Chemo–Mechanical CouplingAnalytical Model forInterfacial OxidationofTBCs　188
4.3.1　Thermo–Chemo–Mechanical Coupling Analytical Growth Model forInterfacial Oxidation　188
4.3.2　Thermo–Chemo–Mechanical Coupling Growth Constitutive Relations forInterfacial Oxidation　201
4.3.3　Analysis of theThermo–Mechano-Chemical CouplingGrowthPatterns and Mechanisms DuringInterfacialOxidation　222 References　232
5　Physically Nonlinear Coupling Growth and Damage Caused by Interfacial Oxidation in TBCs　235
5.1　Physically Nonlinear Model forThermo–Mechano–Chemical Coupling Growth Causedby Interfacial Oxidationin TBCs　236
5.1.1　Model Framework　236
5.1.2　Numerical Implementation　243
5.1.3　Resultsand Discussion　246
5.1.4　Analytical Coupling Model for Interfacial Oxidation　252
5.1.5　Comparison with Experimental Results　256
5.2　Interfacial Oxidation Failure Theorythat Integrates the CZM and PFM　262
5.2.1　Integrated CZM and PFM Framework　262
5.2.2　Introductionto PFM　263
5.2.3　Introductionto CZM for Phase-FieldCrack Interactions　267
5.2.4　Numerical Implementation　271
5.2.5　Resultsand Discussion　273
5.3　Summary and Out look　281
5.3.1　Summary　281
5.3.2　Outlook　283
References　283
6　Thermo–Mechano–Chemical Coupling During CMAS Corrosion in TBCs　287
6.1　Correlation Analysisof Molten CMASIn.ltration and Its KeyIn.uencingFactors　288
6.1.1　Theoretical Model for Mol ten CMASIn.ltration Depthin EB-PVD TBCs　288
6.1.2　Experimentsonthe MoltenCMASIn.ltration Depthinan EB-PVD TBC and Its In.uencing Factors　298
6.1.3　CMASIn.ltration Depthinthe EB-PVD TBC and ItsIn.uencing Factors　299
6.1.4　In.ltration of CMAS Meltsin an APS TBC　308
6.2　Microstructural Evolution， Deformation， and Composition Loss of Coatings Dueto Corrosion　312
6.2.1　Microstructural Evolution and Deformation ofCoatings　312
6.2.2　Thermo–Mechano–Che