物質點法:適於極端工況的粒子類方法(英文版)是2017年清華大學出版社出版的圖書。
基本介紹
- 書名:物質點法:適於極端工況的粒子類方法(英文版)
- 作者:張雄
陳震
劉岩 - 出版時間:2017年06月01日
- 定價:69 元
- ISBN:9787302470274
內容介紹,目錄,
內容介紹
本書系統地論述了物質點法的理論、程式設計和套用,並提供了開原始碼MPM3D-F90。英文版在中文版的基礎上連備龍嚷做了大幅修改和補充,增加和擴充了部分內容(如不可壓物質點法、隱式物質點探灑炒法、開源代全騙拔碼MPM3D-F90的描述與算例、多尺度物質點法等),並基於點面接觸算法對耦合物質點有限元和自適應物質點有限元法進行了全面更新,力圖反映物龍霸妹質點法的最新研究進展。微狼料本書可供航天航空、力學、機械、汽車、土木、水利等專業的虹連高年級本科生、研究生和教師使用芝歡棵夜,也可供相關領域的科技人員閱讀參考。
目錄
Contents
Dedication i
About the Authors vii
Preface ix
1. Introduction
1.1 Lagrangian Methods 1
1.2 Eulerian Methods 3
1.3 Hybrid Methods 4
1.3.1 Arbitrary Eulerian–Lagrangian Method and Its Variations 4
1.3.2 Particle-In-Cell Method and Its Variations 5
1.3.3 Material Point Method 6
1.4 Meshfree Methods 7
2. Governing Equations
2.1 Description of Motion 11
2.2 Deformation Gradient 14
2.3 Rate of Deformation 16
2.4 Cauchy Stress 17
2.5 Jaumann Stress Rate 19
2.6 Updated Lagrangian Formulation 20
2.6.1 Reynolds’ Transport Theorem 20
2.6.2 Conservation of Mass 21
2.6.3 Conservation of Linear Momentum 22
2.6.4 Conservation of Energy 23
2.6.5 Governing Equations 24
2.7 We...
2.7WeakFormoftheUpdatedLagrangianFormulation25
2.8ShockWave27
2.8.1Rankine–HugoniotEquations27
2.8.2ArtificialBulkViscosity29
2.9DetonationWave32
2.9.1CJDetonationModel32
2.9.2ZNDDetonationModel35
iii
ivContents
3.TheMaterialPointMethod
3.1MaterialPointDiscretization37
3.1.1LagrangianPhase38
3.1.2ConvectivePhase41
3.2ExplicitMaterialPointMethod42
3.2.1ExplicitTimeIntegration43
3.2.2ExplicitMPMScheme47
3.2.3QualitativeDemonstration53
3.2.4ComparisonBetweenMPMandFEM56
3.3ContactMethod59
3.3.1BoundaryConditionsatContactSurface60
3.3.2ContactDetection62
3.3.3ContactForce64
3.3.4NumericalAlgorithmforContactMethod67
3.4GeneralizedInterpolationMPMandOtherImprovements68
3.4.1ContiguousParticleGIMP71
3.4.2UniformGIMP72
3.4.3ConvectedParticleDomainInterpolation74
3.4.4DualDomainMaterialPointMethod75
3.4.5SplineGridShapeFunction76
3.5AdaptiveMaterialPointMethod77
3.5.1ParticleAdaptiveSplit77
3.5.2AdaptiveComputationalGrid79
3.6Non-reflectingBoundary87
3.7IncompressibleMaterialPointMethod88
3.7.1MomentumEquationofFluid89
3.7.2OperatorSplitting89
3.7.3PressurePoissonEquations90
3.7.4PressureBoundaryConditions91
3.7.5VelocityUpdate92
3.8ImplicitMaterialPointMethod93
3.8.1ImplicitTimeIntegration95
3.8.2SolutionofaSystemofNonlinearEquations95
3.8.3TheJacobianofGridNodalInternalForce97
3.8.4SolutionofaLinearizedSystemofEquations99
4.ComputerImplementationoftheMPM
4.1ExecutionoftheMPM3D-F90104
4.2InputDataFileFormatoftheMPM3D-F90105
4.2.1Unit105
4.2.2Keywords105
4.2.3GlobalInformation106
4.2.4MaterialModel106
4.2.5BackgroundGrid108
4.2.6SolutionScheme109
4.2.7ResultsOutput109
Contentsv
4.2.8Bodies110
4.2.9Load111
4.2.10AnExampleofInputDataFile111
4.3SourceFilesoftheMPM3D-F90113
4.4FreeFormatInput113
4.5MPMDataEncapsulation115
4.5.1ParticleData115
4.5.2GridData116
4.5.3DataInput119
4.5.4DataOutput120
4.6MainSubroutines121
4.7NumericalExamples137
4.7.1TNTSlabDetonation137
4.7.2TaylorBarImpact138
4.7.3PerforationofaThickPlate139
4.7.4FailureofSoilSlope141
5.CouplingoftheMPMwithFEM
5.1ExplicitFiniteElementMethod143
5.1.1FiniteElementDiscretization143
5.1.2TheFEMFormulationinMatrixForm145
5.1.3HexahedronElement147
5.1.4NumericalAlgorithmforanExplicitFEM155
5.2HybridFEMandMPM156
5.3CoupledFEMandMPM162
5.3.1GlobalSearch164
5.3.2LocalSearch165
5.3.3ContactForce166
5.4AdaptiveFEMPMethod168
5.4.1DiscretizationScheme168
5.4.2ConversionAlgorithm169
5.4.3CouplingBetweenRemainingElementsandParticles170
6.ConstitutiveModels
6.1StressUpdate175
6.2StrengthModels178
6.2.1ElasticModel178
6.2.2ElastoplasticModels179
6.2.3ReturnMappingAlgorithm182
6.2.4J2FlowTheory188
6.2.5Pressure-DependentElastoplasticity196
6.2.6NewtonianFluid205
6.2.7HighExplosive205
6.3EquationofState207
6.3.1PolytropicProcess207
viContents
6.3.2NearlyIncompressibleFluid208
6.3.3LinearPolynomial209
6.3.4JWL210
6.3.5Mie–Grüneisen211
6.4FailureModels213
6.4.1EffectivePlasticStrainFailureModel214
6.4.2HydrostaticTensileFailureModel214
6.4.3MaximumPrincipal/ShearStressFailureModel214
6.4.4MaximumPrincipal/ShearStrainFailureModel214
6.4.5EffectiveStrainFailureModel215
6.5ComputerImplementationofMaterialModels215
6.5.1ModuleMaterialData215
6.5.2ModuleMaterialModel217
7.MultiscaleMPM
7.1GoverningEquationsatDifferentScales222
7.2SolutionSchemeforConcurrentSimulations224
7.2.1Preprocessor224
7.2.2CentralProcessingUnit224
7.3InterfacialTreatment227
7.4Demonstration228
8.ApplicationsoftheMPM
8.1FractureEvolution231
8.2Impact236
8.3Explosion242
8.4Fluid–Structure/SolidInteraction247
8.5MultiscaleSimulation251
8.6BiomechanicsProblems259
8.7OtherProblemswithExtremeDeformations261
Bibliography265
Index277
2.9.2ZNDDetonationModel35
iii
ivContents
3.TheMaterialPointMethod
3.1MaterialPointDiscretization37
3.1.1LagrangianPhase38
3.1.2ConvectivePhase41
3.2ExplicitMaterialPointMethod42
3.2.1ExplicitTimeIntegration43
3.2.2ExplicitMPMScheme47
3.2.3QualitativeDemonstration53
3.2.4ComparisonBetweenMPMandFEM56
3.3ContactMethod59
3.3.1BoundaryConditionsatContactSurface60
3.3.2ContactDetection62
3.3.3ContactForce64
3.3.4NumericalAlgorithmforContactMethod67
3.4GeneralizedInterpolationMPMandOtherImprovements68
3.4.1ContiguousParticleGIMP71
3.4.2UniformGIMP72
3.4.3ConvectedParticleDomainInterpolation74
3.4.4DualDomainMaterialPointMethod75
3.4.5SplineGridShapeFunction76
3.5AdaptiveMaterialPointMethod77
3.5.1ParticleAdaptiveSplit77
3.5.2AdaptiveComputationalGrid79
3.6Non-reflectingBoundary87
3.7IncompressibleMaterialPointMethod88
3.7.1MomentumEquationofFluid89
3.7.2OperatorSplitting89
3.7.3PressurePoissonEquations90
3.7.4PressureBoundaryConditions91
3.7.5VelocityUpdate92
3.8ImplicitMaterialPointMethod93
3.8.1ImplicitTimeIntegration95
3.8.2SolutionofaSystemofNonlinearEquations95
3.8.3TheJacobianofGridNodalInternalForce97
3.8.4SolutionofaLinearizedSystemofEquations99
4.ComputerImplementationoftheMPM
4.1ExecutionoftheMPM3D-F90104
4.2InputDataFileFormatoftheMPM3D-F90105
4.2.1Unit105
4.2.2Keywords105
4.2.3GlobalInformation106
4.2.4MaterialModel106
4.2.5BackgroundGrid108
4.2.6SolutionScheme109
4.2.7ResultsOutput109
Contentsv
4.2.8Bodies110
4.2.9Load111
4.2.10AnExampleofInputDataFile111
4.3SourceFilesoftheMPM3D-F90113
4.4FreeFormatInput113
4.5MPMDataEncapsulation115
4.5.1ParticleData115
4.5.2GridData116
4.5.3DataInput119
4.5.4DataOutput120
4.6MainSubroutines121
4.7NumericalExamples137
4.7.1TNTSlabDetonation137
4.7.2TaylorBarImpact138
4.7.3PerforationofaThickPlate139
4.7.4FailureofSoilSlope141
5.CouplingoftheMPMwithFEM
5.1ExplicitFiniteElementMethod143
5.1.1FiniteElementDiscretization143
5.1.2TheFEMFormulationinMatrixForm145
5.1.3HexahedronElement147
5.1.4NumericalAlgorithmforanExplicitFEM155
5.2HybridFEMandMPM156
5.3CoupledFEMandMPM162
5.3.1GlobalSearch164
5.3.2LocalSearch165
5.3.3ContactForce166
5.4AdaptiveFEMPMethod168
5.4.1DiscretizationScheme168
5.4.2ConversionAlgorithm169
5.4.3CouplingBetweenRemainingElementsandParticles170
6.ConstitutiveModels
6.1StressUpdate175
6.2StrengthModels178
6.2.1ElasticModel178
6.2.2ElastoplasticModels179
6.2.3ReturnMappingAlgorithm182
6.2.4J2FlowTheory188
6.2.5Pressure-DependentElastoplasticity196
6.2.6NewtonianFluid205
6.2.7HighExplosive205
6.3EquationofState207
6.3.1PolytropicProcess207
viContents
6.3.2NearlyIncompressibleFluid208
6.3.3LinearPolynomial209
6.3.4JWL210
6.3.5Mie–Grüneisen211
6.4FailureModels213
6.4.1EffectivePlasticStrainFailureModel214
6.4.2HydrostaticTensileFailureModel214
6.4.3MaximumPrincipal/ShearStressFailureModel214
6.4.4MaximumPrincipal/ShearStrainFailureModel214
6.4.5EffectiveStrainFailureModel215
6.5ComputerImplementationofMaterialModels215
6.5.1ModuleMaterialData215
6.5.2ModuleMaterialModel217
7.MultiscaleMPM
7.1GoverningEquationsatDifferentScales222
7.2SolutionSchemeforConcurrentSimulations224
7.2.1Preprocessor224
7.2.2CentralProcessingUnit224
7.3InterfacialTreatment227
7.4Demonstration228
8.ApplicationsoftheMPM
8.1FractureEvolution231
8.2Impact236
8.3Explosion242
8.4Fluid–Structure/SolidInteraction247
8.5MultiscaleSimulation251
8.6BiomechanicsProblems259
8.7OtherProblemswithExtremeDeformations261
Bibliography265
Index277
