Pubbl/distr/stampa |
Cham, Switzerland : , : Springer, , [2022]
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Descrizione fisica |
1 online resource (357 pages)
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Disciplina |
620.105
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Collana |
Advanced Structured Materials
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Soggetto topico |
Structural analysis (Engineering)
Materials - Analysis
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ISBN |
3-030-97675-0
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Formato |
Materiale a stampa |
Livello bibliografico |
Monografia |
Lingua di pubblicazione |
eng
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Nota di contenuto |
Intro -- Preface -- Contents -- List of Contributors -- Chapter 1 The Use of the Homogenization Method in the Analysis of Anisotropic Creep in Metal-matrix Composites -- 1.1 Introduction -- 1.2 Homogenization Method for Determining the Properties of Composite Materials -- 1.3 Creep Theory of Initially Orthotropic Materials -- 1.4 Method for Determining the Average Creep Properties of Fiber Composites -- 1.5 Micromechanical Creep Analysis of Unidirectional Composite -- 1.6 Conclusions -- References -- Chapter 2 General Forms of Limit Surface: Application for Isotropic Materials -- 2.1 Introduction -- 2.2 Geometric Properties of Criteria -- 2.2.1 Requirements for Yield and Strength Criteria -- 2.2.2 Formulation of Yield and Strength Criteria -- 2.2.3 Pressure-sensitive Extension of Yield Criteria -- 2.3 Designation and Comparison of Yield Criteria -- 2.3.1 Nomenclature of Yield Criteria -- 2.3.2 Comparison of Yield Criteria -- 2.3.3 Shapes of Yield Criteria in the π-plane -- 2.3.4 Extreme Yield Figures -- 2.3.5 Geometric Properties and Basic Experiments -- 2.4 Yield and Strength Criteria -- 2.4.1 Recommended Yield and Strength Criteria -- 2.4.2 PODGÓRSKI-type Shape Functions -- 2.4.3 Inductive Derivation of Criteria -- 2.4.4 Modified YU Strength Theory -- 2.5 Criterion with Shape Variation in π-plane -- 2.6 Summary -- 2.7 Appendix -- 2.7.1 Invariants of Stress Tensor -- 2.7.2 Scalar Functions of Invariants -- 2.7.3 Modified Invariants -- 2.7.4 Particular Points on Limit Surface -- 2.7.5 Values for Comparison -- 2.7.6 Modified Normal Stress Hypothesis -- 2.7.7 Series of Invariants -- 2.7.8 Plausibility Assumptions -- References -- Chapter 3 Model Order Reduction: The Bridge Between Structural Mechanics and System Simulation -- 3.1 Introduction -- 3.2 Multi-body Simulation Including Elastic Bodies -- 3.3 Methods of Model Order Reduction.
3.4 Quality Assurance of the Model Order Reduction -- 3.5 Example for Model Order Reduction -- 3.6 Summary -- References -- Chapter 4 Identification of Temperature Dependent Material Properties in Composite Plates Utilizing Experimental Vibration Data -- 4.1 Introduction -- 4.2 Theory -- 4.2.1 Plate Theory -- 4.2.2 Numerical Methods -- 4.2.3 Operational Modal Analysis -- 4.2.4 Optimization Strategy -- 4.3 Measurements and Simulations -- 4.3.1 Measurement Setup -- 4.3.2 Test Sample -- 4.3.3 Numerical Model -- 4.4 Results -- 4.4.1 Experimental Results and Analysis -- 4.4.2 Identified Elastic Properties -- 4.5 Conclusion -- 4.6 Appendix -- 4.6.1 Mode Shapes of OMA -- 4.6.2 ANSYS Simulated Mode Shapes -- References -- Chapter 5 Unilateral Constraints and Multibody Dynamics -- 5.1 Introduction -- 5.2 Concepts of Dynamics -- 5.2.1 Bilateral Dynamics -- 5.2.2 Unilateral Dynamics -- 5.3 Impacts with Friction -- 5.3.1 General Theory -- 5.3.2 Energy Considerations -- 5.4 Contact Kinematics -- 5.4.1 Plane Contact Kinematics -- 5.4.2 Spatial Contact Kinematics -- 5.5 Numerical Aspects -- 5.6 Applications -- 5.6.1 Woodpecker, a Non-smooth Toy -- 5.6.2 Vibration Conveyor -- 5.6.3 Roller Coaster -- 5.6.4 Drop Tower Hydraulics -- 5.6.5 CVT Power Transmission -- 5.7 Conclusion -- References -- Chapter 6 Influence of Thermal Stabilisation on the Thermal Regime in the Strapdown Inertial Navigation System -- 6.1 Introduction -- 6.2 Description of the Model and Physical Process -- 6.3 Mathematical Framework and Solution Method -- 6.4 Results -- 6.5 Conclusions -- References -- Chapter 7 Experimental-numerical Analysis of Microstructure-property Linkages for Additively Manufactured Materials -- 7.1 Introduction -- 7.2 Methods -- 7.2.1 Experimental Characterisation of Microstructure and Defect Population.
7.2.2 Numerical Characterisation of Microstructure and Defect Population, and Reconstruction -- 7.2.3 Microstructure Properties and Ranking -- 7.2.4 Grain Structure Characterisation -- 7.3 Results -- 7.3.1 Pore Microstructure-property Linkage -- 7.3.2 Grain Microstructure-property Linkage -- 7.4 Conclusions -- References -- Chapter 8 Multisurface Theory of Plasticity with one Active Surface: Basic Relations, Experimental Validation and Microstructural Motivation -- 8.1 Introduction -- 8.2 Conditions of Reversing -- 8.3 Constitutive Equations -- 8.4 Experimental Analysis -- 8.4.1 Test Results for Nickel Specimens -- 8.4.2 Test Results for Steel Specimens -- 8.5 Comparison of the Multisurface Model and the Microstructural Model Predictions -- 8.6 Numerical Implementation of the Constitutive Equations of the Multisurface Theory with one Active Surface -- 8.7 Finite-element Simulations -- 8.8 Conclusions -- References -- Chapter 9 A Damage Model for Corrosion Fatigue due to Hydrogen Embrittlement -- 9.1 Introduction -- 9.2 Model Description -- 9.2.1 Hydrogen Formation, Adsorption, and Absorption -- 9.2.2 Damage Analysis -- 9.3 Numerical Results and Discussions -- 9.3.1 Hydrogen Adsorption and Absorption -- 9.3.2 Parameters of Damage Model -- 9.3.3 Influences of Frequency on the Fatigue Life -- 9.3.4 Influences of Stress Ratio -- 9.4 Conclusions -- 9.5 Appendix -- References -- Chapter 10 A Thermodynamics-BasedWear Model and its Application with the Finite Element Analysis -- 10.1 Introduction -- 10.2 Wear Equation Based on a Thermodynamics Approach -- 10.3 Application with the Finite Element Analysis -- 10.3.1 Time Discretization -- 10.3.2 Contact Iteration -- 10.4 The Wear Simulation of Timing Chains -- 10.4.1 Experimental Investigations -- 10.4.2 Description of the Finite Element Model.
10.4.3 Determining an Extrapolation Factor for the Wear Simulation -- 10.5 Summary -- References -- Chapter 11 Discrete Description of Crack Kinematics in Regularized Free Discontinuities of Crack Faces -- 11.1 Introduction -- 11.2 Representative Crack Elements -- 11.2.1 Structure and Notation -- 11.2.2 Kinematic Coupling -- 11.3 Regularization of the Free Discontinuity Problem -- 11.3.1 Governing Equations -- 11.3.2 Stress and Consistent Tangent -- 11.4 Numerical Applications -- 11.4.1 Self-consistent Test -- 11.4.2 A Single Edge Notch Plate (SENP) at Shear Load -- 11.4.3 Structural Fracture at Finite Strain -- 11.4.4 Cohesive Failure Modeling -- 11.4.5 Contact Friction Modeling -- 11.5 Conclusions -- References -- Chapter 12 Applications of Viscoplasticity and Damage Models, the Thermomechanical Consistency and the Prospect of a Microstructural Representation -- 12.1 Introduction -- 12.2 Experimental and Numerical Investigation of Temperature-dependent Mechanical Behaviour of 3D Printed Polyamide 12 -- 12.2.1 Experimental Analysis -- 12.2.2 Microanalysis -- 12.2.3 Numerical Analysis -- 12.2.4 Results -- 12.3 Thermomechanical Approach -- 12.3.1 Analytical Formulation in the Framework of Continuum Thermomechanics -- 12.3.2 Experimental Approach -- 12.3.3 Results and Discussion -- 12.4 Numerical Models Based on CT Data -- 12.5 Summary -- References.
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Record Nr. | UNINA-9910558499203321 |