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Format: 1 online resource (271 p.)

Edition: First edition.

ISBN: 0-12-801801-1 , 0-12-801697-3

Note: Description based upon print version of record. , Front Cover; Pseudoelasticity of Shape Memory Alloys: Theory and Experimental Studies; Copyright; Contents; About the author; Preface; List of symbols; Notation; Abbreviations; Chapter 1: Introduction; 1.1. Shape memory effects and their technical significance; 1.2. Historical outlook on discovery of SME in various metallic alloys; 1.3. Scope and structure of the book; Chapter 2: Shape memory effects in metallic alloys; 2.1. Physical foundations of SME effects-thermoelastic martensitic transformation , 2.2. Multiscale experimental investigation and modeling of martensitic transformation and SMA materials behavior2.3. SMA materials alloy systems, their characterization and properties; 2.4. Fabrication and processing routes of SMA materials, TMTs; 2.5. SMA materials application areas, functional and utility features; 2.5.1. Free recovery; 2.5.2. Control operation; 2.5.3. Constrained recovery; 2.5.4. Work production; 2.5.5. Pseudoelasticity (superelasticity); 2.5.6. High damping; Chapter 3: Family of thermodynamic RL models of pseudoelasticity; 3.1. Introduction , 3.2. Macroscopic, thermomechanical pseudoelastic behavior of SMA3.3. Approaches towards modeling pseudoelasticity-hysteresis loops; 3.4. Thermodynamic RL model of pseudoelasticity with SD-effect; 3.4.1. Introduction and thermodynamic equilibriums; 3.4.2. State variables; 3.4.3. Free energy functions and the rule of optimum rearrangement of mesostructure; 3.4.4. Thermal equations of state; 3.4.5. Internal material dissipation of work; 3.4.6. Phase transformation kinetics equations; 3.4.7. Complete set of incremental constitutive relations , Chapter 4: Macroscopic free energy function of two-phase SMA material macroelement-mesomechanical studies4.1. Introduction; 4.2. Mesomechanics of thermoelastic martensitic structures; 4.2.1. Mechanical equilibrium of macroelement with nonhomogeneous elastic properties and eigenstrains; 4.2.2. Elastic energy of heterogeneous macroelement in the presence of eigenstrains; 4.2.3. Elastic energy of a two-phase macroelement; 4.2.4. Macroscopic coherency energy W(in); 4.3. Postulate of optimal rearrangement of mesostructure; 4.4. Summary , Annex 4.1. Principle of reciprocity in linear theory of elasticity at presence of eigenstrainsAnnex 4.2. The postulate of work compatibility-Hill's postulate, concept of effective properties; Chapter 5: Experimental validation of RL model assumptions for NiTi alloy; 5.1. Introduction; 5.2. Methodology of experimental studies on NiTi alloy submitted to multiaxial stress states loadings; 5.3. Experimental data processing for validation of theoretical assumptions of the RL model , 5.4. Procedure for identification of the RL model material parameters. Comparison of modeling predictions with experiment ... , English

Language: English

UID:

Format: 1 online resource (271 pages) : , color illustrations

Edition: First edition.

ISBN: 9780128018019 (e-book)

Additional Edition: Print version: Pseudoelasticity of shape memory alloys : theory and experimental studies. Waltham, Massachusetts : Elsevier, [2015] ISBN 9780128016978

Language: English

Keywords: Electronic books.

URL: Click to View

UID:

Format: 1 online resource (271 p.)

Edition: First edition.

ISBN: 0-12-801801-1 , 0-12-801697-3

Note: Description based upon print version of record. , Front Cover; Pseudoelasticity of Shape Memory Alloys: Theory and Experimental Studies; Copyright; Contents; About the author; Preface; List of symbols; Notation; Abbreviations; Chapter 1: Introduction; 1.1. Shape memory effects and their technical significance; 1.2. Historical outlook on discovery of SME in various metallic alloys; 1.3. Scope and structure of the book; Chapter 2: Shape memory effects in metallic alloys; 2.1. Physical foundations of SME effects-thermoelastic martensitic transformation , 2.2. Multiscale experimental investigation and modeling of martensitic transformation and SMA materials behavior2.3. SMA materials alloy systems, their characterization and properties; 2.4. Fabrication and processing routes of SMA materials, TMTs; 2.5. SMA materials application areas, functional and utility features; 2.5.1. Free recovery; 2.5.2. Control operation; 2.5.3. Constrained recovery; 2.5.4. Work production; 2.5.5. Pseudoelasticity (superelasticity); 2.5.6. High damping; Chapter 3: Family of thermodynamic RL models of pseudoelasticity; 3.1. Introduction , 3.2. Macroscopic, thermomechanical pseudoelastic behavior of SMA3.3. Approaches towards modeling pseudoelasticity-hysteresis loops; 3.4. Thermodynamic RL model of pseudoelasticity with SD-effect; 3.4.1. Introduction and thermodynamic equilibriums; 3.4.2. State variables; 3.4.3. Free energy functions and the rule of optimum rearrangement of mesostructure; 3.4.4. Thermal equations of state; 3.4.5. Internal material dissipation of work; 3.4.6. Phase transformation kinetics equations; 3.4.7. Complete set of incremental constitutive relations , Chapter 4: Macroscopic free energy function of two-phase SMA material macroelement-mesomechanical studies4.1. Introduction; 4.2. Mesomechanics of thermoelastic martensitic structures; 4.2.1. Mechanical equilibrium of macroelement with nonhomogeneous elastic properties and eigenstrains; 4.2.2. Elastic energy of heterogeneous macroelement in the presence of eigenstrains; 4.2.3. Elastic energy of a two-phase macroelement; 4.2.4. Macroscopic coherency energy W(in); 4.3. Postulate of optimal rearrangement of mesostructure; 4.4. Summary , Annex 4.1. Principle of reciprocity in linear theory of elasticity at presence of eigenstrainsAnnex 4.2. The postulate of work compatibility-Hill's postulate, concept of effective properties; Chapter 5: Experimental validation of RL model assumptions for NiTi alloy; 5.1. Introduction; 5.2. Methodology of experimental studies on NiTi alloy submitted to multiaxial stress states loadings; 5.3. Experimental data processing for validation of theoretical assumptions of the RL model , 5.4. Procedure for identification of the RL model material parameters. Comparison of modeling predictions with experiment ... , English

Language: English

UID:

Format: 1 online resource (271 p.)

Edition: First edition.

ISBN: 0-12-801801-1 , 0-12-801697-3

Note: Description based upon print version of record. , Front Cover; Pseudoelasticity of Shape Memory Alloys: Theory and Experimental Studies; Copyright; Contents; About the author; Preface; List of symbols; Notation; Abbreviations; Chapter 1: Introduction; 1.1. Shape memory effects and their technical significance; 1.2. Historical outlook on discovery of SME in various metallic alloys; 1.3. Scope and structure of the book; Chapter 2: Shape memory effects in metallic alloys; 2.1. Physical foundations of SME effects-thermoelastic martensitic transformation , 2.2. Multiscale experimental investigation and modeling of martensitic transformation and SMA materials behavior2.3. SMA materials alloy systems, their characterization and properties; 2.4. Fabrication and processing routes of SMA materials, TMTs; 2.5. SMA materials application areas, functional and utility features; 2.5.1. Free recovery; 2.5.2. Control operation; 2.5.3. Constrained recovery; 2.5.4. Work production; 2.5.5. Pseudoelasticity (superelasticity); 2.5.6. High damping; Chapter 3: Family of thermodynamic RL models of pseudoelasticity; 3.1. Introduction , 3.2. Macroscopic, thermomechanical pseudoelastic behavior of SMA3.3. Approaches towards modeling pseudoelasticity-hysteresis loops; 3.4. Thermodynamic RL model of pseudoelasticity with SD-effect; 3.4.1. Introduction and thermodynamic equilibriums; 3.4.2. State variables; 3.4.3. Free energy functions and the rule of optimum rearrangement of mesostructure; 3.4.4. Thermal equations of state; 3.4.5. Internal material dissipation of work; 3.4.6. Phase transformation kinetics equations; 3.4.7. Complete set of incremental constitutive relations , Chapter 4: Macroscopic free energy function of two-phase SMA material macroelement-mesomechanical studies4.1. Introduction; 4.2. Mesomechanics of thermoelastic martensitic structures; 4.2.1. Mechanical equilibrium of macroelement with nonhomogeneous elastic properties and eigenstrains; 4.2.2. Elastic energy of heterogeneous macroelement in the presence of eigenstrains; 4.2.3. Elastic energy of a two-phase macroelement; 4.2.4. Macroscopic coherency energy W(in); 4.3. Postulate of optimal rearrangement of mesostructure; 4.4. Summary , Annex 4.1. Principle of reciprocity in linear theory of elasticity at presence of eigenstrainsAnnex 4.2. The postulate of work compatibility-Hill's postulate, concept of effective properties; Chapter 5: Experimental validation of RL model assumptions for NiTi alloy; 5.1. Introduction; 5.2. Methodology of experimental studies on NiTi alloy submitted to multiaxial stress states loadings; 5.3. Experimental data processing for validation of theoretical assumptions of the RL model , 5.4. Procedure for identification of the RL model material parameters. Comparison of modeling predictions with experiment ... , English

Language: English