Shape memory alloy engineering : for aerospace, structural and biomedical applications

Shape memory alloy engineering for aerospace, structural and biomedical applications

Shape Memory Alloy Engineering introduces materials, mechanical, and aerospace engineers to shape memory alloys (SMAs), providing a unique perspective that combines fundamental theory with new approaches to design and modeling of actual SMAs as compact and inexpensive actuators for use in aerospace...

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Detalles Bibliográficos
Otros Autores: Concilio, Antonio, author (author), Lecce, Leonardo, publishing director (publishing director), Concilio, Antonio, publishing director (contributor), Ameduri, Salvatore, contributor
Formato: Libro electrónico
Idioma:Inglés
Publicado: Kidlington, England ; Waltham, Massachusetts : Butterworth-Heinemann 2015.
Edición:1st edition
Materias:
Alloys > Elastic properties.
Production engineering.
Shape memory alloys.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628690906719
Tabla de Contenidos:
  • Front Cover; Shape Memory Alloy Engineering; Copyright; Dedication; CONTENTS; LIST OF CONTRIBUTORS; ABOUT THE EDITORS-IN-CHIEF; ABOUT THE CONTRIBUTORS; PREFACE; Section 1 Introduction; Chapter 1 - Historical Background and Future Perspectives; 1.1 INTRODUCTION; 1.2 LIST OF SYMBOLS; 1.3 SHAPE MEMORY ALLOYS; 1.4 GOLD-BASED ALLOYS; 1.5 NITINOL; 1.6 COPPER-BASED ALLOYS; 1.7 IRON-BASED ALLOYS; 1.8 SMA COMMUNITY; 1.9 FUTURE PERSPECTIVES; 1.10 SUMMARY TABLES; BIBLIOGRAPHY; Section 2 Material; Chapter 2 - Phenomenology of Shape Memory Alloys; 2.1 INTRODUCTION; 2.2 LIST OF SYMBOLS
  • 2.3 GENERAL CHARACTERISTICS AND THE MARTENSITIC TRANSFORMATIONS2.4 FUNCTIONAL PROPERTIES OF SMAS; 2.5 POROUS NITI; 2.6 MAGNETIC SHAPE MEMORY ALLOYS; 2.7 CONCLUSIONS; BIBLIOGRAPHY; Chapter 3 - Experimental Characterization of Shape Memory Alloys; 3.1 INTRODUCTION; 3.2 LIST OF SYMBOLS; 3.3 CALORIMETRIC INVESTIGATIONS; 3.4 THERMOMECHANICAL CHARACTERIZATION: TESTS AND PARAMETERS; 3.5 COMPLETE EXPERIMENTAL CHARACTERIZATION OF THERMAL AND MECHANICAL PROPERTIES; 3.6 ELECTRICAL RESISTANCE MEASUREMENTS; 3.7 NEUTRON DIFFRACTION ANALYSIS; 3.8 CONCLUSION; BIBLIOGRAPHY
  • Chapter 4 - Manufacturing of Shape Memory Alloys4.1 INTRODUCTION; 4.2 LIST OF SYMBOLS; 4.3 MELTING PROCESS OF SMA; 4.4 TRADITIONAL WORKING PROCESS OF SMA MATERIALS; 4.5 NEW TECHNOLOGIES OF PREPARATION OF SMA PRODUCTS; 4.6 THERMOMECHANICAL PROCESS TO OPTIMIZE THE FUNCTIONAL PROPERTIES OF SMA; 4.7 NEAR NET SHAPE PROCESS; 4.8 ECOCOMPATIBILITY OF SMA; BIBLIOGRAPHY; Section 3 Modelling; Chapter 5 - 1D SMA Models; 5.1 INTRODUCTION; 5.2 LIST OF SYMBOLS; 5.3 NONKINETIC MODELS; 5.4 ADVANCED MODELS WITH TRAINING EFFECT; 5.5 CONCLUSIONS; BIBLIOGRAPHY
  • Chapter 6 - SMA Constitutive Modeling and Analysis of Plates and Composite Laminates6.1 INTRODUCTION; 6.2 LIST OF SYMBOLS; 6.3 THREE-DIMENSIONAL PHENOMENOLOGICAL CONSTITUTIVE MODEL FOR SMA; 6.4 PLATE AND LAMINATE MODELS FOR SMA APPLICATIONS; 6.5 NUMERICAL RESULTS; 6.6 CONCLUSIONS; BIBLIOGRAPHY; Chapter 7 - SMAs in Commercial Codes; 7.1 INTRODUCTION; 7.2 SUPERELASTIC SMAS WITHIN SIMULIA ABAQUS SOLVER; 7.3 INTEGRATION OF SMAS WITHIN COMSOL MULTIPHYSICS SOLVER; 7.4 INTEGRATION OF SMAS WITHIN ANSYS SOLVER; 7.5 INTEGRATION OF SMAS WITHIN MSC.NASTRAN SOLVER; 7.6 APPLICATIONS; 7.7 CONCLUSIONS
  • BIBLIOGRAPHYSection 4 Aeronautics; Chapter 8 - Design and Industrial Manufacturing of SMA Components; 8.1 INTRODUCTION; 8.2 LIST OF SYMBOLS; 8.3 DESIGN OF SMA COMPONENTS; 8.4 MANUFACTURING OF SMA COMPONENTS; 8.5 CONCLUSIONS; BIBLIOGRAPHY; Chapter 9 - Design of SMA-Based Structural Actuators; 9.1 INTRODUCTION; 9.2 LIST OF SYMBOLS; 9.3 REQUIREMENTS FOR THE DESIGN OF AN SMA-BASED ACTUATOR; 9.4 DESIGN OF AN SMA-BASED INTEGRATED SYSTEM: FORCE-DISPLACEMENT/STRESS-STRAIN PLANE; 9.5 COMPUTATION OF THE WORKING POINTS; 9.6 COMPUTATION OF STRUCTURAL RIGIDITY AS PERCEIVED BY THE SMA ELEMENT
  • 9.7 DESIGN OF AN ARC SMA-BASED ACTUATOR

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