Hyperelasticity Primer [electronic resource] / by Robert M. Hackett.

Por: Hackett, Robert M [author.]Colaborador(es): SpringerLink (Online service)Tipo de material: Texto

TextoEditor: Cham : Springer International Publishing : Imprint: Springer, 2018Edición: 2nd ed. 2018Descripción: XIX, 186 p. 5 illus., 4 illus. in color. online resourceTipo de contenido: text Tipo de medio: computer Tipo de portador: online resourceISBN: 9783319732015Tema(s): Mechanics | Mechanics, Applied | Materials science | Solid Mechanics | Solid Mechanics | Characterization and Evaluation of Materials | Classical MechanicsFormatos físicos adicionales: Printed edition:: Sin título; Printed edition:: Sin título; Printed edition:: Sin títuloClasificación CDD: 531 | 531 Clasificación LoC:TA349-359TA349-359Recursos en línea: Libro electrónico Texto

Contenidos:

Finite Elasticity -- Strain Measures -- Polar Decomposition -- Strain-Energy Function -- Stress Measures -- Tangent Moduli -- Conjugate Pairs -- Incrementation (Parts I -- II -- III and IV) -- Objectivity -- Finite Viscoelasticity -- Finite Element Implementation -- How to Obtain Model Parameters from Test Data,- Appendices.

En: Springer Nature eBookResumen: This book introduces the subject of hyperelasticity in a concise manner mainly directed to students of solid mechanics who have a familiarity with continuum mechanics. It focuses on important introductory topics in the field of nonlinear material behavior and presents a number of example problems and solutions to greatly aid the student in mastering the difficulty of the subject and gaining necessary insight. Professor Hackett delineates the concepts and applications of hyperelasticity in such a way that a new student of the subject can absorb the intricate details without having to wade through excessively complicated formulations. The book further presents significant review material on intricately related subjects such as tensor calculus and introduces some new formulations. Introduces hyperelasticity in a concise, straightforward manner using practical examples; Reinforces understanding with a significant number of example problems/solutions to demonstrate application of the presented formulations; Defines material models for rubber, polymers, foams and soft tissue; Emphasizes incremental formulations and solutions; Presents material related to finite element implementation and incremental finite viscoelasticity; Explains methodology of obtaining model parameters from test data.

Existencias ( 1 )
Notas de título ( 4 )

Existencias
Tipo de ítem	Biblioteca actual	Colección	Signatura	Copia número	Estado	Fecha de vencimiento	Código de barras
Libro Electrónico	Biblioteca Electrónica	Colección de Libros Electrónicos		1	No para préstamo

Acceso multiusuario

This book introduces the subject of hyperelasticity in a concise manner mainly directed to students of solid mechanics who have a familiarity with continuum mechanics. It focuses on important introductory topics in the field of nonlinear material behavior and presents a number of example problems and solutions to greatly aid the student in mastering the difficulty of the subject and gaining necessary insight. Professor Hackett delineates the concepts and applications of hyperelasticity in such a way that a new student of the subject can absorb the intricate details without having to wade through excessively complicated formulations. The book further presents significant review material on intricately related subjects such as tensor calculus and introduces some new formulations. Introduces hyperelasticity in a concise, straightforward manner using practical examples; Reinforces understanding with a significant number of example problems/solutions to demonstrate application of the presented formulations; Defines material models for rubber, polymers, foams and soft tissue; Emphasizes incremental formulations and solutions; Presents material related to finite element implementation and incremental finite viscoelasticity; Explains methodology of obtaining model parameters from test data.

UABC ; Temporal ; 01/01/2021-12/31/2023.