Mechanics of elastic contacts /

Materials and mechanical engineering researchers studying wear, fretting, elastic indentation testing and other tribological processes frequently need closed-form solutions for various attributes of contacts. These characteristics include contact law, pressure distribution, internal state of stress...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Hills, D. A. (David Anthony), 1955-
Otros Autores: Nowell, D., Sackfield, A.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Oxford [England] ; Boston : Butterworth-Heinemann, 1993.
Temas:
Mechanics, Applied.
Surfaces (Technology)
Rolling contact.
Elasticity.
Elasticity
M�ecanique appliqu�ee.
Surfaces (Technologie)
Contact de roulement.
�Elasticit�e.
modulus of elasticity.
elasticity.
TECHNOLOGY & ENGINEERING > Engineering (General)
TECHNOLOGY & ENGINEERING > Reference.
Mechanics, Applied
Rolling contact
Elastische Deformation
Elastischer Sto�
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Mechanics of Elastic Contacts; Copyright Page; Table of Contents; Preface; Part 1: Introduction; Chapter 1. Essential solid mechanics; 1.1 Introduction; 1.2 Forces and stresses; 1.3 Stress transformation; 1.4 Principal stresses and directions; 1.5 Displacements and strains; 1.6 The field equations
  • equilibrium; 1.7 The field equations
  • compatibility; 1.8 Constitutive laws; 1.9 Decomposition of the stress and strain tensors; 1.10 Characteristics of two-dimensional problems; 1.11 Failure criteria
  • preliminaries; 1.12 Yielding; 1.13 The bulk approach to brittle fracture.
  • 1.14 Basic fracture mechanics1.15 Introduction to contacts; Part 2: Plane Contact Problems; Chapter 2. Plane contacts: surface tractions; 2.1 Introduction; 2.2 Influence functions; 2.3 Contact of cylinders; 2.4 Sliding of elastically dissimilar cylinders; 2.5 Indentation by a general, convex body; 2.6 Sliding of elastically dissimilar convex bodies; 2.7 Indentation by a wedge; 2.8 Indentation by a rigid flat-ended punch; 2.9 Indentation by a punch generating uniform pressure; 2.10 Summary of results; Chapter 3. Plane contacts: interior stress fields; 3.1 Introduction; 3.2 Contact of cylinders.
  • 3.3 Sliding of elastically dissimilar cylinders3.4 Generalized incomplete plane contact; 3.5 Triangular pressure distribution; 3.6 Uniform pressure distribution; 3.7 Indentation by a rigid flat-ended punch; 3.8 Strength of plane contacts; 3.9 The elastic limit; 3.10 The shakedown limit; 3.11 Summary of results; Chapter 4. Plane contacts: partial slip; 4.1 Introduction; 4.2 Formulation of the problem; 4.3 Fretting contact
  • similar materials; 4.4 Rolling contact
  • similar materials; 4.5 Normal contact
  • dissimilar materials; 4.6 Fretting contact
  • dissimilar materials.
  • 4.7 Rolling contact
  • dissimilar materials4.8 Strength of plane contacts under partial slip conditions; Chapter 5. Plane contacts: mathematical techniques; 5.1 Introduction; 5.2 Elasticity equations in complex form: the Muskhelishvili potential; 5.3 The Plemelj formulae; 5.4 The Riemann-Hilbert problem; 5.5 Singular integral equations; Part 3: Axi-symmetric Contact Problems; Chapter 6. Axi-symmetric contacts: surface tractions; 6.1 Introduction; 6.2 Influence functions; 6.3 Contact of spheres (the Hertz problem); 6.4 Generalized incomplete contact; 6.5 Indentation by a conical punch.
  • 6.6 Indentation by a rigid flat-ended punch6.7 Indentation by a punch generating uniform pressure; 6.8 Summary of results; Chapter 7. Axi-symmetric contacts: interior stress field; 7.1 Introduction; 7.2 Contact of spheres (the Hertz problem); 7.3 More general incomplete contact; 7.4 Stress field under a conical punch; 7.5 Stress field under a rigid flat-ended punch; 7.6 Stress state induced by uniform pressure; 7.7 Stress state induced by a cone of pressure; 7.8 Strength of axi-symmetric contacts; Chapter 8. Axi-symmetric contacts: partial slip; 8.1 Introduction.

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