Mechanical properties of solid polymers.
"A substantially updated version of the previous 1983, combined with material from the highly regarded 2004 edition with the detailed mechanics of the first edition. Providing an updated and comprehensive account of the properties of solid polymers, the book covers all aspects of mechanical beh...
| Κύριοι συγγραφείς: | , |
|---|---|
| Μορφή: | Ηλ. βιβλίο |
| Γλώσσα: | English |
| Έκδοση: |
Chichester, West Sussex :
John Wiley & Sons,
2012.
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| Έκδοση: | Third edition / |
| Θέματα: | |
| Διαθέσιμο Online: | Full Text via HEAL-Link |
Πίνακας περιεχομένων:
- Mechanical Properties of Solid Polymers; Contents; Preface; 1 Structure of Polymers; 1.1 Chemical Composition; 1.1.1 Polymerisation; 1.1.2 Cross-Linking and Chain-Branching; 1.1.3 Average Molecular Mass and Molecular Mass Distribution; 1.1.4 Chemical and Steric Isomerism and Stereoregularity; 1.1.5 Liquid Crystalline Polymers; 1.1.6 Blends, Grafts and Copolymers; 1.2 Physical Structure; 1.2.1 Rotational Isomerism; 1.2.2 Orientation and Crystallinity; References; Further Reading; 2 The Mechanical Properties of Polymers: General Considerations; 2.1 Objectives.
- 2.2 The Different Types of Mechanical Behaviour2.3 The Elastic Solid and the Behaviour of Polymers; 2.4 Stress and Strain; 2.4.1 The State of Stress; 2.4.2 The State of Strain; 2.5 The Generalised Hooke's Law; References; 3 The Behaviour in the Rubber-Like State: Finite Strain Elasticity; 3.1 The Generalised Definition of Strain; 3.1.1 The Cauchy-Green Strain Measure; 3.1.2 Principal Strains; 3.1.3 Transformation of Strain; 3.1.4 Examples of Elementary Strain Fields; 3.1.5 Relationship of Engineering Strains to General Strains; 3.1.6 Logarithmic Strain; 3.2 The Stress Tensor.
- 3.3 The Stress-Strain Relationships3.4 The Use of a Strain Energy Function; 3.4.1 Thermodynamic Considerations; 3.4.2 The Form of the Strain Energy Function; 3.4.3 The Strain Invariants; 3.4.4 Application of the Invariant Approach; 3.4.5 Application of the Principal Stretch Approach; References; 4 Rubber-Like Elasticity; 4.1 General Features of Rubber-Like Behaviour; 4.2 The Thermodynamics of Deformation; 4.2.1 The Thermoelastic Inversion Effect; 4.3 The Statistical Theory; 4.3.1 Simplifying Assumptions; 4.3.2 Average Length of a Molecule between Cross-Links.
- 4.3.3 The Entropy of a Single Chain4.3.4 The Elasticity of a Molecular Network; 4.4 Modifications of Simple Molecular Theory; 4.4.1 The Phantom Network Model; 4.4.2 The Constrained Junction Model; 4.4.3 The Slip Link Model; 4.4.4 The Inverse Langevin Approximation; 4.4.5 The Conformational Exhaustion Model; 4.4.6 The Effect of Strain-Induced Crystallisation; 4.5 The Internal Energy Contribution to Rubber Elasticity; 4.6 Conclusions; References; Further Reading; 5 Linear Viscoelastic Behaviour; 5.1 Viscoelasticity as a Phenomenon; 5.1.1 Linear Viscoelastic Behaviour; 5.1.2 Creep.
- 5.1.3 Stress Relaxation5.2 Mathematical Representation of Linear Viscoelasticity; 5.2.1 The Boltzmann Superposition Principle; 5.2.2 The Stress Relaxation Modulus; 5.2.3 The Formal Relationship between Creep and Stress Relaxation; 5.2.4 Mechanical Models, Relaxation and Retardation Time Spectra; 5.2.5 The Kelvin or Voigt Model; 5.2.6 The Maxwell Model; 5.2.7 The Standard Linear Solid; 5.2.8 Relaxation Time Spectra and Retardation Time Spectra; 5.3 Dynamical Mechanical Measurements: The Complex Modulus and Complex Compliance.
