Constitutive Models for Rubber III: Proceedings of the Third European Conference on Constitutive Models for Rubber, London, UK, 15-17 September 2003J. Busfield, A. Muhr CRC Press, 1 de jan. de 2003 - 460 páginas Recent developments in the modelling of rubber are collated in this volume, including not only stress-strain behaviour and the use of the large strain finite element method for simulation, but also fatigue, fracture, filler reinforcement, dynamic properties and the effects of ageing. |
Conteúdo
P Charrier E OstojaKuczynski E Verron G Marckmann L Gornet G Chagnon | 11 |
N Murphy C Spratt S Ronan S Jerrams R Johannknecht | 27 |
experimental database and macroscopic observations | 41 |
Fatigue life prediction and verification of rubber to metal bonded springs | 55 |
Study on the dynamic mechanical properties of aged rubbers | 71 |
A R Azura D Göritz A H Muhr A G Thomas | 85 |
Uniaxial and equibiaxial tension tests of silicone elastomer | 99 |
Application of nonlinear FEA to tyre rolling resistance simulation | 115 |
On a micromechanicallybased finite element simulation of the viscoelastic and | 213 |
Time dependencies in the response of selforganizing linkage patterns to imposed deformation | 231 |
efficiency and limitations | 237 |
Modelling dilatational stress softening of rubber | 253 |
E Canga Ş Özüpek E B Becker | 273 |
Thermodynamic analysis of polymer networks | 291 |
Modelling inelastic stressstrain phenomena and a scheme for efficient experimental characterization | 309 |
Network junction model for mechanical properties of filled vulcanizates | 325 |
Finite element analysis of a rubber bushing considering rate and amplitude dependent effects | 133 |
theory and experiment | 147 |
Critical comparison of popular hyperelastic material models in design | 161 |
Influence of the filler properties on the mechanical response of silica filled natural rubber | 177 |
The effect of spatially inhomogeneous mixing of polymer and crosslinks for | 195 |
The effect of swelling and temperature on the electrical and mechanical behaviour of a filled rubber | 343 |
Interpretation of the high lowstrain modulus of filled rubbers as an inelastic effect | 357 |
A Magalini D Vetturi G Ramorino A Saleri F Viganò | 373 |
A micromechanical mechanism for energy dissipation of filled rubber | 387 |
Termos e frases comuns
ABAQUS Achain applied behaviour bulk modulus Busfield & Muhr calculated carbon black chain components compression computational constitutive equation Constitutive Models crack growth cross-links curve damage deformation dependence displacement dynamic dynamic mechanical elastic elastomeric elastomers elongation energy release rate Engineering Equation experimental data fatigue filled elastomers filled rubber filler finite element analysis frequency Gent hydrostatic hyperelastic hysteresis incompressible increase ISBN 90 material model material parameters maximum measured mechanical method Models for Rubber Muhr eds Mullins effect natural rubber Neo-Hookean nonlinear Ogden particles Payne effect polymer pre-strain predicted properties ratio relaxation Rivlin rolling resistance sample shear modulus shown in Figure simple shear simulation solid specimen stiffness strain amplitude strain energy strain energy density strain energy function stress softening stress-strain stretch surface Swets & Zeitlinger temperature tensile tensor testpiece theory tion tire tyre uniaxial tension unloading viscoelastic volume change Yeoh Young's modulus