Numerical Evaluation of Micro- to Macroscopic Mechanical Behavior of Carbon Black-Filled Rubber

Yoshihiro Tomita; Wei Lu; Yasuhiro Furutani

doi:10.4028/www.scientific.net/KEM.274-276.19

Paper Titles

Preface

Plasticity in Monocrystalline Silicon: Experiment and Modelling
p.1

Analysis of Ridging in Ferritic Stainless Steel and Aluminum Alloy Sheets
p.11

Numerical Evaluation of Micro- to Macroscopic Mechanical Behavior of Carbon Black-Filled Rubber
p.19

Plastic Collapse of Honeycombs under In-Plane Biaxial Compression
p.25

Micromechanics of Nonlinear Composites
p.35

Mesoplasticity and Its Applications in Micro-Scale Deformation Processing
p.43

Dislocation Depleted Deformation in Nano-Grained Metals
p.51

High Temperature Low Cycle Fatigue of Steels and their Welds
p.57

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Numerical Evaluation of Micro- to Macroscopic Mechanical Behavior of Carbon Black-Filled Rubber

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Key Engineering Materials (Volumes 274-276)

Pages:

19-24

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.274-276.19

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Online since:

October 2004

Authors:

Yoshihiro Tomita, Wei Lu, Yasuhiro Furutani

Keywords:

Carbon-Black-Filled Rubber, Computational Simulation, Cyclic Deformation, Molecular Chain Network Theory, Mullins Effect, Nonaffine Model, Rubber

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