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A thermo-viscoelastic-damage constitutive model for cyclically loaded rubbers. Part I: Model formulation and numerical examples

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Indexed by:期刊论文

Date of Publication:2018-02-01

Journal:INTERNATIONAL JOURNAL OF PLASTICITY

Included Journals:SCIE、EI、Scopus

Volume:101

Page Number:106-124

ISSN No.:0749-6419

Key Words:Thermo-viscoelastic-damage coupling; Fatigue; Dissipative heating; Rubbers

Abstract:Cyclically loaded rubbers exhibit a complex history-dependent response characterized by fatigue induced stress-softening and hysteresis along with dissipative heating. The coupling between these different inelastic effects usually appearing together is far from being fully established. In this Part I of two-part paper, we present a new thermo-viscoelastic-damage approach, in accordance with the thermodynamic principles, for the prediction of this set of inelastic fatigue phenomena. An interpretation of the underlying physical mechanisms is proposed in which two types of dissipative network rearrangements are considered, i.e. recoverable rearrangements inducing viscoelasticity and Unrecoverable rearrangements inducing damage. The recoverable viscoelastic rearrangements are assumed to be induced by the move of entangled and non-entangled free chains superimposed on a purely elastic perfect rubber network. Each population of free chains is considered to be the main source of one aspect of the history-dependent mechanical cyclic features, i.e. stress-softening and hysteresis, respectively. The thermo-mechanical coupling is defined by postulating the existence of a free energy in which two internal state variables are introduced to account for the two types of dissipative network rearrangements. Network thermal kinetics, induced by the dissipative heating, as well as network damage kinetics, induced by the fatigue damage, are defined and used to alter the cyclically loaded perfect rubber network. The proposed constitutive model is implemented into a finite element program and a parametric study is presented via numerical applications on rubber structures in order to analyze the effects of key model parameters on the rubber inelastic fatigue response. A focus is especially made on the respective influence of temperature, viscoelasticity and damage on the rubber softening.

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