Micro-sphere model for strain-induced crystallization in rubber

J. Guilie; L. Thien Nga; P. Le Tallec

doi:10.1201/b14964-87

Micro-sphere model for strain-induced crystallization in rubber

J. Guilie
, L. Thien Nga
, P. Le Tallec

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Natural rubber is known to crystallize under strain so that samples subjected to loadingunloading cycles exhibit hysteresis. In the present paper, an anisotropic constitutive model for straininduced crystallization rubber is proposed based on review of the numerous experiments conducted on this material. Detailed information on the semi-crystalline system is therefore available, particularly simultaneous measurements of stress and crystallinity versus elongation. Then, introducing an internal variable associated to crystallinity, a solution to the evolution of this variable can be found, that is thermodynamically consistent. This 1D model is then plugged into a micro-sphere approach. In this approach, each direction is free to have its own history, which allows us to obtain an evolving anisotropy. This model is assessed by uniaxial tensile tests under cyclic loadings and anisotropy measurements.

Original language	English
Title of host publication	Constitutive Models for Rubber VIII
Publisher	CRC Press
Pages	467-472
Number of pages	6
ISBN (Electronic)	9781315884844
ISBN (Print)	9781138000728
DOIs	https://doi.org/10.1201/b14964-87
Publication status	Published - 1 Jan 2013

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title = "Micro-sphere model for strain-induced crystallization in rubber",

abstract = "Natural rubber is known to crystallize under strain so that samples subjected to loadingunloading cycles exhibit hysteresis. In the present paper, an anisotropic constitutive model for straininduced crystallization rubber is proposed based on review of the numerous experiments conducted on this material. Detailed information on the semi-crystalline system is therefore available, particularly simultaneous measurements of stress and crystallinity versus elongation. Then, introducing an internal variable associated to crystallinity, a solution to the evolution of this variable can be found, that is thermodynamically consistent. This 1D model is then plugged into a micro-sphere approach. In this approach, each direction is free to have its own history, which allows us to obtain an evolving anisotropy. This model is assessed by uniaxial tensile tests under cyclic loadings and anisotropy measurements.",

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N2 - Natural rubber is known to crystallize under strain so that samples subjected to loadingunloading cycles exhibit hysteresis. In the present paper, an anisotropic constitutive model for straininduced crystallization rubber is proposed based on review of the numerous experiments conducted on this material. Detailed information on the semi-crystalline system is therefore available, particularly simultaneous measurements of stress and crystallinity versus elongation. Then, introducing an internal variable associated to crystallinity, a solution to the evolution of this variable can be found, that is thermodynamically consistent. This 1D model is then plugged into a micro-sphere approach. In this approach, each direction is free to have its own history, which allows us to obtain an evolving anisotropy. This model is assessed by uniaxial tensile tests under cyclic loadings and anisotropy measurements.

AB - Natural rubber is known to crystallize under strain so that samples subjected to loadingunloading cycles exhibit hysteresis. In the present paper, an anisotropic constitutive model for straininduced crystallization rubber is proposed based on review of the numerous experiments conducted on this material. Detailed information on the semi-crystalline system is therefore available, particularly simultaneous measurements of stress and crystallinity versus elongation. Then, introducing an internal variable associated to crystallinity, a solution to the evolution of this variable can be found, that is thermodynamically consistent. This 1D model is then plugged into a micro-sphere approach. In this approach, each direction is free to have its own history, which allows us to obtain an evolving anisotropy. This model is assessed by uniaxial tensile tests under cyclic loadings and anisotropy measurements.

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BT - Constitutive Models for Rubber VIII

PB - CRC Press

ER -

Micro-sphere model for strain-induced crystallization in rubber

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