Phenomenological constitutive laws for the dissipative behaviour of highly compressible elastomers and their finite element implementation

IF 4.4 2区 工程技术 Q1 MECHANICS
Manon Bour , Stéphane Méo , Guénhaël Le Quilliec , Florent Chalon , Matthieu Raymond , Didier Picart
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引用次数: 0

Abstract

This paper deals with the development of constitutive equations to model the mechanical behaviour of compressible elastomers. These materials are naturally incompressible but can be made compressible by the addition of hollow microspheres, for example. Such a material is referred to as syntactic foam. The CEA (French Commission for Atomic and Alternative Energies) employs such compressible materials as seals in complex structures to reduce the internal stresses in vulnerable components and prevent their failure. The behaviour of these structures is predicted by finite element simulations. It is important to know and model the mechanical behaviour of the seals. Like elastomers, they can undergo large deformations. The microspheres enable the material to undergo large volume change unlike pure elastomer that is nearly incompressible. This compressibility also intensifies dissipative phenomena encountered in elastomers such as viscosity or plasticity. Furthermore, the Mullins stress softening effect is also intensified even for loadings that only bring about volumetric changes. To model these behaviours, a phenomenological approach was developed based on the isochoric/volumetric decomposition of the deformation gradient. The method of intermediate dissipative configurations was employed to introduce multiple phenomena, including viscosity (with several characteristic times) and viscoplasticity, for these two parts of the deformation. The constitutive equations and their flow rules were implemented in Abaqus through a UMAT subroutine and using a numerical approach to define the tangent operator. The parameters of the behaviour law were identified using a model reduction technique known as shape manifold approach. The resulting model can be compared with experimental data.

高度可压缩弹性体耗散行为的现象构成定律及其有限元实现
本文论述了可压缩弹性体机械行为建模构成方程的开发。这些材料天然不可压缩,但可以通过添加空心微球等方法使其可压缩。这种材料被称为合成泡沫。法国原子能和替代能源委员会(CEA)在复杂的结构中使用这种可压缩材料作为密封件,以减少易损部件的内应力,防止其失效。这些结构的行为是通过有限元模拟来预测的。了解和模拟密封件的机械性能非常重要。与弹性体一样,密封件也会发生较大的变形。与几乎不可压缩的纯弹性体不同,微球使材料能够发生较大的体积变化。这种可压缩性也加剧了弹性体中的耗散现象,如粘度或塑性。此外,穆林斯应力软化效应也会增强,即使是只带来体积变化的载荷。为了模拟这些行为,我们开发了一种基于变形梯度等时/体积分解的现象学方法。采用中间耗散构型法为这两部分变形引入了多种现象,包括粘性(具有多个特征时间)和粘塑性。在 Abaqus 中通过 UMAT 子程序实现了构成方程及其流动规则,并使用数值方法定义了切线算子。使用一种称为形状流形方法的模型还原技术确定了行为规律的参数。得出的模型可与实验数据进行比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.00
自引率
7.30%
发文量
275
审稿时长
48 days
期刊介绍: The European Journal of Mechanics endash; A/Solids continues to publish articles in English in all areas of Solid Mechanics from the physical and mathematical basis to materials engineering, technological applications and methods of modern computational mechanics, both pure and applied research.
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