A new class of Finitely Extensible Nonlinear Elastic (FENE-P) models obtained with a thermodynamical approach and the use of compressible natural configurations. Part II: Decoupled thermo-mechanical deformations

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
J.P. Gomez-Constante, L.I. Palade
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引用次数: 0

Abstract

In this paper which is the continuation of the isothermal viscoelastic model presented in Gomez-Constante and Palade (2023), we incorporate temperature changes into our model. To achieve this, we present a temperature dependent Helmholtz potential from where the model will be derived using the idea of evolving natural configurations. To simplify the analysis, we assume that the temperature and the invariants of deformation are decoupled so the Helmholtz potential can be expressed as the product of two independent functions. The model thus derived is consistent with fundamental thermodynamical postulates and constrains. To show its qualitative behavior we chose to compare the isothermal model in Gomez-Constante and Palade (2023) with this paper non-isothermal version of the model and show how they behave in the classical Couette flow between infinite parallel plates and analyze their differences. We also present a simple extensional flow simulation for the non-isothermal version of the model to complete the analysis. Ideas towards the following steps towards a generalization of the model are also presented and discussed.

利用热力学方法和可压缩的自然构形,得到了一类新的有限可扩展非线性弹性(FENE-P)模型。第二部分:解耦热机械变形
本文是Gomez-Constante和Palade(2023)中提出的等温粘弹性模型的延续,我们将温度变化纳入了我们的模型。为了实现这一目标,我们提出了一个温度依赖的亥姆霍兹势,从这个势中,模型将使用进化的自然构型的思想推导出来。为了简化分析,我们假设温度和变形的不变量是解耦的,因此亥姆霍兹势可以表示为两个独立函数的乘积。由此导出的模型符合基本的热力学假设和约束。为了展示其定性行为,我们选择将Gomez-Constante和Palade(2023)的等温模型与本文的非等温模型进行比较,并展示它们在无限平行板之间的经典Couette流中的行为,并分析它们的差异。我们还提出了一个简单的非等温版本模型的扩展流模拟来完成分析。还提出并讨论了对模型进行推广的后续步骤的想法。
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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
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审稿时长
68 days
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