Simulation of the Deformation Diagram of a Viscoelastic Material Based on a Structural Model

IF 0.9 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
A. S. Kurkin, A. S. Kiselev, S. V. Krasheninnikov, A. A. Bogdanov
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Abstract

A serious problem in computer simulation of a stress state of polymer structures is to validate the mathematical description of the mechanical properties of materials. The structural model of a viscoelastic material has a number of advantages in describing both the rheology of a material and strain curves of it. In this model, a material is described as a structure consisting of several elements with relatively simple rheological properties. Reproduction of a complex behavior of a material under alternating non-isothermal loading is provided through the interaction of these simple elements. A technique developed in this work for modeling a viscoelastic material is intended for strength calculations of structures made of materials operating under conditions of a long-term repetitive thermomechanical impact using the finite element method. The application of the developed procedure to a polymeric material, polymethyl methacrylate (PMMA), is considered. The results of testing this material under uniaxial compression at a constant temperature are presented. The methodology and results of identification of the developed structural model using a specialized software code are described. Formulas are obtained for the approximation of the deformation characteristics of the material at a constant strain rate and for the time dependence of the deformation of the material during its holding at a constant stress level. Approximation is an important stage in the validation of the material model, which facilitates the systematization of the initial experimental data and their further mathematical processing. The best approximation of the deformation characteristics of a viscoelastic material is provided by a hyperbolic tangent function, whereas a logarithmic function provides the best results for the deformation upon holding. Further construction of the structural model was performed by selecting sequential parameters of bilinear rheological functions of the separate elements of the model and by iterative refinement of these parameters. The simulation results are compared with the experiments performed at different strain rates and with holding at different stress levels. In this work, the results of the initial stage of the performed experimental and theoretical studies are presented.

Abstract Image

Abstract Image

基于结构模型的粘弹性材料变形图模拟
摘要 在对聚合物结构的应力状态进行计算机模拟时,一个严重的问题是验证材料力学特性的数学描述。粘弹性材料的结构模型在描述材料的流变学和应变曲线方面有许多优点。在该模型中,材料被描述为由多个元素组成的结构,其流变特性相对简单。通过这些简单元素的相互作用,可以再现材料在交变非等温载荷作用下的复杂行为。这项工作中开发的粘弹性材料建模技术旨在利用有限元方法,对长期重复热机械冲击条件下的材料结构进行强度计算。本研究考虑将所开发的程序应用于聚合材料聚甲基丙烯酸甲酯(PMMA)。介绍了在恒温条件下对这种材料进行单轴压缩测试的结果。介绍了使用专用软件代码识别所开发结构模型的方法和结果。获得了材料在恒定应变速率下的变形特征近似公式,以及材料在恒定应力水平下保持变形过程中的时间相关性公式。近似是验证材料模型的一个重要阶段,它有助于初始实验数据的系统化和进一步的数学处理。双曲正切函数提供了粘弹性材料变形特征的最佳近似值,而对数函数则提供了保持时变形的最佳结果。结构模型的进一步构建是通过选择模型各独立元素的双线性流变函数的连续参数以及对这些参数的迭代改进来实现的。模拟结果与在不同应变速率和不同应力水平下进行的实验进行了比较。本文介绍了实验和理论研究的初始阶段结果。
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来源期刊
Inorganic Materials
Inorganic Materials 工程技术-材料科学:综合
CiteScore
1.40
自引率
25.00%
发文量
80
审稿时长
3-6 weeks
期刊介绍: Inorganic Materials is a journal that publishes reviews and original articles devoted to chemistry, physics, and applications of various inorganic materials including high-purity substances and materials. The journal discusses phase equilibria, including P–T–X diagrams, and the fundamentals of inorganic materials science, which determines preparatory conditions for compounds of various compositions with specified deviations from stoichiometry. Inorganic Materials is a multidisciplinary journal covering all classes of inorganic materials. The journal welcomes manuscripts from all countries in the English or Russian language.
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