The Comparison of Fractional Derivative Model and Classical Spring-Dashpot Model in the Identification of Viscoelastic Characteristics of a Rubber Material

EPI International Journal of Engineering Pub Date : 2021-09-15 DOI:10.25042/epi-ije.022021.06

D. Narita, Y. Ohta

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Abstract

In the design of viscoelastic materials used in rubber products, not theoretical approaches but experimental approaches have been usually employed. This is due to the difficulties in mathematical procedures of the dynamic material characteristics such as the dependencies of strain amplitude, frequency and/or environmental temperature in deformation. In mathematical approach there are two kind of analytical models for a complex module of the material, which are a fractional derivative model and a spring-dashpot model. However there are few papers dealing with the study of the identifications of parameters for the experimental modulus actually obtained not only by using the fractional derivative model but also by using the spring-dashpot model and the discussion of the comparisons of the two models. In the present paper, the complex elastic modulus for a rubber material are obtained experimentally for a wide range of excitation frequency, and the modulus-frequency relations are derived analytically by using the two models, respectively. Finally, the applicability of the models are discussed from the numerical results.

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分数阶导数模型与经典弹簧-阻尼器模型在橡胶材料粘弹性特性辨识中的比较

在橡胶制品粘弹性材料的设计中，通常采用实验方法而不是理论方法。这是由于材料的动态特性，如应变幅度、频率和/或环境温度对变形的依赖关系，在数学过程中存在困难。在数学方法上，对材料的复杂模块有两种解析模型，即分数阶导数模型和弹簧-阻尼器模型。然而，关于既采用分数阶导数模型又采用弹簧-阻尼器模型确定试验模量参数的研究以及对两种模型的比较讨论的文章却很少。本文通过实验得到了橡胶材料在较宽激励频率范围内的复弹性模量，并分别用这两种模型解析导出了模频关系。最后，从数值结果讨论了模型的适用性。

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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EPI International Journal of Engineering

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