Modelling the Time-Dependent Behavior of Elastomers Using Fractional Viscoelastic Material Formulations

A. Leenders, Hamed Vahdati Zadeh, M. Wangenheim
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Abstract

Elastomer materials are often used for components such as tire treads or hydraulic sealings, when deformable and damping behavior of components are desired and high dynamic loads appear. Such elastomers show time- and frequency-dependent characteristics, called viscoelasticity. The modelling of viscoelastic material is mainly implemented in simulations by rheological models, which often consists of elastic and damping elements. A viscoelastic model can be parametrized to experimental data to describe a specific elastomer with high accuracy. The most common model is the Prony-series. This model uses several Maxwell-branches (connection of one elastic and one damping element in series). Every branch is only able to fit the experimental behavior at one single excitation frequency. This fact makes it necessary to use a lot of parameters for adapting the frequency- and temperature-dependent characteristics over decades of the excitation frequency. To overcome this need for a huge amount of parameters we formulate a fractional viscoelastic model approach that gets along with a much smaller set of parameters, using finite elements. In order to reduce the numerical effort, a similarly formulated model is set up on force-displacement level additionally. In this way, the complexity of the simulation can be reduced with mapping of the material behavior.
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用分数黏弹性材料公式模拟弹性体的时间依赖性行为
弹性体材料通常用于轮胎胎面或液压密封件等部件,当需要部件的变形和阻尼性能并且出现高动载荷时。这种弹性体表现出与时间和频率相关的特性,称为粘弹性。粘弹性材料的建模主要是通过流变模型来实现的,流变模型通常由弹性和阻尼元件组成。粘弹性模型可以与实验数据进行参数化,以高精度地描述特定弹性体。最常见的型号是prony系列。该模型采用了多个麦克斯韦分支(一个弹性单元和一个阻尼单元串联连接)。每个支路只能在一个单一的激励频率下符合实验行为。这一事实使得有必要使用许多参数来适应频率和温度相关的特性,超过几十年的激励频率。为了克服对大量参数的需求,我们制定了一种分数粘弹性模型方法,该方法可以使用更小的参数集,使用有限元。为了减少数值计算的工作量,另外在力-位移水平上建立了类似的公式模型。通过这种方式,可以通过映射材料的行为来降低模拟的复杂性。
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