Viscoelastic model with complex rheological behavior (VisCoR): incremental formulation

IF 1.8 Q3 ENGINEERING, MANUFACTURING

Advanced Manufacturing: Polymer & Composites Science Pub Date : 2020-01-02 DOI:10.1080/20550340.2019.1709010

S. Saseendran, D. Berglund, J. Varna

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引用次数: 7

Abstract

Abstract A thermo-rheologically complex linear viscoelastic material model, accounting for temperature and degree of cure (DoC), is developed starting with series expansion of the Helmholtz free energy and systematically implementing simplifying assumptions regarding the material behavior. In addition to the temperature and DoC dependent shift factor present in rheologically simple models, the derived novel model contains three cure and temperature dependent functions. The first function is identified as the rubbery modulus. The second is a weight factor to the transient integral term in the model and reflects the current temperature and cure state, whereas the third function is under the sign of the convolution integral, thus affecting the “memory” of the material. An incremental form of this model is presented which, due to improved approximation inside the time increment, has better numerical convergence than most of the similar forms. Parametric analysis is performed simulating stress development in a polymer, geometrically constrained in the mold during curing and cool-down. The importance of using proper viscoelastic model is shown, and the role of parameters in the model is revealed and discussed. Graphical Abstract

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具有复杂流变行为的粘弹性模型(visor):增量公式

从亥姆霍兹自由能的级数展开出发，系统地实现了材料行为的简化假设，建立了考虑温度和固化度的热流变复杂线性粘弹性材料模型。除了存在于流变简单模型中的温度和DoC相关位移因子外，导出的新模型还包含三个固化和温度相关函数。第一个函数被确定为橡胶模量。第二个函数是模型中瞬态积分项的权重因子，反映当前温度和固化状态，而第三个函数是在卷积积分的符号下，从而影响材料的“记忆”。该模型的增量形式由于在时间增量范围内的改进逼近，比大多数同类形式具有更好的数值收敛性。参数分析进行模拟应力发展的聚合物，几何约束在模具期间固化和冷却。指出了使用合适的粘弹性模型的重要性，并揭示和讨论了参数在模型中的作用。图形抽象

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