Moisture Diffusion in Multi-Layered Materials: The Role of Layer Stacking and Composition

Shaojie Zhang, Yuhao Liu, Peng Feng, Pavana Prabhakar
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Abstract

Multi-layered materials are everywhere, from fiber-reinforced polymer composites (FRPCs) to plywood sheets to layered rocks. When in service, these materials are often exposed to long-term environmental factors, like moisture, temperature, salinity, etc. Moisture, in particular, is known to cause significant degradation of materials like polymers, often resulting in loss of material durability. Hence, it is critical to determine the total diffusion coefficient of multi-layered materials given the coefficients of individual layers. However, the relationship between a multi-layered material's total diffusion coefficient and the individual layers' diffusion coefficients is not well established. Existing parallel and series models to determine the total diffusion coefficient do not account for the order of layer stacking. In this paper, we introduce three parameters influencing the diffusion behavior of multi-layered materials: the ratio of diffusion coefficients of individual layers, the volume fraction of individual layers, and the stacking order of individual layers. Computational models are developed within a finite element method framework to conduct parametric analysis considering the proposed parameters. We propose a new model to calculate the total diffusion coefficient of multi-layered materials more accurately than current models. We verify this parametric study by performing moisture immersion experiments on multi-layered materials. Finally, we propose a methodology for designing and optimizing the cross-section of multi-layered materials considering long-term moisture resistance. This study gives new insights into the diffusion behavior of multi-layered materials, focusing on polymer composites.
多层材料中的水分扩散:层堆叠和成分的作用
从纤维增强聚合物复合材料(FRPC)到胶合板,再到多层岩石,多层材料无处不在。在使用过程中,这些材料通常会长期暴露在潮湿、温度、盐度等环境因素中。众所周知,湿气尤其会导致聚合物等材料发生严重降解,从而导致材料耐久性下降。因此,根据单层材料的扩散系数确定多层材料的总扩散系数至关重要。然而,多层材料的总扩散系数与单层材料的扩散系数之间的关系并没有得到很好的确定。现有的用于确定总扩散系数的并联和串联模型没有考虑层堆叠的顺序。在本文中,我们引入了影响多层材料扩散行为的三个参数:单层扩散系数比、单层体积分数和单层堆积顺序。我们在有限元方法框架内建立了计算模型,以考虑所提出的参数进行参数分析。与现有模型相比,我们提出了一种新模型,可以更精确地计算多层材料的总扩散系数。我们通过对多层材料进行湿气浸泡实验来验证这一参数研究。最后,我们提出了一种考虑长期耐湿性的多层材料横截面设计和优化方法。这项研究为多层材料的扩散行为提供了新的见解,重点是聚合物复合材料。
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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