Influence of Long-Term Moisture Exposure and Temperature on the Mechanical Properties of Hybrid FRP Composite Specimens

IF 3 Q2 MATERIALS SCIENCE, COMPOSITES

Journal of Composites Science Pub Date : 2024-08-09 DOI:10.3390/jcs8080312

Getahun Tefera, Glen Bright, S. Adali

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Abstract

The present experimental study assesses the mechanical properties of glass/carbon/glass hybrid composite laminates after being exposed to moisture in a deep freezer and elevated temperatures for extended periods. The top and bottom layers of the hybrid laminates are reinforced with glass fibre, and the middle layer is reinforced with carbon fibre using the epoxy matrix as a binder polymer material. The hybrid laminates were manufactured using the resin transfer moulding method, and their compressive and tensile properties were determined using a tensile testing machine. The storage modulus, loss modulus, and damping factors of all groups of laminates were identified using a dynamic mechanical analysis as a function of temperature and vibration frequency. The experimental results on compressive and tensile properties revealed slight variations when the hybrid laminates were kept at low temperatures in a deep freezer for extended periods. This might occur due to the increasing molecular crosslinking of the polymer network. As the testing temperature increased, compressive, tensile, storage modules, loss modulus, and damping factors decreased. This might occur due to the increasing mobility of the binder material. Particularly, the highest stiffness parameters were obtained at −80 °C/GCG (glass/carbon/glass) laminates due to the presence of a beta transition in the glassy region. The relationships between the glass transitions and the targeted frequencies were characterized. The values of the glass transition shift towards higher temperatures as the frequency increases. This might occur due to a reduction in the gaps between the crosslinking of the epoxy network when the frequency increases. The accuracy of the storage modulus results was compared with the empirical models. The model based on the Arrhenius law provided the closest correlation. Meanwhile, another model was observed that was not accurate enough to predict when gamma and beta relaxations occur in a glassy state.

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长期湿度暴露和温度对混合玻璃钢复合材料试样力学性能的影响

本实验研究评估了玻璃/碳/玻璃混合复合材料层压板长期暴露于深冷冻室的潮湿环境和高温下的机械性能。混合层压板的顶层和底层用玻璃纤维增强，中间层用碳纤维增强，使用环氧树脂基体作为粘结聚合物材料。混合层压板是用树脂传递模塑法制造的，其压缩和拉伸性能是用拉伸试验机测定的。利用动态力学分析确定了各组层压板的存储模量、损耗模量和阻尼系数与温度和振动频率的函数关系。压缩和拉伸性能的实验结果表明，当混合层压板在低温深冷冻箱中长时间保存时，其压缩和拉伸性能略有变化。这可能是由于聚合物网络的分子交联增加所致。随着测试温度的升高，压缩、拉伸、存储模块、损失模量和阻尼系数都有所下降。这可能是由于粘合剂材料的流动性增加所致。特别是在-80 °C/GCG（玻璃/碳/玻璃）层压板中获得了最高的刚度参数，这是因为玻璃区域存在贝塔转变。玻璃转变与目标频率之间的关系得到了表征。随着频率的增加，玻璃转化值会向更高的温度移动。这可能是由于频率升高时环氧网络交联间隙减小所致。将存储模量结果的准确性与经验模型进行了比较。基于阿伦尼乌斯定律的模型提供了最接近的相关性。同时，还观察到另一种模型在预测玻璃态发生伽马和贝塔弛豫时不够准确。

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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