High-Temperature Performance Evaluation of a Novel Graphene-Based Aerogel

B. Mourched, N. Abboud, M. Abdallah
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Abstract

This paper provides an in-depth analysis of the thermal and mechanical properties of Ethylenediamine Graphene Aerogel (EGA) using COMSOL Multiphysics software. The study focuses on understanding the stress distribution and mechanical responses of this material under various conditions. Thermal stress applied to the bottom of a cylindrical structure revealed distinct stress patterns over time and temperature. High-stress regions were noted towards the cylinder's center, suggesting the effects of temperature fluctuations, while the upper surface experienced lower stress. The von Mises stress increased over time, indicating the material's response to heat, particularly near the heat source, and stabilized around 40 minutes, suggesting a new thermal equilibrium. A critical observation was made at a critical region from the cylinder's bottom, where a significant shift in stress patterns and performance characteristics occurred, emphasizing the need to consider these variations in design for safety and functionality. This study highlights the material ’ s low thermal conductivity and its role in temperature distribution, demonstrating its capability to manage thermal expansion effectively. These properties make the Ethylenediamine Graphene Aerogel suitable for high-temperature applications such as aerospace, automotive, and thermal barrier systems, and open avenues for further applications.
新型石墨烯基气凝胶的高温性能评估
本文使用 COMSOL Multiphysics 软件对乙二胺石墨烯气凝胶 (EGA) 的热性能和机械性能进行了深入分析。研究重点是了解这种材料在各种条件下的应力分布和机械响应。对圆柱形结构底部施加的热应力显示了随时间和温度变化的不同应力模式。在圆柱体中心发现了高应力区域,这表明受到了温度波动的影响,而上表面的应力较低。随着时间的推移,冯-米塞斯应力不断增加,表明材料对热的反应,尤其是在热源附近,并在 40 分钟左右趋于稳定,表明出现了新的热平衡。在圆筒底部的关键区域进行了重要观察,发现应力模式和性能特征发生了显著变化,强调了在设计中考虑这些变化以确保安全和功能的必要性。这项研究强调了材料的低导热性及其在温度分布中的作用,证明了其有效管理热膨胀的能力。这些特性使乙二胺石墨烯气凝胶适用于航空航天、汽车和热屏障系统等高温应用,并为进一步的应用开辟了道路。
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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