Feasibility study of developing hollow-core vacuum insulated panels

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
Mauricio Aguilar Cardenas, Christopher Kendrick, Martin Heywood, S. Resalati
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Abstract

Super-insulation materials have become more commonplace as highly insulated building envelopes are required to reduce the energy demand of buildings aligned with the net zero targets. While several super insulation materials are available, their environmental impacts and practical on-site limitations hindered their large-scale adoption. The following paper investigates the feasibility of developing hollow-core vacuum insulated panels supported by an internal structural array with different configurations. The designed panel was simulated and measured to evaluate its performance as a thermal insulator for building applications. Panel samples were manufactured from polished stainless-steel plates separated by a PTFE structural array. The change in temperature and heat flux through the sample was measured in a vacuum chamber at a pressure of 0.01 Pa. Thermal conductance was obtained from gradual measurements of heat flux and temperature across the sample after a rapid increase in temperature. Numerical methods that combine molecular and macroscopic solvers were used to model unsteady behaviour recorded in empirical tests. Direct Simulation Monte Carlo (DSMC) was used to calculate the thermal conductivity of the rarefied gas, which was then used to solve the enthalpy equation for the multi-region model. Thermal resistance from empirical tests and numerical methods are in agreement within error bands, the greatest accuracy observed in high conductance models. Thermal resistance as low as 0.17 [Formula: see text] and as high as 4.75[Formula: see text] was measured. Low conductance sample configurations were sensitive to thermal contact conductance from the structural array contact interfaces, accounting for at least 40% of transferred energy. Gas conduction at a pressure of 0.01 Pa transfers up to 4% of energy in low emissivity sample configurations. Radiative energy transfer in high conductance configurations was responsible for up to 95% of transferred energy. The paper provides a comprehensive feasibility study, providing a solid foundation for further design optimization of the technology.
开发空心真空绝热板的可行性研究
由于需要高度隔热的建筑围护结构来减少建筑物对能源的需求,以实现净零目标,因此超级隔热材料变得越来越普遍。虽然目前已有几种超级隔热材料,但它们对环境的影响和现场的实际限制阻碍了它们的大规模应用。以下论文研究了开发由不同配置的内部结构阵列支撑的空心真空绝热板的可行性。对所设计的面板进行了模拟和测量,以评估其作为建筑用隔热材料的性能。面板样品由抛光不锈钢板制成,并由聚四氟乙烯结构阵列隔开。在压力为 0.01 Pa 的真空室中测量了样品的温度变化和热通量。热导率是在温度快速升高后,通过逐步测量穿过样品的热通量和温度得到的。结合分子和宏观求解器的数值方法用于模拟经验测试中记录的不稳定行为。直接模拟蒙特卡罗(DSMC)用于计算稀薄气体的热导率,然后用于求解多区域模型的焓方程。经验测试和数值方法得出的热阻在误差范围内是一致的,在高导模型中观察到的热阻精度最高。测得的热阻最低为 0.17[计算公式:见正文],最高为 4.75[计算公式:见正文]。低传导样品配置对来自结构阵列接触界面的热接触传导非常敏感,至少占传递能量的 40%。在低发射率样品配置中,0.01 Pa 压力下的气体传导最多可传递 4% 的能量。在高传导率配置中,辐射能量传递占传递能量的 95%。本文提供了一项全面的可行性研究,为进一步优化该技术的设计奠定了坚实的基础。
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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来源期刊
Journal of Building Physics
Journal of Building Physics 工程技术-结构与建筑技术
CiteScore
5.10
自引率
15.00%
发文量
10
审稿时长
5.3 months
期刊介绍: Journal of Building Physics (J. Bldg. Phys) is an international, peer-reviewed journal that publishes a high quality research and state of the art “integrated” papers to promote scientifically thorough advancement of all the areas of non-structural performance of a building and particularly in heat, air, moisture transfer.
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