用低导热气体填充缝隙对带纱窗单元热保护的影响

G. Parfenov, N.N. Smirnov, V. Tyutikov, E.N. Bushuev, E.A. Shuina
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引用次数: 0

摘要

ISPU 的科学家们已经开发出带有热反射屏的节能窗单元结构,并在气候室中进行了测试,还对通过这些结构的传热过程进行了模拟建模。尽管有大量科学论文对通过半透明结构的传热过程进行了实验室实验研究和数值模拟,但还没有数据表明在玻璃和金属元件形成的缝隙中使用低导热气体对提高带纱窗单元的热保护效果有什么影响。正确计算带纱窗和低导热气体的窗单元所减少的热传导阻力会影响房屋热平衡的正确性,进而影响确保室内微气候的能源系统设计质量。因此,为确保室内微气候,当务之急是开发通过带纱窗的窗单元的传热过程模型。仿真数值模型是在传热基本定律的基础上采用有限元法进行的。作者建立了一个带有热反射纱窗的窗单元传热二维模拟模型,其中玻璃和铝箔之间的间隙填充了氩气和氪气。研究了热传导阻力沿半透明围护结构高度的分布情况。通过与其他科学家的数据和法规文件进行比较,证实了所提出的模拟模型的适当性。在玻璃和金属箔之间填充氩气,可使带纱窗的窗户单元的区域传热阻力比基础方案(空气)增加 6-23%,氪气增加 8-58%(取决于测量位置和纱窗数量)。通过应用所开发的模拟模型,可以更准确地确定在建筑物的间歇式供暖系统中使用窗户热反射纱窗的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Influence of filling gaps with low thermal conductivity gases on thermal protection of window units with screens
ISPU scientists have developed energy-saving constructions of window units with heat-reflecting screens, have tested them in a climate chamber, and have carried out simulation modeling of the heat transfer process through these constructions. Despite a large number of scientific papers that consider experimental laboratory studies and numerical simulation of heat transfer processes through translucent constructions, there is no data on the effect of the application of low thermal conductivity gases in the gaps formed by glass and metal elements on increasing the thermal protection of window units with screens. The correct calculation of the reduced heat transfer resistance of window units with screens and low-thermal conductivity gases affects the correctness of the heat balance for premises and, consequently, the quality of the design of energy systems to ensure the indoor microclimate. Thus, the development of models of heat transfer process through a window unit with screens is an urgent task to ensure the indoor microclimate. Simulation numerical modeling is carried out using the finite element method based on the fundamental laws of heat transfer. The authors have developed a two-dimensional simulation model of heat transfer through a window unit with heat-reflecting screens, in which the gaps between the glass and aluminum foil are filled with argon and krypton. The distribution of resistance to heat transfer along the height of a translucent enclosing structure has been studied. The adequacy of the proposed simulation model is confirmed by comparison with data of other scientists and regulatory documentation. Filling the gaps between glass and metal foil with argon makes it possible to increase the zonal heat transfer resistance of a window unit with screens in relation to the base-case scenario (air) by 6–23 %, krypton by 8–58 % (depending on the measurement location and the number of screens). The application of the developed simulation model will make it possible to more accurately determine the potential to use heat-reflecting screens in windows for intermittent heating systems of buildings.
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