Numerical modeling for evaluation of the thermal resistance of reflective airspaces with and without defects

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
H. Saber, D. Yarbrough
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Abstract

The thermal resistances (R-values) of airspaces depends on the emittance of all surfaces around an airspace, dimensions, heat-flow direction, and the temperatures of the bounding surfaces. Assessing the energy performance of building envelope components and fenestration systems requires accurate results for the R-values of any enclosed spaces. The evaluation of reflective insulation R-values has evolved to include use of computational fluid dynamics and surface-to-surface radiation to quantify convective and radiative contributions to the heat transfer across airspaces of all types. This paper compares an advanced and validated model for calculating enclosed airspace R-values with the widely-used ISO 6946 and airspace R-values in the ASHRAE Handbook-Fundamentals. The impact of construction and installation defects on the thermal performance of reflective insulation has not been previously evaluated. In this research, an advanced model was used to evaluate a construction defect and dimensional aspect ratios that one-dimensional methods do not address. Imperfect installation and defects that result in air movement into or through a reflective insulation assembly reduces the thermal resistance of the assembly. Additionally, the amount of thermal resistance reduction depends on the amount and temperature of invasive air or the size of internal defects that allows natural convection inside the reflective airspace. In this study, these performance issues are evaluated quantitatively using computer simulation techniques. The differences in results obtained using methods that are currently being used to evaluate the R-value and the advantages of the advanced method for evaluating the reflective insulation performance for different applications are discussed. For the case considered in this study, the results showed that the failure to achieve parallel surfaces results in less than a 5% decrease in thermal resistance. Also, the results showed that internal air gaps between airspaces result in negligible loss in R-value unless air gaps that allow circulation between airspaces are created.
有缺陷和无缺陷反射空气空间热阻评估的数值模拟
空气空间的热阻(r值)取决于空气空间周围所有表面的发射度、尺寸、热流方向和边界表面的温度。评估建筑围护结构组件和开窗系统的能源性能需要对任何封闭空间的r值进行准确的结果。反射隔热r值的评估已经发展到包括使用计算流体动力学和地对地辐射来量化对流和辐射对所有类型空气空间传热的贡献。本文将计算封闭空域r值的先进且经过验证的模型与广泛使用的ISO 6946和ASHRAE手册-基础中的空域r值进行了比较。施工和安装缺陷对反射隔热材料热性能的影响以前没有被评估过。在这项研究中,一个先进的模型被用来评估一维方法无法解决的结构缺陷和尺寸宽高比。不完美的安装和缺陷会导致空气进入或穿过反射绝缘组件,从而降低组件的热阻。此外,热阻减少的量取决于侵入空气的数量和温度,或允许反射空域内自然对流的内部缺陷的大小。在本研究中,使用计算机模拟技术对这些性能问题进行了定量评估。讨论了目前用于评估r值的方法所获得的结果的差异以及用于评估不同应用的反射绝缘性能的先进方法的优点。对于本研究中考虑的情况,结果表明,未能实现平行表面导致热阻下降不到5%。此外,结果表明,除非在空气空间之间创建允许循环的空气间隙,否则空气空间之间的内部气隙导致r值的损失可以忽略不计。
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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