Optimization strategies of the envelope insulation for a detached house based on load sensitivity and thermal storage performance

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
Botao Zhou, Juan Zhao, Yongcai Li, Junmei Gao, Bojing Huang, Ritu Wu, Wenjie Zhang, Biao Tan
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Abstract

Reasonable thermal insulation in cold regions is the key to improve the indoor thermal environment. In this paper, the detached house is taken as the research object, and the sensitivity analysis method is used to quantify the influence of each parameter on the building heat load in three different climate zones. The attenuation characteristics of the heat storage body to the outdoor temperature wave are studied by using the A·M Shklovel calculation method, and the thermal insulation strategy of the envelope structure is optimized by genetic algorithm (GA). The results show that the heat transfer coefficient of roof and exterior wall has the most significant influence on the building heat load. The mean effect response of each factor shows that the Delta (Delta is the value used in Taguchi design methodology to express the relative effect of each factor on the response) of roofs in the three regions is the highest, 3.061, 4.061, and 5.88, respectively. The influence of the type and thickness of the insulation material on the heat storage performance is different. The indoor and outdoor temperature wave penetration attenuation multiple increases with the increase of the thickness of the insulation layer, increases with the decrease of the thermal conductivity of the insulation material, and increases with the increase of the specific heat capacity. The choice of insulation materials is not only related to the above two parameters, but also directly affected by the price. Considering the influence of various factors, the economy of choosing expanded polystyrene board for thermal insulation in the three regions is the best. The optimal thermal insulation thickness of the north wall and roof is 8 and 16 cm (3A climate zone), 10 and 17 cm (2B climate zone), 13 and 20 cm (2A climate zone), respectively.
基于负荷敏感性和蓄热性能的独立式住宅围护结构隔热优化策略
寒冷地区合理的保温隔热措施是改善室内热环境的关键。本文以独立式住宅为研究对象,采用敏感性分析方法量化了三个不同气候区各参数对建筑热负荷的影响。利用 A-M Shklovel 计算方法研究了蓄热体对室外温度波的衰减特性,并通过遗传算法(GA)优化了围护结构的保温策略。结果表明,屋顶和外墙的传热系数对建筑热负荷的影响最大。各因素的平均效应响应显示,三个区域中屋顶的 Delta 值(Delta 值是 Taguchi 设计方法中用来表示各因素对响应的相对影响的值)最高,分别为 3.061、4.061 和 5.88。隔热材料的类型和厚度对蓄热性能的影响不同。室内外温度波穿透衰减倍数随隔热层厚度的增加而增加,随隔热材料导热系数的降低而增加,随比热容的增加而增加。隔热材料的选择不仅与上述两个参数有关,还直接受到价格的影响。综合考虑各种因素的影响,三地选择膨胀聚苯板做保温材料的经济性最好。北墙和屋顶的最佳保温厚度分别为 8 厘米和 16 厘米(3A 气候区)、10 厘米和 17 厘米(2B 气候区)、13 厘米和 20 厘米(2A 气候区)。
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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