Experimental study on effect of an active solar heating soil heat storage system on the thermal environment in Gobi solar greenhouses

IF 6.6 2区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Energy and Buildings Pub Date : 2024-11-13 DOI:10.1016/j.enbuild.2024.115055
Jing Zhao , Foping Chen , Yingmei Wang , Kezhen Wang , Xueli Zhai , Dong Zhang
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Abstract

The present study proposes an innovative active solar heating soil heat storage system to enhance the thermal environment of Gobi solar greenhouses (GSGs) and address the issue of uneven heat distribution. This system utilizes Gobi gravel soil as a heat storage medium, combining solar flat plate collectors and horizontal buried pipes at a depth of 0.15 m. To validate the system’s practical efficacy, an 80-day field experiment was conducted in Jiuquan City, located in the northwest Gobi region of China. The experiment focused on investigating the impact of soil heat storage on the temporal and spatial distribution of air and soil temperatures within the greenhouse, as well as assessing the system’s environmental and economic benefits. The results demonstrated that the system exhibited outstanding performance, with an average heat collection efficiency exceeding 56.96 % and a daily average heat storage amount of 132.13 kWh. Compared to the contrast greenhouse, the experimental greenhouse showed an increase in nighttime average air temperatures of 4.9 °C, 3.9 °C, and 3.6 °C on typical sunny, cloudy, and snowy days, respectively. The average surface soil temperatures increased correspondingly by 6.5 °C, 4.8 °C, and 4.5 °C. And the effective accumulated temperature increased by 40 %. Furthermore, the system significantly improved the uniformity of indoor temperature distribution. During nighttime heat release, the maximum temperature difference in the air, both span and vertically, did not exceed 0.8 °C; the maximum soil temperature differences in the span and length directions were no greater than 0.3 °C and 1.8 °C, respectively. During the daytime heat storage process, the maximum soil temperature differences in the span and length directions were no more than 0.4 °C and 1.7 °C, respectively. This study of the active solar soil heat storage system demonstrates significant application effects in improving the thermal environment of GSGs, with substantial environmental and economic benefits.
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主动式太阳能加热土壤蓄热系统对戈壁日光温室热环境影响的实验研究
本研究提出了一种创新的主动式太阳能加热土壤蓄热系统,以改善戈壁日光温室(GSG)的热环境并解决热量分布不均的问题。该系统利用戈壁砾石土壤作为蓄热介质,结合太阳能平板集热器和 0.15 米深的水平埋管。实验的重点是研究土壤蓄热对温室内空气和土壤温度时空分布的影响,以及评估该系统的环境和经济效益。结果表明,该系统性能卓越,平均集热效率超过 56.96%,日平均蓄热量为 132.13 千瓦时。与对比温室相比,在典型的晴天、阴天和雪天,实验温室的夜间平均气温分别提高了 4.9 ℃、3.9 ℃ 和 3.6 ℃。地表土壤平均温度也相应增加了 6.5 °C、4.8 °C和 4.5 °C。有效积温提高了 40%。此外,该系统还大大改善了室内温度分布的均匀性。在夜间放热过程中,跨度和垂直方向的最大空气温差均不超过 0.8 °C;跨度和长度方向的最大土壤温差分别不超过 0.3 °C和 1.8 °C。在白天的蓄热过程中,跨度方向和长度方向的最大土壤温差分别不超过 0.4 °C 和 1.7 °C。这项关于主动式太阳能土壤蓄热系统的研究表明,该系统在改善金沙国际娱乐网址热环境方面具有显著的应用效果,并能带来巨大的环境和经济效益。
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来源期刊
Energy and Buildings
Energy and Buildings 工程技术-工程:土木
CiteScore
12.70
自引率
11.90%
发文量
863
审稿时长
38 days
期刊介绍: An international journal devoted to investigations of energy use and efficiency in buildings Energy and Buildings is an international journal publishing articles with explicit links to energy use in buildings. The aim is to present new research results, and new proven practice aimed at reducing the energy needs of a building and improving indoor environment quality.
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