Performance study of an isolated small scale Trombe wall with partially evacuated air gap

Mahmud H. Ali, M. K. Mawlood, Rawand E. Jalal
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Abstract

The Trombe wall is a passive solar heating system that aims to mitigate heating load. However, its efficiency is impeded by significant heat loss through the glazing. To address this issue, a novel technique has been developed that involves partial evacuation of the space between the storage wall and the glazing. This approach, which has already found successful application in double-paned windows and solar collectors, is examined in this study to evaluate its impact on the performance of an isolated Trombe wall. An effectiveness criterion based on the ability of a system to preserve its stored thermal energy is defined and used for assessing the performance of a vacuumed system relative to a non-vacuumed one. An experimental test cell, composed of a solid concrete wall serving as a thermal storage and a glazing separated from the wall by an air gap, facing south is constructed in Kirkuk, Iraq. The wall is insulated at all its sides except the side facing the glass. The gap has been sealed meticulously to maintain a vacuum. Due to unrepeatability of the testing conditions experimentally, a numerical method and a computer code is also developed for simulation of the system. Measurement results obtained from the test cell under normal atmospheric pressure and a gage pressure of −0.3 bar of the air gap are used to validate the numerical method. The code is then used to simulate the performance of the system under the same ambient conditions but at different vacuum pressures of the air gap. Results obtained from the numerical tests show that partial evacuation of the air gap can be an efficient way to enhance the performance of the Trombe wall and the absolute pressure of 0.1 bar results in the most significant increase in the effectiveness of the studied model.
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带部分排空气隙的孤立式小型特罗姆贝墙性能研究
特罗姆贝墙是一种被动式太阳能供热系统,旨在减轻供热负荷。然而,通过玻璃的大量热量损失阻碍了它的效率。为了解决这个问题,我们开发了一种新技术,对储热墙和玻璃之间的空间进行部分排空。这种方法已成功应用于双层玻璃窗和太阳能集热器,本研究将对其进行检验,以评估其对隔离特洛姆贝墙性能的影响。根据系统保存其存储热能的能力定义了一个有效性标准,并用于评估抽真空系统相对于非抽真空系统的性能。在伊拉克的基尔库克建造了一个实验测试单元,该单元由一个用作热储存的实心混凝土墙和一个由气隙隔开的玻璃窗组成,玻璃窗朝南。除了朝向玻璃的一面外,墙壁的所有侧面都是隔热的。为了保持真空状态,气隙被仔细密封。由于试验条件无法重复,因此还开发了一种数值方法和计算机代码来模拟该系统。测试单元在正常大气压力和气隙-0.3 巴测量压力下的测量结果用于验证数值方法。然后,使用该代码模拟系统在相同环境条件下但在不同气隙真空压力下的性能。数值测试的结果表明,气隙部分抽真空是提高特洛姆贝墙性能的有效方法,0.1 巴的绝对压力使所研究模型的有效性得到了最显著的提高。
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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