土空气热交换器的计算流体动力学模拟:串联和并联布置的热性能比较

IF 6 Q1 ENGINEERING, MULTIDISCIPLINARY
Sarwo Edhy Sofyan , Teuku Meurah Indra Riayatsyah , Khairil , Eric Hu , Akram Tamlicha , Teuku Muhammad Reza Pahlefi , H.B. Aditiya
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引用次数: 0

摘要

本研究使用 Ansys Fluent 对用于冷却的串联和并联地球空气热交换器(EAHE)系统的热性能进行了比较。利用已发表文献中的实验数据和匹配的模拟结果对模型进行了验证。敏感性研究考察了长度、直径和地表覆盖物对 EAHE 性能的影响。此外,还探讨了 EAHE 效能与传热系数(NTU)之间的关系,以及土壤热制度。模拟结果表明,串联式 EAHE 比并联式 EAHE 的温降更低。输入空气温度为 32 °C,EAHE 长度从 10 米到 50 米不等(以 10 米为增量),50 米长的 EAHE 产生的出口空气温度最低:串联配置为 27.2 °C,并联配置为 28.8 °C。改变 EAHE 的直径(4-6 英寸)会导致两种设置的出口空气温度下降 ±0.2 °C。EAHE 在短草土壤覆盖下表现最佳,串联和并联布置的出口空气温度分别比沥青覆盖低 1.4 °C 和 0.5 °C。压降随 EAHE 的长度成比例增加。模拟结果表明,串联设计的压力损失是并联设计的 ±6 倍。效果-NTU 关系表明,并联 EAHE 比串联 EAHE 的效果高 15%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Computational fluid dynamic simulation of earth air heat exchanger: A thermal performance comparison between series and parallel arrangements
This study uses Ansys Fluent to compare the thermal performance of series and parallel earth air heat exchanger (EAHE) systems for cooling. The model was validated using experimental data from published literature and matched simulation results. The sensitivity study examined how length, diameter, and ground surface coverings affected EAHE performance. The relationship between effectiveness and the Number Transfer Unit (NTU) of EAHE was explored along with the soil thermal regime. The simulation results show that the series EAHE can achieve a lower temperature drop than parallel. With an input air temperature of 32 °C and EAHE lengths varying from 10 m to 50 m (in 10 m increments), the 50 m EAHE produced the lowest outlet air temperatures: 27.2 °C for the series configuration and 28.8 °C for the parallel arrangement. Changing the EAHE diameter (4–6 in) results in a ±0.2 °C outlet air temperature drop for both setups. EAHE performed best under short grass soil cover, yielding 1.4 °C and 0.5 °C lower outlet air temperatures, for series and parallel arrangements than the asphalt cover. The pressure drop increased proportionally with EAHE's length. Simulation results indicate a ±6 times larger pressure loss in the series design compared to the parallel setup. The effectiveness-NTU relationship shows that parallel EAHEs are 15 % more effective than series ones.
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来源期刊
Results in Engineering
Results in Engineering Engineering-Engineering (all)
CiteScore
5.80
自引率
34.00%
发文量
441
审稿时长
47 days
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