A Computational Study on Utilizing Phase Change Material With a Condenser to Improve air Conditioning System Performance

Energy Storage Pub Date : 2024-09-24 DOI:10.1002/est2.70051

Arun Kumar Sao, Arun Arora, Mukesh Kumar Sahu

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Abstract

The efficacy of employing multiple cylindrical phase change materials (PCM) to enhance the performance of an air conditioning (AC) unit is examined in this study. The objective of the present study is to examine the effects of combining an AC unit with a cylindrical PCM container configuration on the PCM discharge process and the performance of the AC system. The procedure involves the connection of a heat exchanger with a cold energy storage PCM to the condenser of the AC. During the daytime, the warm surrounding air is cooled and then transmitted to the AC unit's condenser. Four different turbulence models, that is, the SST $k - ω$ , standard $k - ω$ , Realizable $k - ɛ$ and RNG $k - ɛ$ have been considered for the present computational study. The investigation has been performed for different air flow rates, that is, 33.6, 42, and 49 $L / s$ for a constant inlet air temperature of 308.15 K. The present outcomes indicate that as the flow rate rises, the air temperature inside the domain increases and the solid PCM starts melting. It is noted that complete discharging time for multi-cylindrical PCM reduces as the air flow rate rises which are around 13.36, 11.03, and 9.94 h for airflow rates of 33.6, 42, and 49 $L / s$ , respectively. The maximum achieved increase in the COP is around 94.49%, 88.68%, and 87.57% at airflow rates of 33.6, 42, and 49 L/s, respectively, for the multi-cylindrical PCM throughout the summer. It is found that for the same temperature, as the airflow rate rises, the consumed power saving rises.

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利用冷凝器相变材料改善空调系统性能的计算研究

本研究探讨了采用多种圆柱形相变材料 (PCM) 提高空调 (AC) 设备性能的效果。本研究的目的是考察空调设备与圆柱形 PCM 容器配置相结合对 PCM 排放过程和空调系统性能的影响。该过程包括将装有冷能储存 PCM 的热交换器连接到空调的冷凝器上。白天，周围的暖空气被冷却，然后传送到空调设备的冷凝器。本计算研究考虑了四种不同的湍流模型，即 SST k - ω $$ k-\omega $$、标准 k - ω $$ k-\omega $$、Realizable k - ɛ $$ k-\varepsilon $$和 RNG k - ɛ $$ k-\varepsilon $$。研究针对不同的空气流速进行，即 33.6、42 和 49 L /s $$ \mathrm{L}/\mathrm{s} $$，入口空气温度恒定为 308.15 K。值得注意的是，多圆柱形 PCM 的完全排出时间随着空气流速的增加而缩短，当空气流速为 33.6、42 和 49 L / s $$ \mathrm{L}/\mathrm{s} $$ 时，排出时间分别为 13.36、11.03 和 9.94 h。在整个夏季，多圆柱形 PCM 的气流速率分别为 33.6、42 和 49 L/s 时，COP 的最大增幅分别约为 94.49%、88.68% 和 87.57%。研究发现，在温度相同的情况下，随着气流速率的增加，消耗的功率也会增加。

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

Energy Storage

CiteScore

2.90

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0.00%

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