在铜鳍长度和方向不同的方形电池中提高 RT42 石蜡的熔化率:数值模拟

Q1 Chemical Engineering International Journal of Thermofluids Pub Date : 2024-09-19 DOI:10.1016/j.ijft.2024.100877
Saif Ali Kadhim , Karrar A. Hammoodi , Mohammed J. Alshukri , Issa Omle , Karrar K. Abdul Hussein , Abbas Fadhil Khalaf , Ammar Elsheikh
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引用次数: 0

摘要

在可再生热能系统中,潜热蓄能装置因其强大的蓄热能力而受到特别青睐。然而,这些装置中的相变材料导热率较低,这促使研究人员采用多种方法来解决这一问题,例如加入翅片。这项数值研究通过在一个使用石蜡 RT42 作为相变材料的方形电池(50 × 50 毫米)内部添加 4 片 1 毫米厚、不同长度的铜鳍片,提高了电池的充电率。铜翅片位于左壁,在此施加恒温热流,而其他壁则隔热。对电池的四种配置进行了研究:分别是不带鳍片、带 10 毫米长鳍片、带 20 毫米长鳍片和带 30 毫米长鳍片。结果表明,翅片的存在大大提高了方形电池的充电速率。与没有翅片的基准配置相比,翅片长度为 10 毫米、20 毫米和 30 毫米的石蜡 RT42 完全熔化所需的时间分别缩短了 22.22%、33.33% 和 55.56%。此外,还将配置四与将类似翅片安装在底壁同时保持左壁热通量的设置进行了比较。观察发现,与配置四相比,总熔化时间增加了一倍,这表明热通量的最佳位置在翅片所在的壁上。这项研究有助于提高和发展正方形和长方形 PCM 电池的充电率,例如用于冷却光伏电池板的电池。
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Enhancing the melting rate of RT42 paraffin wax in a square cell with varied copper fin lengths and orientations: A numerical simulation
Latent thermal energy storage units are especially preferred in renewable thermal energy systems for their significant capacity to store heat. Nevertheless, the phase change materials in these units have low thermal conductivity, prompting researchers to tackle this problem using several methods, such as incorporating fins. This numerical study contributes to improving the charging rate of a square cell (50 × 50 mm) used paraffin wax RT42 as phase change material by adding 4 copper fins inside, 1 mm thick and of different lengths. The fins were positioned on the left wall, where a constant-temperature heat flux was applied, while the other walls were thermally insulated. Four configurations of the cell were examined: without fins, with 10 mm length fins, with 20 mm length fins, and with 30 mm length fins, respectively. The results demonstrated that the presence of fins significantly improved the charging rate of the square cell. Compared to the baseline configuration without fins, the time required for the paraffin wax RT42 to completely melt was reduced by 22.22 %, 33.33 %, and 55.56 % with fins of 10 mm, 20 mm, and 30 mm lengths, respectively. Configuration four was also compared with a setup where similar fins were positioned on the bottom wall while maintaining the heat flux on the left wall. It was observed that the total melting time doubled compared to configuration four, suggesting that the optimal placement for the heat flux is on the wall where the fins are located. The study contributes to enhancing and developing the charge rates of square and rectangular PCM cells such as these used for cooling PV panels.
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来源期刊
International Journal of Thermofluids
International Journal of Thermofluids Engineering-Mechanical Engineering
CiteScore
10.10
自引率
0.00%
发文量
111
审稿时长
66 days
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