珀耳帖器件作为冷却源的性能增强

2023 International Conference on Energy, Power, Environment, Control, and Computing (ICEPECC) Pub Date : 2023-03-08 DOI:10.1109/ICEPECC57281.2023.10209445

Erum Iftikhar, Bilal Hassan Bhatti, Fawad Mehboob, A. Muzaffar, Muhammad Hasnain Tariq, T. A. Cheema

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引用次数: 0

摘要

在传统制冷和空调系统中，作为制冷剂的氢氟碳化合物和氯氟碳化合物(CFCs和HCFCs)的生产、使用和处置所造成的环境危害已经暴露出来。这促使人们深入研究替代制冷系统的生产。热电冷却由于其独特的特性提供了一种潜在的替代技术。在热电冷却器(TEC)中利用珀尔帖效应在两种不同材料相遇时产生热流。利用热电效应，建立了一种低功耗、环保的制冷系统。该研究是通过研究与Peltier冷侧相连的水体产生的冷却效果来进行的，其中水以恒定速度流动，在热侧安装了带变速风扇的铝翅片。收集了研究结果，并对冷却效果进行了检验。结果表明，随着风机转速的增加，系统的冷却效果和性能系数(COP)均有所提高。在最大风扇转速下，COP高达62.7。

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Performance Enhancement of a Peltier Device as a Cooling Source

The environmental harm caused by the production, use, and disposal of hydro- and chlorofluorocarbons (CFCs and HCFCs) as refrigerants in conventional refrigeration and air conditioning systems has come to light. This has prompted in-depth study into the production of substitute refrigeration systems. Thermoelectric cooling offers a potential alternative technique due to its distinct characteristics. The Peltier effect was utilised in thermoelectric coolers (TEC) to create a heat flux at the meeting of two different materials. In this work, a low-power, environment friendly refrigeration system was built using the thermoelectric effect. The studies were carried out by studying the cooling effect created in a water body connected to the Peltier colder side where water was flowing at constant speed, and on the hotter side aluminium fins with variable speed fan were installed. The findings were collected, and the cooling effect was examined. It was found that the cooling effect and coefficient of performance (COP) of the system increase with fan speed. The COP increased up to 62.7 at maximum fan speed.

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2023 International Conference on Energy, Power, Environment, Control, and Computing (ICEPECC)

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