Thermal analysis of a gravity-assisted heat pipe working with zirconia-acetone nanofluids: An experimental assessment

IF 0.8 Q4 THERMODYNAMICS
Amin Abdolhossein Zadeh
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引用次数: 2

Abstract

An experimental investigation was performed on the thermal performance and heat transfer characteristics of acetone/zirconia nanofluid in a straight (rod) gravity-assisted heat pipe. The heat pipe was fabricated from copper with a diameter of 15 mm, evaporator-condenser length of 100 mm and adiabatic length of 50 mm. The zirconia-acetone nanofluid was prepared at 0.05–0.15% wt. Influence of heat flux applied to the evaporator, filling ratio, tilt angle and mass concentration of nanofluid on the heat transfer coefficient of heat pipe was investigated. Results showed that the use of nanofluid increases the heat transfer coefficient while decreasing the thermal resistance of the heat pipe. However, for the filling ratio and tilt angle values, the heat transfer coefficient initially increases with an increase in both. However, from a specific value, which was 0.65 for filling ratio and 60–65 deg for tilt angle, the heat transfer coefficient was suppressed. This was attributed to the limitation in the internal space of the heat pipe and also the accumulation of working fluid inside the bottom of the heat pipe due to the large tilt angle. Overall, zirconia-acetone showed a great potential to increase the thermal performance of the heat pipe.
氧化锆-丙酮纳米流体重力辅助热管的热分析:实验评估
对丙酮/氧化锆纳米流体在直(棒)重力辅助热管中的热性能和传热特性进行了实验研究。热管由铜制成,直径为15 mm,蒸发器-冷凝器长度为100 mm,绝热长度为50 mm。制备了重量为0.05 ~ 0.15%的氧化锆-丙酮纳米流体,考察了蒸发器的热流密度、填充比、纳米流体的倾斜角度和质量浓度对热管传热系数的影响。结果表明,纳米流体的使用增加了热管的传热系数,降低了热管的热阻。而对于填充比和倾斜角值,传热系数最初随两者的增大而增大。但在填充比为0.65、倾斜角为60 ~ 65°时,传热系数被抑制。这是由于热管内部空间的限制,以及由于大的倾斜角度导致热管底部积聚了工质。综上所述,氧化锆-丙酮在提高热管热性能方面具有很大的潜力。
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来源期刊
Archives of Thermodynamics
Archives of Thermodynamics THERMODYNAMICS-
CiteScore
1.80
自引率
22.20%
发文量
0
期刊介绍: The aim of the Archives of Thermodynamics is to disseminate knowledge between scientists and engineers interested in thermodynamics and heat transfer and to provide a forum for original research conducted in Central and Eastern Europe, as well as all over the world. The journal encompass all aspect of the field, ranging from classical thermodynamics, through conduction heat transfer to thermodynamic aspects of multiphase flow. Both theoretical and applied contributions are welcome. Only original papers written in English are consider for publication.
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