Two-phase flow condensation heat transfer characteristics of R-134a inside three-dimensional cylindrical micropillar enhanced tube

Anil Kumar, Ravi Kumar, Arup Kumar Das
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Abstract

This paper presents an experimental investigation for evaluation of heat transfer coefficient, frictional pressure drops and flow regimes with their transitions during the condensation of R-134a inside a smooth, two microfins (MF1 and MF2) and a newly developed micropillar (MP) tubes. The experiments are carried out for a range of mass flux at an average saturation temperature of 35°C. Micropillar tube has produced the maximum heat transfer coefficient, while the microfin (MF1) tube resulted the highest frictional pressure gradient compared to other tubes. The experimental observations of microfin and micropillar tubes are plotted on the mass flux versus vapor quality flow map and Taitel and Duckler flow map to discuss the transitions within different flow patterns achieved. Visual inspection of the flow regimes with varying mass flux and vapor quality showed stratified-wavy, intermittent, and annular flow regimes. The occurrence of annular flow is found to be more in MF1 and MP tube. A performance evaluation factor (PEF) is defined to evaluate the thermal-hydraulic performance of the tubes. Using the same, it has been observed that the newly developed MP tube has a PEF value greater than unity which suggest augmentation of heat transfer coefficient at the expense of lesser pressure drop penalty.

三维圆柱形微柱增强管内 R-134a 的两相流冷凝传热特性
本文介绍了一项实验研究,用于评估 R-134a 在一个光滑管、两个微鳍管(MF1 和 MF2)和一个新开发的微柱管(MP)内冷凝时的传热系数、摩擦压降和流动状态及其转换。实验是在平均饱和温度为 35°C 的一系列质量流量下进行的。与其他管子相比,微柱管的传热系数最大,而微鳍管(MF1)的摩擦压力梯度最大。微鳍管和微柱管的实验观察结果绘制在质量流量与蒸汽质量流动图以及 Taitel 和 Duckler 流动图上,以讨论不同流动模式下的过渡。目测质量通量和蒸汽质量变化时的流态显示了分层波浪形、间歇和环形流态。环形流在 MF1 和 MP 管道中出现得更多。性能评估系数(PEF)用于评估管道的热-水性能。使用该系数可以观察到,新开发的 MP 管的 PEF 值大于 1,这表明以较小的压降损失为代价提高了传热系数。
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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