CFD Air Flow Evaluation of Finned Tube Evaporator for Refrigerated Display Cabinet Application

Q2 Mathematics
I. D. Made, Cipta Santosa, Gede Nyoman, Suta Waisnawa, P. Sunu, Wayan Temaja, Liang Li
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Abstract

This study is aimed to develop a simulation to improve the performance of the finned tube evaporator which is applied to the refrigerated display cabinet. CFD model was developed to be able to analyse the characteristics of air flow inside the fin gap and air side heat transfer coefficient. Geometry of the model of overall finned tube evaporator is considered covering two aluminium wavy fins with an air flow in between, combination of staggered cooper tubes with refrigerant flow inside. Fin gap is designed 4 mm to anticipate frost on the fin surface that can block air flow. Turbulence models used in the study is the realizable k-ε turbulence which had the best performance turbulence model and it was validated with secondary data from previous studies and shows the lowest error only 5.9 %. The use of CFD was found to be sufficiently representative of the heat transfer characteristics of evaporators, and acted as an effective simulation tool to determine the heat transfer coefficient in order to improve efficiency in terms of improved design. The characteristics of air flow between the fin gap and around the tube was obtained various and complex. In the case study the entry velocity of 1.7 m /s at the highest turbulence condition of the first row can reach speeds of 2.75 m/s. Hight turbulence regime in flow can indicate higher the heat transfer coefficient of the evaporator.
用于冷藏展示柜的翅片管蒸发器 CFD 气流评估
本研究旨在开发一种模拟方法,以提高应用于冷藏展示柜的翅片管蒸发器的性能。为分析翅片间隙内的气流特性和空气侧传热系数,开发了 CFD 模型。整体翅片管蒸发器模型的几何形状包括两个铝制波浪形翅片,中间有气流,交错的库珀管与内部的制冷剂流相结合。翅片间隙设计为 4 毫米,以防止翅片表面结霜而阻碍气流。研究中使用的湍流模型是可实现的 k-ε 湍流,它是性能最好的湍流模型,并通过以前研究的二手数据进行了验证,误差最小,仅为 5.9%。研究发现,CFD 能够充分代表蒸发器的传热特性,是确定传热系数的有效模拟工具,从而在改进设计方面提高效率。鳍片间隙和管子周围的气流特征多种多样,十分复杂。在案例研究中,第一排最高湍流条件下的进入速度为 1.7 米/秒,速度可达 2.75 米/秒。流动中的高湍流状态表明蒸发器的传热系数更高。
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
CFD Letters
CFD Letters Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
3.40
自引率
0.00%
发文量
76
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