Evaluation of thermal and hydraulic of air flow through perforated concave delta winglet vortex generators in a rectangular channel with field synergy principle

Syaiful, Pracayasa Ade Putra, M. Tauviqirrahman, N. Sinaga, M. Bae
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引用次数: 2

Abstract

A compact heat exchanger can be found in air conditioning, automotive industry, chemical processing, etc. Most compact heat exchangers use gas as a heating or cooling fluid. However, gas has high thermal resistance, which affects lower heat transfer. In order to reduce thermal resistance on the gas side, the convection heat transfer coefficient is increased. One effective way to enhance the convection heat transfer coefficient is to use a vortex generator. Vortex generators are surface protrusions that are able to manipulate flow resulting in an increase in convection heat transfer coefficient by enhancing the mixture of air near the wall with the air in the main flow. Therefore, this work aims to evaluate the thermal and hydraulic characteristics of airflow through the perforated concave delta winglet vortex generator. This study was conducted on delta winglet vortex generators (DW VGs) and concave delta winglet vortex generator (CDW VGs) with the 45° angle of attack with a number of hole three-holes that applied on every vortex generator with one-line fitting, two-line fitting, and three-line fitting respectively. Results of simulation revealed that heat transfer coefficient (h) for perforated CDW VGs decrease 16.07% and pressure drop decrease 7% compare to that without hole configuration at Reynolds number of 8600. Convection heat transfer coefficient for perforated DW VGs decrease 13.76% and pressure drop decrease 5.22% compare to delta winglet without hole at Reynolds number of 8600.A compact heat exchanger can be found in air conditioning, automotive industry, chemical processing, etc. Most compact heat exchangers use gas as a heating or cooling fluid. However, gas has high thermal resistance, which affects lower heat transfer. In order to reduce thermal resistance on the gas side, the convection heat transfer coefficient is increased. One effective way to enhance the convection heat transfer coefficient is to use a vortex generator. Vortex generators are surface protrusions that are able to manipulate flow resulting in an increase in convection heat transfer coefficient by enhancing the mixture of air near the wall with the air in the main flow. Therefore, this work aims to evaluate the thermal and hydraulic characteristics of airflow through the perforated concave delta winglet vortex generator. This study was conducted on delta winglet vortex generators (DW VGs) and concave delta winglet vortex generator (CDW VGs) with the 45° angle of attack with a number of hole three-holes tha...
基于场协同原理的矩形通道内穿孔凹三角洲小涡发生器气流热水力特性评价
紧凑型热交换器可以在空调,汽车工业,化学加工等领域找到。大多数紧凑型热交换器使用气体作为加热或冷却流体。然而,气体具有很高的热阻,这影响了较低的传热。为了减小气体侧的热阻,增加了对流换热系数。提高对流换热系数的一种有效方法是使用涡发生器。涡发生器是能够操纵流动的表面突起,通过增强壁面附近空气与主流空气的混合,从而增加对流换热系数。因此,本文旨在对穿孔凹型三角小涡发生器气流的热特性和水力特性进行研究。研究了45°攻角的delta小翼涡发生器(DW VGs)和凹型delta小翼涡发生器(CDW VGs),分别采用单线拟合、双线拟合和三线拟合的方法在每个涡发生器上施加三孔。模拟结果表明,在雷诺数为8600时,穿孔后的CDW VGs换热系数(h)比未配置孔时降低了16.07%,压降降低了7%。在雷诺数为8600时,与无孔三角小翼相比,带孔DW小翼对流换热系数降低了13.76%,压降降低了5.22%。紧凑型热交换器可以在空调,汽车工业,化学加工等领域找到。大多数紧凑型热交换器使用气体作为加热或冷却流体。然而,气体具有很高的热阻,这影响了较低的传热。为了减小气体侧的热阻,增加了对流换热系数。提高对流换热系数的一种有效方法是使用涡发生器。涡发生器是能够操纵流动的表面突起,通过增强壁面附近空气与主流空气的混合,从而增加对流换热系数。因此,本文旨在对穿孔凹型三角小涡发生器气流的热特性和水力特性进行研究。本文研究了45°迎角的三角小波涡发生器(DW VGs)和凹三角小波涡发生器(CDW VGs),它们具有一定的孔数。
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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