Numerical Analysis of Heat Exchanger for Spray-Assisted Low-Temperature Desalination System

Amour Othman Muhunzi, Y. Jande, Revocatus Lazaro Machunda
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引用次数: 1

Abstract

A numerical study for heat exchanger for spray-assisted low-temperature desalination system is presented for an existing low-temperature desalination unit at Arusha Technical College. This is aimed at recognizing the effect of mass flow and physical parameters like tube layout (diameter and length) on the overall heat transferred and the pressure drop in the shell-and-tube heat exchanger (STHX), as well as the impact of these parameters on the heat transfer coefficient and the overdesign of the STHX. Also, the study provides a suitable mathematical model for the replacement of the current condensation unit which tends to reduce energy consumption by reducing some of the electrical components in the system. A Math CAD model was developed using the Delaware method to obtain the mentioned parameters. The results show that at 0.8 kg/s flow rate a maximum heat transfer coefficient of 23212 W/m2K is achieved in a minimum diameter of 10 mm within a maximum tube length of 1000 mm heat exchanger and the pressure drop seems to be very low in a range of 0.328-0.957 Pa from all configurations. The configuration with 1000 mm tube length and 10 mm diameter performed well on the mass flow of 0.3 kg/s-0.8 kg/s by providing a suitable overall heat transfer coefficient of 2306-2539 W/m2K, while 12.8 is a maximum overdesign coefficient achieved on 0.8 kg/s mass flow. The study results show the possibility of using STHX instead of the current condensation unit in implementing a proposed system layout with the minimum effect of energy consumption.
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喷雾辅助低温海水淡化系统换热器数值分析
针对阿鲁沙技术学院现有的低温脱盐装置,对喷雾辅助低温脱盐系统换热器进行了数值研究。这是为了认识管壳式换热器(STHX)的质量流量和管布局(直径和长度)等物理参数对总体换热和压降的影响,以及这些参数对传热系数和STHX的过度设计的影响。同时,本研究也为当前冷凝机组的更换提供了一个合适的数学模型,该模型倾向于通过减少系统中的一些电气元件来降低能耗。采用Delaware法建立了数学CAD模型,得到了上述参数。结果表明,在流量为0.8 kg/s时,在最大管长为1000 mm、最小管径为10 mm的换热器中,换热系数最大可达23212 W/m2K,在0.328 ~ 0.957 Pa范围内,各种配置的压降都很低。在质量流量为0.3 kg/s-0.8 kg/s时,管长为1000 mm、直径为10 mm的结构传热系数为2306-2539 W/m2K,而在质量流量为0.8 kg/s时,传热系数最高为12.8。研究结果表明,采用STHX代替现有的冷凝装置实现所提出的系统布局的可能性,且能耗影响最小。
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28 weeks
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