The Effect of Mixing Promotors on Sweeping Gas Membrane Distillation System Performance

Volume 7: Fluids Engineering Pub Date : 2019-11-11 DOI:10.1115/imece2019-10727

U. Alqsair, Anas M. Alwatban, Ahmed M. Alshwairekh, Robert Krysko, Abdullah A. Alghafis, A. Oztekin

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引用次数: 1

Abstract

Computational fluid dynamics simulations were conducted to model the effect of adding mixing promoters in sweeping gas membrane distillation modules. Net-type spacers of 45° are placed in the feed side while membrane corrugation is employed with the tips of the corrugation pointing towards the permeate side. The membrane corrugation is of chevron type. The membrane is considered as a functional surface, and the vapor flux through the membrane is modeled using the Dusty-Gas model. The vapor flux equation couples the vapor pressure variation across the membrane with the feed concentration. The flow inside the channels with mixing promoters is considered turbulent. The k–ω SST turbulent model is used to model the steady-state turbulent structures inside the channels. The flow rate in the feed side is fixed, and the flow rate in the permeate channel is varied so that Rep = 1000,1500, and 2000 are considered. The inlet feed and permeate temperatures, and the membrane properties are fixed. The results indicate that the presence of mixing promoters increases the vapor permeation through the membrane by alleviation of the concentration and temperature polarization effects. The mixing promoters are more effective at high flow rates in both channels.

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混合促进剂对扫气膜蒸馏系统性能的影响

通过计算流体力学模拟，模拟了在扫气膜蒸馏模块中加入混合促进剂的效果。进料侧放置45°的网型垫片，而膜波纹采用波纹的尖端指向渗透侧。膜波纹为v型。将膜视为一个功能表面，通过膜的蒸汽通量采用尘埃-气体模型进行建模。蒸汽通量方程将膜上的蒸汽压变化与进料浓度耦合在一起。有混合促进剂的通道内的流动被认为是紊流。采用k -ω海温湍流模型对通道内的稳态湍流结构进行建模。进料侧流量固定，渗透通道流量变化，考虑Rep = 1000、1500、2000。进料和渗透温度，膜的性能是固定的。结果表明，混合促进剂的存在通过减轻浓度和温度的极化效应增加了蒸汽通过膜的渗透性。在两个通道的高流速下，混合促进剂更有效。

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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Volume 7: Fluids Engineering

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