| 新型板框气隙式膜蒸馏组件流场的CFD数值模拟 |
| 作者:许凯,李保安 |
| 单位: (1. 天津大学化工学院,天津,300350; 2. 化学化工协同创新中心,天津,300072; 3. 化学工程联合国家重点实验室,天津,300072; 4. 天津市膜科学与海水淡化重点实验室,天津,300350) |
| 关键词: 气隙式膜蒸馏;计算流体力学;模型设计;温度分布 |
| 出版年,卷(期):页码: 2017,37(2):88-95 |
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摘要: |
| 利用计算流体力学(CFD)软件,构造三维计算模型,对新型的热量回收板框气隙式膜蒸馏组件内部热质传递过程进行研究。分别考察了不同进料温度、流速和操作真空度条件下模型内部流体温度分布情况。模拟结果表明:提高进料侧料液流速或者减小渗透侧真空度,在同一位置的膜表面温度均增加;渗透侧换热中空纤维从下至上壁面温度呈现递增的趋势,各层中空纤维外表面温度均存在差异,距离膜侧位置越近,中空纤维表面温度越高。本研究的一个重要发现是在不同条件下渗透侧底部区域的蒸汽温度大于热料液主体温度,不利于膜蒸馏过程和热量回收利用;当增加料液温度或者下游侧真空度时,有效膜蒸馏面积增大。本研究结果揭示了新型组件内部直观的参数分布规律,为内部结构进一步优化奠定了基础。 |
| By using computational fluid dynamics (CFD) software, the three-dimensional calculation model was constructed to research the internal heat and mass transfer progress of the new type of heat recovery of frame and air gap membrane distillation module. The distribution of fluid temperature was examined under the condition of different feed temperature, feed rate and operating vacuum. The simulation results showed that: the surface temperature of membrane was increased by improving feed rate or decreasing vacuum degree of permeability side; Outer surface temperature of heat-transfer hollow fiber by side of the permeability showed the tendency was increasing from the bottom. The outer surface temperature of each hollow fiber existed differences, the higher outer surface temperature of hollow fiber, the closer distance to the side of membrane. The steam temperature of the bottom of side of the permeability was higher than main temperature of the hot feed liquid, which was not conducive to membrane distillation process. The effective area of membrane distillation would be increased which elevates temperature or vacuum degree. This study reveals internal intuitive parameters distribution law of the new component, which laid a foundation for further optimization of the internal structure. |
| 第一作者简介:许凯(1991-),男,江苏省如皋县,硕士研究生,研究方向:膜蒸馏过程传质传热研究,E-mail:tdxukai@163.com |
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参考文献: |
| [1] El-Bourawi M S,Ding Z,Ma R,et al. A framework for better understanding membrane distillation separation process [J]. Journal of Membrane Science,2006,285:4-29. [2] 申龙,高瑞昶. 膜蒸馏技术最新研究应用进展 [J]. 化工进展,2014,33(2):289-297. [3] Alsaadi A S,Francis L,Maab H,et al. Evaluation of air gap membrane distillation process running under sub-atmospheric conditions: Experimental and simulation studies [J]. Journal of Membrane Science,2015,489:73-80. [4] Li Xiaojun,Qin Yingjie,Liu Rongling,et al. Study on concentration of aqueous sulfuric acid solution by multiple-effect membrane distillation [J]. Desalination,2012,307:34-41. [5] He Qingfeng,Li Pingli,Geng Hongxin,et al. Modeling and optimization of air gap membrane distillation system for desalination [J]. Desalination,2014,354:68–75. [6] Yun C W,Kim Y,Shim W G,et al. Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation [J]. Journal of Membrane Science,2016,513:74–84. [7] Geng Hongxin,Wu Haoyun,Li Pingli,et al. Study on a new air-gap membrane distillation module for desalination [J]. Desalination,2014,334:29-38. [8] Abu-Zeid E R,Zhang L,Jin W Y,et al. Improving the performance of the air gap membrane distillation process by using a supplementary vacuum pump [J]. Desalination,2016,384:31-42. [9] 李卜义,王建友,王济虎,等. 新型中空纤维空气隙式膜蒸馏用于海水淡化 [J]. 化工学报,2015(1):149-156. [10] Duong H C,Chivas A R,Nelemans B,et al. Treatment of RO brine from CSG produced water by spiral-wound air gap membrane distillation — A pilot study [J]. Desalination,2015,366:121-129. [11] 高云霄,刘芮,李保安. 热回收式板框膜蒸馏组件的制备及性能研究 [J]. 现代化工,2016,36(11):163-168. [12] 张雅琴,张林,侯立安. 计算流体力学在水处理膜过程中的应用 [J]. 中国工程科学,2014,16(7):47-52. [13] Shirazi M M A,Kargari A,Ismail A F,et al. Computational Fluid Dynamic (CFD) opportunities applied to the membrane distillation process: State-of-the-art and perspectives [J]. Desalination,2016,377:73-90. [14] Yang Xing,Yu Hui,Wang Rong,et al. Analysis of the effect of turbulence promoters in hollow fiber membrane distillation modules by computational fluid dynamic (CFD) simulations [J]. Journal of Membrane Science,2012,415–416:758-769. [15] Lian B,Wang Y,Le-Clech P,et al. A numerical approach to module design for crossflow vacuum membrane distillation systems [J]. Journal of Membrane Science,2016,510:489-496. [16] Chang H,Hsu J A,Chang C L,et al. CFD Simulation of Direct Contact Membrane Distillation Modules with Rough Surface Channels [J]. Energy Procedia,2015,75:3083-3090. [17] Pinnau I,Freeman B D. Membrane formation and modification [M]. Washing DC:American Chemical Society,2000. [18] Banat F A,Simandl J. Desalination by membrane distillation: a parametic study [J]. Sep Sci Technol 1998,33(2):201-226. [19] Banat F A,Simandl J. Membrane distillation for dilute methanol: separation from aqueous streams [J]. Journal of Membrane Science,1999,163(2):333-348. |
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