Visual experiment on evolution of flow pattern of R124-DMAC bubble absorption process in vertical tube

doi:10.11949/j.issn.0438-1157.20150229

Abstract

Abstract:

Through constructing a visual experiment platform of bubble absorption heat and mass coupled transfer characteristics in the vertical tube, the flow pattern characteristic and distribution regularity of bubble absorption process on R124/DMAC (2-chloro-1,1,1,2,-tetrafluoroethane / N', N'- dimethylacetamide) as working medium are studied. The result shows that the flow pattern characteristic and distribution regularity are influenced by the refrigerant vapor flow rate, absorption solution flow rate and its inlet temperature. Under large refrigerant vapor flow rate and high solution inlet temperature conditions, three kinds of flow patterns of churn flow, slug flow and bubble flow can be simultaneously observed in the bubble absorption tube. Under the condition which the vapor is completely absorbed in the absorption tube, the height of churn flow is no more than half of the total absorption height, while the height of slug flow is no more than 2/5 of the total absorption height. The rest of the absorbing height is occupied by bubble flow.

Key words: organic compounds, bubble, absorption, vertical tube, two-phase flow, visualization

摘要：

通过搭建一套垂直管管内鼓泡吸收热、质耦合传递特性可视化实验平台,对以R124-DMAC(一氯四氟乙烷-二甲基乙酰胺)为工质的鼓泡吸收过程的流型特征与分布规律进行研究。结果表明,制冷剂气体流率、吸收溶液流率和进口温度对鼓泡吸收过程的流型及其分布规律均产生一定的影响。在制冷剂气体流率和溶液入口温度较高的情况下,鼓泡吸收过程存在搅拌流、弹状流、泡状流3种流型。制冷剂气体在吸收管内被完全吸收的条件下,搅拌流流型高度不超过总吸收高度(喷嘴出口到气泡消失的垂直距离)的1/2;弹状流流型所占总吸收高度的比例不超过2/5;其余的吸收高度为泡状流流型。

关键词: 有机化合物, 气泡, 吸收, 垂直管, 两相流, 可视化

CLC Number:

TB61

JIANG Mengnan, XU Shiming, HU Junyong, WANG Wei, WU Xi. Visual experiment on evolution of flow pattern of R124-DMAC bubble absorption process in vertical tube[J]. CIESC Journal, 2015, 66(7): 2433-2441.

蒋孟男, 徐士鸣, 胡军勇, 王伟, 吴曦. 垂直管内R124-DMAC鼓泡吸收过程流型演化可视化实验[J]. 化工学报, 2015, 66(7): 2433-2441.

References 24

[1]	Kang Yong Tae, Atsushi Akisawa, Takao Kashiwagi. Analytical investigation of two different absorption modes: falling film and bubble types [J]. International Journal of Refrigeration, 2000, 23(6): 430-443.
[2]	Kang Y T, Nagano T, Kashiwagi T. Visualization of bubble behavior and bubbled diameter correlation for NH3-H2O bubble absorption [J]. International Journal of Refrigeration-Revue Internationale Du Froid, 2002, 25(1): 127-135.
[3]	Kang Y T, Nagano T, Kashiwagi T. Mass transfer correlation of NH3-H2O bubble absorption [J]. International Journal of Refrigeration-Revue Internationale Du Froid, 2002, 25(7): 878-886.
[4]	Lee K B, Chun B H, Lee J C, Lee C H, Kim S H. Experimental analysis of bubble mode in a plate-type absorber [J]. Chemical Engineering Science, 2002, 57(11): 1923-1929.
[5]	Lee J C, Lee K B, Chun B H, Lee C H, Ha J J, Kim S H. A study on numerical simulations and experiments for mass transfer in bubble mode absorber of ammonia and water [J]. International Journal of Refrigeration, 2003, 26(5): 551-558.
[6]	Cheng Wenlong(程文龙), Zhao Rui(赵锐), Liu Chang(刘畅), Jiang Shouli(江守利), Chen Zeshao(陈则韶). Experimental study of influence of additives on ammonia bubble absorption [J]. Journal of Refrigeration(制冷学报), 2006, 27(3): 35-40.
[7]	Zhao Rui(赵锐), Cheng Wenlong(程文龙), Jiangshouli(江守利), Chen Zenshao(陈则韶). Experimental study of ammonia bubble absorption—effect of flow rate and orifice diameter [J]. Fluid Machinery(流体机械), 2006, 34(3): 58-61.
[8]	Zhao Rui(赵锐), Cheng Wenlong(程文龙), Jiang Shouli(江守利), Chen Zenshao(陈则韶). Study on performance of ammonia bubble absorption [J]. Journal of Engineering Thermophysics(工程热物理学报), 2007, 28(1): 25-28.
[9]	Ferreira C A, Keizer C, Machielsen C H M. Heat and mass transfer in vertical tubular bubble absorbers for ammonia-water absorption refrigeration systems [J]. International Journal of Refrigeration, 1984, 7(6): 348-357.
[10]	Kim H Y, Saha B B, Koyama S. Development of a slug flow absorber working with ammonia-water mixture (Ⅱ): Data reduction model for local heat and mass transfer characterization [J]. International Journal of Refrigeration, 2003, 26(6): 698-706.
[11]	Kim H Y, Saha B B, Koyama S. Development of a slug flow absorber working with ammonia-water mixture(Ⅰ): Flow characterization and experimental investigation [J]. International Journal of Refrigeration, 2003, 26(5): 508-515.
[12]	Wei Qi(魏琪), Xia Lijiang(夏利江). Numerical study of bubble absorption in vertical tube absorber [J]. Refrigeration and Air-conditioning(制冷与空调), 2007, 7(1): 35-38.
[13]	Xia Lijiang(夏利江), Wei Qi(魏琪). Analysis of heat and mass transfer process during the bubble absorption process in vertical tubular absorber [J]. Journal of Zhengzhou University of Light Industry: Natural Science (郑州轻工业学院学报:自然科学版), 2007, 22(1): 46-49.
[14]	Luo Yulin(罗玉林), Xu Shiming(徐士鸣). Ammonia-water bubble absorption in air-cooled vertical finned tube [J]. CIESC Journal(化工学报), 2010, 61(2): 289-295.
[15]	Suresh M, Mani A. Heat and mass transfer studies on R134a bubble absorber in R134a/DMF solution based on phenomenological theory [J]. International Journal of Heat and Mass Transfer, 2010, 53(13): 2813-2825.
[16]	Suresh M, Mani A. Experimental studies on bubble characteristics for R134a-DMF bubble absorber [J]. Experimental Thermal and Fluid Science, 2012, 39: 79-89.
[17]	Suresh M, Mani A. Experimental studies on heat and mass transfer characteristics for R134a-DMF bubble absorber [J]. International Journal of Refrigeration, 2012, 35(4): 1104-1114.
[18]	Suresh M, Mani A. Heat and mass transfer studies on a compact bubble absorber in R134a-DMF solution based vapour absorption refrigeration system [J]. International Journal of Refrigeration, 2013, 36(3): 1004-1014.
[19]	Sujatha K S, Mani A, Murthy S Srinivasa. Analysis of a bubble absorber working with R22 and five organic absorbents [J]. Heat and Mass Transfer, 1997, 32(4): 255-259.
[20]	Sujatha K S, Mani A, Murthy S Srinivasa. Finite element analysis of a bubble absorber [J]. International Journal of Numerical Methods for Heat & Fluid Flow, 1997, 7(7): 737-750.
[21]	Sujatha K S, Mani A, Murthy S Srinivasa. Experiments on a bubble absorber [J]. International Communications in Heat and Mass Transfer, 1999, 26(7): 975-984.
[22]	Li Jianbo, Xu Shiming. The performance of absorption- compression hybrid refrigeration driven by waste heat and power from coach engine [J]. Applied Thermal Engineering, 2013, 61(2): 747-755.
[23]	Xu Shiming, Li Jianbo, Liu Fusen. An investigation on the absorption-compression hybrid refrigeration cycle driven by gases and power from vehicle engines [J]. International Journal of Energy Research, 2013, 37(12): 1428-1439.
[24]	Lao Liyun(劳力云), Zheng Zhichu(郑之初), Wu Yingxiang(吴应湘), Li Donghui(李东晖). Analysis of heat and mass transfer process during the bubble absorption process in vertical tubular absorber [J]. Advances in Mechanics(力学进展), 2002, 32(2): 235-248.