Visualization experiments of bubble growth and detachment on catalytic surface in a microchannel

doi:10.3969/j.issn.0438-1157.2014.12.005

CIESC Journal ›› 2014, Vol. 65 ›› Issue (12): 4678-4683.DOI: 10.3969/j.issn.0438-1157.2014.12.005

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Visualization experiments of bubble growth and detachment on catalytic surface in a microchannel

YE Dingding^1,2, XIANG Wei², ZHU Xun^1,2, LI Jun^1,2, LIAO Qiang^1,2

1. Key Laboratory of Low-grade Energy Utilization Technologies and Systems, Chongqing University, Chongqing 400030, China;
2. Institute of Engineering Thermophysics, Chongqing University, Chongqing 400030, China

Received:2014-04-24 Revised:2014-06-18 Online:2014-12-05 Published:2014-12-05
Supported by:
supported by the National Natural Science Foundation of China (51376203, 51276208) and the National Natural Science Funds for Distinguished Young Scholar (51325602).

微通道内催化表面气泡生长及脱离的可视化实验

叶丁丁^1,2, 相威², 朱恂^1,2, 李俊^1,2, 廖强^1,2

1. 重庆大学低品位能源利用技术及系统教育部重点实验室, 重庆 400030;
2. 重庆大学工程热物理研究所, 重庆 400030

通讯作者: 朱恂
基金资助:
国家自然科学基金项目(51376203,51276208);国家杰出青年科学基金项目(51325602);高等学校博士学科点专项科研基金项目(20120191110010).

Abstract

Abstract: A rectangular microchannel was fabricated with polydimethylsiloxane (PDMS) material and MnO₂ catalysts were deposited on the wall of the microchannel. The growth and detachment process of oxygen bubbles generated by the catalytic reaction of H₂O₂ solution were recorded by a high speed camera. The effects of reactant concentration and flow rate on bubble growth rate and detachment diameter were also analyzed. The growth and detachment process of bubbles generated on the catalytic surface in the microchannel occurred periodically. Moreover, the bubble growth consisted of two processes, the initial fast growth process and the later slow growth process. Before 3 s, the generated bubbles were in a fast growth period, and reaction kinetics dominated the process. However, after 3s, reaction rate was controlled by diffusion, resulting in the fact that bubble growth rate increased with increasing reactant concentration. In addition, bubble detachment diameter was slightly affected by reactant concentration, while it was significantly affected by reactant flow rate and dropped linearly as Reynolds number increased.

Key words: microchannels, catalysis, reaction, bubble growth, detachment diameter

摘要： 采用聚二甲基硅氧烷材料(PDMS)制备矩形截面的微通道,并在微通道壁面上沉积MnO₂作为催化剂,采用高速摄影仪对通流过程中过氧化氢催化分解生成氧气气泡的过程进行了可视化实验研究,分析了反应物的浓度和流量对气泡生长速度及脱离直径的影响.结果表明:气泡在微通道内催化表面的生长及脱离过程呈周期性变化的趋势;气泡生长可以分为快速生长和缓慢生长两个阶段,当t<3 s时气泡处于快速生长阶段,催化反应主要受动力学控制,当t≥3 s时扩散控制占主要地位,气泡生长速度随反应物浓度的升高而增大;气泡脱离直径受反应物浓度影响较小,受反应物流量影响较大,而且随液相反应物Reynolds数的增大线性降低.

关键词: 微通道, 催化, 反应, 气泡生长, 脱离直径

CLC Number:

YE Dingding, XIANG Wei, ZHU Xun, LI Jun, LIAO Qiang. Visualization experiments of bubble growth and detachment on catalytic surface in a microchannel[J]. CIESC Journal, 2014, 65(12): 4678-4683.

叶丁丁, 相威, 朱恂, 李俊, 廖强. 微通道内催化表面气泡生长及脱离的可视化实验[J]. 化工学报, 2014, 65(12): 4678-4683.

References 22

[1]	Mills P L, Quiram D J, Ryley J F. Microreactor technology and process miniaturization for catalytic reactions—a perspective on recent developments and emerging technologies [J]. Chemical Engineering Science, 2007, 62 (24): 6992-7010
[2]	Luo Guangsheng (骆广生), Wang Kai (王凯), Xu Jianhong (徐建鸿), Lü Yangcheng (吕阳成), Wang Yujun (王玉军). Multiphase flow, transport and reaction in micro-structured chemical systems [J]. CIESC Journal (化工学报), 2010, 61 (7): 1621-1626
[3]	Nagy K D, Jensen K F. Catalytic processes in small scale flow reactors: status and opportunities [J]. Chimica Oggi/Chemistry Today, 2011, 29 (4): 18-21
[4]	Kobayashi J, Mori Y, Okamoto K, Akiyama R, Ueno M, Kitamori T, Kobayashi S. A microfluidic device for conducting gas-liquid-solid hydrogenation reactions [J]. Science, 2004, 304 (5675): 1305-1308
[5]	Dong Z, Xu J, Jiang F, Liu P. Numerical study of vapor bubble effect on flow and heat transfer in microchannel [J]. International Journal of Thermal Sciences, 2012, 54: 22-32
[6]	Gedupudi S, Zu Y Q, Karayiannis T G, Kenning D B R, Yan Y Y. Confined bubble growth during flow boiling in a mini-/micro-channel of rectangular cross-section (Ⅰ): Experiments and 1-D modelling [J]. International Journal of Thermal Sciences, 2011, 50 (3): 250-266
[7]	Zu Y Q, Yan Y Y, Gedupudi S, Karayiannis T G, Kenning D B R. Confined bubble growth during flow boiling in a mini-/micro-channel of rectangular cross-section (Ⅱ): Approximate 3-D numerical simulation [J]. International Journal of Thermal Sciences, 2011, 50 (3): 267-273
[8]	Peng J, Zhang Z Y, Niu H T. A 3D two-phase model for a membraneless fuel cell using decomposition of hydrogen peroxide with Y-shaped microchannel [J]. ECS Trans., 2013, 50 (2): 77-86
[9]	Shyu J C, Wei C S, Lee C J, Wang C C. Investigation of bubble effect in microfluidic fuel cells by a simplified microfluidic reactor [J]. Applied Thermal Engineering, 2010, 30 (13):1863-1871
[10]	Hasegawa S, Shimotani K, Kishi K, Watanabe H. Electricity generation from decomposition of hydrogen peroxide [J]. Electrochemical and Solid-state Letters, 2005, 8 (2): A119-A121
[11]	Kandlikar S G. Fundamental issues related to flow boiling in minichannels and microchannels [J]. Experimental Thermal and Fluid Science, 2002, 26 (2/3/4): 389-407
[12]	Serizawa A, Feng Z, Kawara Z. Two-phase flow in microchannels [J]. Experimental Thermal and Fluid Science, 2002, 26 (6/7): 703-714
[13]	Cubaud T, Ulmanella U, Ho C M. Two-phase flow in microchannels with surface modifications [J]. Fluid Dynamics Research, 2006, 38 (11): 772-786
[14]	Wu H Y, Cheng P. An experimental study of convective heat transfer in silicon microchannels with different surface conditions [J]. International Journal of Heat and Mass Transfer, 2003, 46 (14): 2547-2556
[15]	Barber J, Sefiane K, Brutin D, Tadrist L. Hydrodynamics and heat transfer during flow boiling instabilities in a single microchannel [J]. Applied Thermal Engineering, 2009, 29 (7): 1299-1308
[16]	Edel Z J, Mukherjee A. Experimental investigation of vapor bubble growth during flow boiling in a microchannel [J]. International Journal of Multiphase Flow, 2011, 37 (10): 1257-1265
[17]	Dong Tao (董涛), Yang Zhaochu (杨朝初), Bi Qincheng (毕勤成), Zhang Yulong (张玉龙), Gu Dandan (谷丹丹), Zhang Chunquan (张春权). Micro-bubble controlled growth in rectangular microchannel of micro-electro-mechanical systems [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2007, 58 (1): 54-60
[18]	Fu B R, Pan C. Bubble growth with chemical reactions in microchannels [J]. International Journal of Heat and Mass Transfer, 2009, 52 (3): 767-776
[19]	Fu B R, Pan C. Flow pattern transition instability in a microchannel with CO2 bubbles produced by chemical reactions [J]. International Journal of Heat and Mass Transfer, 2005, 48 (21/22): 4397-4409
[20]	Fu B R, Tseng F, Pan C. Two-phase flow in converging and diverging microchannels with CO2 bubbles produced by chemical reactions [J]. International Journal of Heat and Mass Transfer, 2007, 50 (1): 1-14
[21]	Bewer T, Beckmann T, Dohle H, Mergel J, Stolten D. Novel method for investigation of two-phase flow in liquid feed direct methanol fuel cells using an aqueous H2O2 solution [J]. Journal of Power Sources, 2004, 125 (1): 1-9
[22]	Xu J, Feng Y, Cen J. Transient flow patterns and bubble slug lengths in parallel microchannels with oxygen gas bubbles produced by catalytic chemical reactions [J]. International Journal of Heat and Mass Transfer, 2007, 50 (5/6): 857-871

Visualization experiments of bubble growth and detachment on catalytic surface in a microchannel

微通道内催化表面气泡生长及脱离的可视化实验

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