陶瓷微孔膜管制造微气泡的研究

膜科学与技术 , 2009, 29(6): 61-65. doi: 10.3969/j.issn.1007-8924.2009.06.014

陶瓷微孔膜管制造微气泡的研究

吴胜军 ^1, , 方为茂 ^2, , 赵红卫 ^3, , 昌宇奇 ^4, , 冯波 ^5, , 熊莹 ^6, , 林学理 ^7,

1.四川大学,化工学院,成都,610065

2.四川大学,化工学院,成都,610065

3.四川大学,化工学院,成都,610065

4.四川大学,化工学院,成都,610065

5.四川大学,化工学院,成都,610065

6.四川大学,化工学院,成都,610065

7.四川大学,化工学院,成都,610065

关键词：气浮 , 陶瓷微孔膜管 , 微气泡 , 气泡粒径分布

Research on microbubbles generated by ceramic microporous tube

WU Shengjun ^1, , FANG Weimao ^2, , ZHAO Hongwei ^3, , CHANG Yuqi ^4, , FENG Bo ^5, , XIONG Ying ^6, , LIN Xueli ^7,

1.四川大学,化工学院,成都,610065

2.四川大学,化工学院,成都,610065

3.四川大学,化工学院,成都,610065

4.四川大学,化工学院,成都,610065

5.四川大学,化工学院,成都,610065

6.四川大学,化工学院,成都,610065

7.四川大学,化工学院,成都,610065

Keywords： air flotation , ceramic microporous tube , microbubble , bubble size distribution

气浮工艺中气泡的大小是衡量气泡制造技术的关键.研究了陶瓷微孔膜管产生微气泡的条件,并对两种不同材质的微孔膜管产生微气泡的结果进行了比较,从气泡形成机理上分析了影响气泡粒径分布的因素.实验采用静态显微摄像技术和图像分析系统时气泡粒径分布进行了表征.实验结果表明,利用陶瓷微孔膜管产生的气泡粒径主要集中在15～50 μm之间,平均粒径在25.7～44.2 μm之间.微孔膜管的孔径大小、表面性能,气体流量,剪切流流速,液体表面张力,黏度是影响气泡粒径分布的主要因素.

Bubble size is a key of evaluating the bubble generation in air floatation technology. This work is a study on the conditions of using ceramic microporous tube to produce microbubbles, the results of bubble forma-tion compared with the metal microporous membrane tube, and the factors effecting on the initial bubble size distribution are also analyzed from the mechanism of bubble formation. The bubble size distribution in this unit was measured by static micro- video and image analytics system.The experimental results showed that the microbubble diameter is ranged from 15 μm to 50 /urn, and mean diameter is between 25.7 μm to 44.2 μm, the initial bubble size distribution depend strongly on the pore size and facial characteristics of the microporous membrane tube,air flow rate,cross - flow rate, liquid surface tension and viscosity.

参考文献

[1]	朱锡海,任欣,陈卫国.气浮分离技术研究现状与方向[J].水处理技术,1991(06):355.
[2]	徐振华,赵红卫,方为茂,钟本和,潘美英,陈刚,罗永钦.金属微孔管制造微气泡的研究[J].环境污染治理技术与设备,2006(09):78-82.
[3]	吴辉煌.表面化学[M].北京:化学工业出版社,1991:21.
[4]	O. Skurtys;P. Bouchon;J.M. Aguilera .Formation of bubbles and foams in gelatine solutions within a vertical glass tube[J].Food hydrocolloids,2008(4):706-714.
[5]	Rodrigues R T;Rubio J .New basis for measuring the size distribution of bubbles[J].Minerals Engineering,2006,16:757-765.
[6]	Kazakis N A;Mouza A A;Paras S V .Experimental study of bubble formation at metal porous spargers:Effect of liquid properties and sparger characteristics on the initial bubble size distribution[J].Chern Eng Sri,2008,137:256-281.
[7]	Ryan WL.;Hemmingsen EA. .Bubble formation at porous hydrophobic surfaces[J].Journal of Colloid and Interface Science,1998(1):101-107.
[8]	J.A. Torrealba-Vargas;J.A. Finch .Continuous air rate measurement In flotation cells: Some fundamental considerations[J].International Journal of Mineral Processing,2006(2):85-92.
[9]	Arakawa T;Yamamoto T;Shoji S .Micro-bubble formation with organic membrane in a multiphase microfluidic system[J].Sensors and Actuators, A. Physical,2008(1):58-63.
[10]	Forrester SE.;Rielly CD. .Bubble formation from cylindrical, flat and concave sections exposed to a strong liquid cross-flow[J].Chemical Engineering Science,1998(8):1517-1527.
[11]	程传炫.表面物理化学[M].北京:科学技术文献出版社,1995:132-133.
[12]	Kukizaki M;Wada T .Effect of the membrane wettability on the size and size distribution of microbubbles formed from Shirasu-porous-glass (SPG) membranes[J].Colloids and Surfaces, A. Physicochemical and Engineering Aspects,2008(1/3):146-154.

上一张下一张

计量

下载量()
访问量()

作者相关

文章评分

您的评分：
1

0%
2

0%
3

0%
4

0%
5

0%

材料期刊网