OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

化工学报 2015

射流鼓泡反应器的混合特性

DOI: 10.11949/j.issn.0438-1157.20150435, PP. 4438-4445

郭天琪,黄正梁,王靖岱,蒋斌波,阳永荣

Keywords: 多相反应器,混合,气泡,射流,输入功率

Full-Text Cite this paper Add to My Lib

Abstract:

射流鼓泡反应器以液体射流代替搅拌实现液相混合,具有结构简单、制造及维护费用低等诸多优点,研究其混合特性对于反应器的设计、优化及放大具有重要意义。以空气-水作为模拟介质,采用KCl电解质溶液为示踪剂考察了表观气速和射流Reynolds数的大小对液相宏观混合时间的影响,并从能量输入的角度对射流鼓泡反应器的混合机制进行分析。研究发现,在实验条件下(表观气速变化范围为0.0006～0.0343m·s-1,射流Reynolds数的变化范围为1.75×104～7.00×104),鼓泡的加入使得均相射流反应器内的液相混合得到改善;随着表观气速增大,液相宏观混合时间先缩短后延长;当气体输入功率或液体输入功率不变时,混合时间随总输入功率的增大而缩短。通过对多组实验数据的回归分析,提出了液相宏观混合时间与液体输入功率和气体输入功率的经验关联式,计算值与实际值吻合较好。最后基于提出的关联式,发现当总输入功率一定时,混合时间随气体输入功率的增加先缩短后延长,临界转变点在气体输入功率为总功率的61%处,此时气液两相协同作用最强。

References

[1]	Meng Huibo(孟辉波), Wang Yanfen(王艳芬), Yu Yanfang(禹言芳), Wang Wei(王伟), Wang Feng(王丰), Wu Jianhua(吴剑华). Research progress of mixing time in jet mixing equipment [J]. Chemical Industry and Engineering Process(化工进展), 2012, 31 (12): 2615-2625.
[2]	Fossett H, Prosser L E. The application of free jets to the mixing of fluids in bulk [J]. Proceedings of the Institution of Mechanical Engineers, 1949, 160 (1): 224-232.
[3]	Fox E A , Gex V E. Single-phase blending of liquids[J]. AIChE Journal, 1956, 2 (4): 539-544.
[4]	Lane A G C, Rice P. Comparative assessment of the performance of the three designs for liquid jet mixing [J]. Industrial & Engineering Chemistry Process Design and Development, 1982, 21 (4): 650-653.
[5]	Simon M, Fonade C. Experimental study of mixing performances using steady and unsteady jets [J]. The Canadian Journal of Chemical Engineering, 1993, 71 (4): 507-513.
[6]	Brooker L. Mixing with the jet set [J]. Chemical Engineer-London, 1993, (550): 16.
[7]	Ranade V V. Towards better mixing protocols by designing spatially periodic flows: the case of a jet mixer [J]. Chemical Engineering Science, 1996, 51 (11): 2637-2642.
[8]	Giorges A T, Forney L J, Wang X. Numerical study of multi-jet mixing [J]. Chemical Engineering Research and Design, 2001, 79 (5): 515-522.
[9]	Jayanti S. Hydrodynamics of jet mixing in vessels [J]. Chemical Engineering Science, 2001, 56 (1): 193-210.
[10]	Rahimi M, Parvareh A. Experimental and CFD investigation on mixing by a jet in a semi-industrial stirred tank [J]. Chemical Engineering Journal, 2005, 115 (1/2): 85-92.
[11]	Evans G M. A study of a plunging jet bubble column[D]. New Castle: University of Newcastle, 1990.
[12]	Blenke H. Biochemical loop reactors [J]. Biotechnology, 1985, 2: 465-517.
[13]	Evans G M, Jameson G J. Hydrodynamics of a plunging liquid jet bubble-column [J]. Chemical Engineering Research and Design, 1995, 73(6): 679-684.
[14]	Amiri T Y, Moghaddas J S, Moghaddas Y. A jet mixing study in two phase gas-liquid systems [J]. Chemical Engineering Research and Design, 2011, 89(3A): 352-366.
[15]	Paul E L, Atiemo-Obeng V, Kresta S M. Handbook of Industrial Mixing: Science and Practice[M]. New York: John Wiley & Sons, 2004.
[16]	Zlokarnik M. Stirring[M]. Wiley Online Library, 1988.
[17]	Ma Yuelong(马跃龙), Huang Juan(黄娟), Shen Chunyin(沈春银), Dai Gance(戴干策). Liquid phase mixing time in bubble columns [J]. Journal of East China University of Science and Technology(华东理工大学学报), 2010, 36 (2): 165-172.
[18]	Tian Yanli(田艳丽).Numerical simulation on flow field of rotory jet mixing system and nozzle structure optimization[D]. Hangzhou: Zhejiang University, 2008.
[19]	Miron A S, Garcia M C C, Camacho F G, Grima E M, Chisti Y. Mixing in bubble column and airlift reactors [J]. Chemical Engineering Research and Design, 2004, 82 (10): 1367-1374.
[20]	Haque M W, Nigam K, Joshi J B. Optimum gas sparger design for bubble columns with a low height-to-diameter ratio [J]. Chemical Engineering Journal, 1986, 33(2): 63-69.
[21]	Zhang Yuanxing(张元兴), Xu Xueshu(许学书). Biochemical Reactor Engineering(生物反应器工程)[M]. Shanghai: East China University of Science and Technology Press, 2001.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133