随机分布纤维束间纵向层流时传质的数值模拟

Numerical simulation of mass transfer in axial flow through randomly packed fiber bundle

在线阅读下载PDF

导出

摘要按层流流动理论模型,对纤维为随机分布的中空纤维膜组件的壳程,在恒定壁面传质量和恒定壁面浓度边界条件下的传质现象进行了数值模拟,并得到了不同装填率下传质Sherwood数关联式。结果表明,纵向层流时,随机分布纤维间的传质仍可分进口段和充分发展段。对于某一给定的纤维束,在传质的充分发展段,传质Sherwood数为一个定值,且较纤维束规则排列时小得多,纤维分布不均一性将导致膜组件的传质能力下降。在传质进口段,传质Sherwood数也较纤维束规则排列时要小,装填率不但对传质系数的关联式Sh=BReaScbf(de/L)的系数B值有影响,且对该式中的Reynolds数的指数a和Schmidt数的指数b值也均有影响。 According to the theoretical model for laminar flow,the mass transfer in the shell-side of randomly distributed hollow fiber bundles under two boundary conditions is investigated.One boundary condition assigns a constant mass flow rate,and the other assigns a constant concentration.The correlations of mass transfer Sherwood number are obtained under different packing ratios.The results show that the mass transfer for the axial laminar flow in the randomly distributed fiber bundles can be divided into developing region and fully developed region as well as those in a tube.In the fully developed region of a given randomly distributed fiber bundle,Sherwood number is a certain value and much smaller than that in the fully developed region of a regular array fiber bundles.The non-uniform distribution of hollow fibers decreases the performance of mass transfer in the module.In the developing region of a given random distributed fiber bundle,Sherwood number is also smaller than that in the developing region of in the regular array fiber bundles.The packing ratio affects not only the coefficient B,but also the exponents a of Re and b of Sc in the correlation Sh=BReaScbf（de/L）.

作者陈冰冰张元平高增梁金伟娅

机构地区浙江工业大学化工机械设计研究所制药工程省部共建重点实验室(浙江工业大学)

出处《化工学报》 EI CAS CSCD 北大核心 2010年第6期1406-1414,共9页 CIESC Journal

基金浙江省自然科学基金项目(Y406070)~~

关键词随机分布中空纤维传质系数数值模拟 randomly distribution hollow fiber mass transfer coefficient numerical simulation

分类号 TQ028.8 [化学工程]

作者简介联系人：陈冰冰（1968-），男，副教授。

引文网络
相关文献

参考文献20

1Sullivan R R. Specific surface measurements on compact bundles of parallel fibers. Journal of Applied Physics, 1942, 13:725-730.
2Costello M J, Fane A G, Hogan P A, Schofield R W. The effect of shell side hydrodynamics on the performance of axial flow hollow fiber modules. Journal of Membrane Science, 1993, 80:1-11.
3Chen V, Hlavacek M. Application of Voronoi tessellation for modeling randomly packed hollow-fiber bundles. AIChE Journal, 1994, 40.. 606-612.
4Gabelman A, Hwang S T. Hollow fiber membrane contacts. Journal of Membrane Science, 1999, 159: 61-106.
5Yang M C, Cussler E L. Designing hollow-fiber contactors. AIChEJournal, 1986, 32:1910-1915.
6Prasad R, Sirkar K K. Dispersion free solvent extraction with microporous hollow-fiber modules. AIChE Journal, 1988, 34:177-188.
7Gawronski R, Wrzesinska B. Kinetics of solvent in hollow- fiber contactors. Journal of Membrane Science, 2000, 168, 213-222.
8Wu J, Chen V. Shell-side mass transfer performance of of randomly packed hollow fiber modules. Journal Membrane Science, 2000, 172: 59-74.
9Lipnizki F, Field R W. Mass transfer performance for hollow fibre modules with shell-side axial feed flow: using an engineering approach to develop a framework. Journal of Membrane Science, 2001, 193:195-208.
10Keshavarz P, Ayatollahi S, Fathikalajahi J. Mathematical modeling of gas-liquid membrane eontaetors using random distribution of fibers. Journal of Membrane Science, 2008, 325: 98-108.

二级参考文献10

1丁卫平,何立群,骆晓东,赵刚,程曙霞,高大勇.壁面对中空纤维透析器传质系数的影响[J].化学通报,2004,67(11):825-829. 被引量：3
2Chan D Y C,Hughes B D,Paterson L.Fluid capacity distribution of random porous media.Transp.Porous Media,1988,3:81-94
3Chen V,Hlavacek M.Application of voronoi tessellation for modeling randomly packed hollow fiber bundles.AIChE J.,1994,40:606-612
4Rogers J D,Long R.Modeling hollow fiber membrane contactors using film theory,voronoi tessellations,and facilitation factors for systems with interface reactions.J.Membr.Sci.,1997,134:1-17
5Wu J,Chen V.Shell-side mass transfer performance of ranmomly packed hollow fiber modules.J.Membr.Sci.,2000,172:59-74
6Miyatake O,Iwashita H.Laminar-flow heat transfer to a fluid flowing axially between cylinders with a uniform wall heat flux.Int.J.Heat Mass Tran.,1991,34:322-327
7Bao L,Lipscomb G G.Well-developed mass transfer in axial flows through randomly packed fiber bundles with constant wall flux.Chem.Eng.Sci.,2002,57:125-132
8Costello M J,Fane A G,Hogan P A.The effect of shell side hydrodynamics on the performance of axial flow hollow fibre modules.J.Membr.Sci.,1993,80:1-11
9Cussler E L.Diffusion Mass Transfer in Fluid System(扩散流体系统中的传质).2nd ed.Wang Yuxin(王宇新),trans.Beijing:Chemical Industry Press,2002:69-75
10姚素薇,赵瑾,张卫国,董大为.单晶硅上电沉积Cu/Co纳米多层膜及其巨磁电阻效应[J].磁流体发电情报,2004,55(3):414-417. 被引量：12

共引文献2

1刘俊,陈冰冰,梁力锦.中空纤维膜组件壳程传质的研究进展[J].轻工机械,2012,30(6):110-114. 被引量：2
2吴云,张楠,张宏伟,贾辉.膜曝气生物膜反应器内流场的CFD模拟及组件优化[J].化工学报,2015,66(1):402-409. 被引量：10

1樊智锋,刘广春,王志,袁力,王世昌.脱除CO_2的膜吸收过程研究[J].膜科学与技术,2005,25(5):34-39. 被引量：10
2姚春梅,魏取福,许凤凤.非织造布表面处理对纳米纤维分布及成型的影响[J].化工新型材料,2013,41(1):73-75. 被引量：1
3赵康,鄢君辉,刘正堂,郑修麟.化学气相沉积传质现象的研究与反应器设计、工艺参数的优化[J].材料导报,2000,14(3):13-15. 被引量：3
4臧传义,马红安,李瑞,李尚升,肖宏宇,黄国锋,贾晓鹏.碳源扩散不均一性对宝石级金刚石单晶生长的影响[J].超硬材料工程,2008,20(1):11-14.
5姜山,朱春英,张璠玢,马友光.微通道内单乙醇胺水溶液吸收CO2/N2混合气的传质特性[J].化工学报,2017,68(2):643-652. 被引量：5
6李季,郑志坚,朱家骅,夏素兰,李勇,文浩.错排降膜阵列气液交叉流界面捕集PM2.5的传质类比模型[J].化工学报,2014,65(11):4238-4245. 被引量：6
7李鹏,钱震涛,侯跃峰.管壳式甲醇合成装置增产节能改造技术[J].化学工业与工程技术,2010,31(5):50-52.
8Alfred Watzl.用于电子领域的高技术玻璃纤维织物[J].产业用纺织品,2005,23(10):42-43. 被引量：1
9沙勇,成弘,袁希钢,余国琮.伴有Marangoni效应的传质动力学[J].化工学报,2003,54(11):1518-1523. 被引量：13
10任丹萍,段谟华,张国亮,孟琴,杨志宏,吴景.填充密度对中空纤维膜接触器精馏过程壳程传质的影响[J].化工学报,2009,60(9):2226-2231. 被引量：5

化工学报

2010年第6期

浏览历史

内容加载中请稍等...

随机分布纤维束间纵向层流时传质的数值模拟

参考文献20

二级参考文献10

共引文献2

相关作者

相关机构

相关主题

浏览历史