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开孔阳极铝电解槽熔体中气液两相流数值模拟 被引量:5

Numerical simulation of gas-liquid two-phase flow in aluminum reduction cells with perforated anodes
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摘要 目前的电解铝生产工艺以氧化铝为原料,在直流电的作用下,熔融电解质中的氧化铝在高温环境下与碳阳极发生复杂的电化学反应,主要在阳极底掌析出二氧化碳L1J。二氧化碳气体从阳极底掌产生到逸出电解质表面的过程中,一方面会不断搅动电解质熔体,阳极气泡与电解质相互发生复杂的传热传质作用,有利于氧化铝颗粒在高温熔体中均匀快速地溶解和扩散运动;另一方面, Numerical simulation of anodic bubble/electrolyte two-phase flow in the melts of aluminum reduction cells with the Euler-Euler two-fluid model was conducted based on computational fluid dynamics (CFD). A modified k-eturbulence model was used to describe liquid phase turbulence in the simulation, by assuming the pseudo turbulence resulted from anodie bubbles. The results of CFD simulation for traditional no-hole anodes were compared with the experimental data under similar conditions using particle image veIocimetry (PIV). Good agreement was found between the CFD model and PIV measurements, which indicated that the current CFD model could be used to deal with two types of perforated anodes. The electrolyte velocity under perforated anodes could be reduced and the stability of bath flow could be maintained. Perforated anodes could make bath flow more stable. The maximum and average velocity of electrolyte in four-hole anodes were reduced by 9. 53% and 12.89%, respectively. The global average bubble fraction in the melts, the local average bubble fraction in anode-cathode distance (ACD) and the thicknesses of bubble layer under the anode with perforated anodes were less than those with no-hole anodes, but the immersion depth of anodic bubbles in electrolyte was almost the same as that in the case of no-hole anodes. Both ACD and cell voltage could be lowered and energy consumption could be reduced.
作者 詹水清 周孑民 李茂 董英 刘志明 周益文 杨建红
机构地区 中南大学能源科学与工程学院 中国铝业股份有限公司郑州研究院
出处 《化工学报》 EI CAS CSCD 北大核心 2013年第10期3612-3619,共8页 CIESC Journal
基金 国家高技术研究发展计划项目(2010AA065201) 国家自然科学基金项目(50974127 50876116) 中南大学中央高校基本科研业务费专项资金资助项目(2013zzts038)~~
关键词 铝电解槽 开孔阳极 气液两相流 数值模拟 aluminum reduction cells perforated anode gas-liquid two-phase flow numerical simulation
分类号 TF821 [冶金工程—有色金属冶金] TB115 [理学—应用数学]
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  • 1黄俊,吴建康,姚世焕.铝电解槽磁流体流动的数值计算[J].有色冶炼,2002,31(6):25-26. 被引量:4
  • 2闫红杰,周萍,周孑民,吕子剑,周怀敏.空气搅拌式种分槽流场的数值解析及结构参数的优化[J].过程工程学报,2005,5(2):135-138. 被引量:2
  • 3李相鹏,李劼,赖延清,刘业翔,周昊,岑可法.预焙铝电解槽阳极底部开排气沟对电解质流场的影响[J].中国有色金属学报,2006,16(6):1088-1093. 被引量:6
  • 4任必军,王兆文,石忠宁,班允刚,邱竹贤.大型铝电解槽阳极开槽试验的研究[J].矿冶工程,2007,27(3):61-63. 被引量:24
  • 5Mandar V Joshi. CFD interphase Tabib, Swarnendu A Roy, Jyeshtharaj B simulation of bubble culumn--an analysis of force and turbulence models. Chemical Engineering Journal, 2008, 139:589 -614.
  • 6Krishna R, van Baten J M, Ureanu M 1. Three phase Eulerian simulations of bubble column reactors operating in the churn turbulent regime: a scale up strategy. Chemical Engineering Scfence, 2000, 55: 3275- 3286.
  • 7Zhang D, Deen N G, Kuipers J A M. Numerical simulation of dynamic flow behavior in a bubble column: a study of closures for turbulence and interface forces. Chemical Engineering Science, 2006, 61:7593- 7608.
  • 8Mudde R F, Simonin O. Two and three dimensional simulation of a bubble plume using a two fluid model. Chemical Engineering Science, 1999, 54:5061- 5071.
  • 9Hills J H. Radial non uniformity of velocity and voidage in a bubble column. Transactions of the Institution of Chemical Engineers, 1974, 52:1 -9.
  • 10Rampure Mohan R, Kulkrni Amol A, Ranade Vivek V. Hydrodynamic of bubble column reactors at high gas velocity: experiments and computational fluid dynamics (CFD) simulations. Ind. Eng. Chem. Res. , 2007, 46 ; 8431- 8447.

共引文献38

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  • 1薛玉卿,周乃君,包生重.铝电解槽内阳极气泡运动的冷态模拟[J].中国有色金属学报,2006,16(10):1823-1828. 被引量:19
  • 2王志刚,赖延清,刘伟,刘杰,伍玉云.铝电解阳极气泡行为研究进展[J].轻金属,2007(5):27-31. 被引量:13
  • 3WELCH B J, KUSCHEL G I. Crust and alumina powder dissolution in aluminum smelting electrolytes[J]. JOM, 2007, 59(5): 50-54.
  • 4HAVERKAMP R G, WELCH B J. Modelling the dissolution of alumina powder in cryolite[J]. Chemical Engineering and Processing, 1998, 37(6): 177-187.
  • 5BEREZIN A I, ISAEVA L A, BELOLIPETSKY V M, PISKAZHOVA T V, SINELNIKOV V V. A model of dissolution and heating of alumina charged by point-feeding system in "virtual cell" program[C]//KVANDE H. Light Metals 2005. San Francisco CA: TMS, 2005:151-154.
  • 6LILLEBUEN B, BUGGE M, HOIE H. Alumina dissolution and current efficiency in Hall-Hdroult cells[C]//BEARNE G. Light Metals 2009. San Francisco CA: TMS, 2009: 389-394.
  • 7VASYUNINA N V, VASYUNINA I P, MIKHALEV Y G, VINOGRADOV A M. The solubility and dissolution rate of alumina in acidic cryolite aluminous melts[J]. Russian Journal of Non-ferrous Metals, 2009, 50(4): 338-342.
  • 8FENG Y Q, COOKSEY M A, SCHWARZ M P. CFD modeling of alumina mixing in aluminium reduction cells[C]//HAGNI A M. Light Metals 2010. Seattle, WA: TMS, 2010:451-456.
  • 9FENG Y Q, COOKSEY M A, SCHWARZ M P. CFD modeling of alumina mixing in aluminium reduction cells[C]//LINDSAY J Light Metals 2011. San Diego, CA: TMS, 2011: 543-548.
  • 10von KAENEL R, ANTILLE J, ROMERIO M, BESSON O. Impact of magnetohydrodynamic and bubbles driving forces on the alumina concentration in the bath of an Hall-Heroult cell[C]// BARRY S. Light Metals 2013. San Antonio: TMS, 2013: 585-590.

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化工学报
2013年 第10期

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