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底流口直径和锥角对旋流器流场的影响 被引量:9

Influence of Apex Diameter and Cone Angle on the Flow Field Inside Hydrocyclone
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摘要 利用计算流体力学的原理与方法,在底流口直径和锥角的多个水平下对旋流器内部流场进行了数值模拟,以揭示两因素对旋流器流场的影响.结果表明:增大底流口直径,流场内的流速降低,轴向零速包络面向上收缩;增大锥角后,轴向零速包络面的大小相应改变;锥角越小,底流口直径对轴向零速包络面内速度场的影响越小,故对改善分选效果的作用也越不明显;增大底流口直径,旋流器内流场的压强降低,但底流口区域内的压强梯度增大,而锥角不同,其变化程度有所不同,这从某些程度上体现了两因素对旋流器流场的交互影响. A CFD-based numerical simulation of the flow field inside a hydrocyclone was carried out at different levels to reveal the influence of apex diameter and cone angle on the flow field.The results showed that the flow velocity of the field decreases,with increasing apex diameter,then the enveloping surface at zero axial velocity shrinks.When the cone angle increases the size of the enveloping surface changes,and the smaller the cone angle,the less the influnce of apex diameter on the velocity field within the enveloping surface and the more unobvious the effect of improving separation.With the apex diameter increased,the pressure of the flow field decreases but the pressure gradient within the apex region increases differently in accordance to the change in cone angle.The phenomenon reveals the interactive influence between the cone angle and apex diameter in the flow field inside a hydrocyclone to a certain extent.
作者 高淑玲 魏德洲 韩聪 胡瑞彪
机构地区 东北大学资源与土木工程学院
出处 《东北大学学报(自然科学版)》 EI CAS CSCD 北大核心 2010年第5期728-732,共5页 Journal of Northeastern University(Natural Science)
基金 国家重点基础研究发展规划项目(2005CB623701)
关键词 计算流体力学 数值模拟 底流口直径 锥角 旋流器 流场 CFD(computational fluid dynamics) numerical simulation apex diameter cone angle hydrocyclone flow field
分类号 TD923.5 [矿业工程—选矿]
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参考文献11

  • 1赵立新,蒋明虎,孙德智.水力旋流器流场分析与测试[J].化工机械,2005,32(3):139-142. 被引量:9
  • 2邹宽,杨茉,曹玮,胡利光,林高平,章立新,林宗虎.水力旋流器湍流流动的数值模拟[J].工程热物理学报,2004,25(1):127-129. 被引量:36
  • 3刘峰,钱爱军,郭秀军.DSM重介质旋流器流场的数值模拟[J].煤炭学报,2006,31(5):627-630. 被引量:20
  • 4Murphy S, Delfosb R. Prediction of strongly swirling flow within an axial hydrccyclone using two commercial CFD codes [J ]. Chemical Engineering Science, 2007, 62 ( 6 ) : 1619 -1635.
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二级引证文献54

东北大学学报(自然科学版)
2010年 第5期

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