偏心搅拌槽固液悬浮特性

›› 2008, Vol. 8 ›› Issue (6): 1064-1069.

偏心搅拌槽固液悬浮特性

杨锋苓周慎杰张翠勋陈莲芳

山东大学机械工程学院山东大学机械工程学院过控教研室山东大学机械工程学院过控教研室山东大学机械工程学院过控教研室

收稿日期:2008-07-03 修回日期:2008-08-21 出版日期:2008-12-20 发布日期:2008-12-20
通讯作者: 周慎杰

Investigation on Solid-Liquid Suspension Performance in an Eccentrically Stirred Tank

YANG Feng-Ling Yang Shenjie Zhou ZHANG Cui-xun CHEN Lian-fang

School of Mechanical Engineering，Shandong University School of Mechanical Engineering，Shandong University School of Mechanical Engineering，Shandong University School of Mechanical Engineering，Shandong University

Received:2008-07-03 Revised:2008-08-21 Online:2008-12-20 Published:2008-12-20
Contact: Shenjie Zhou

摘要/Abstract

摘要： 以数值模拟对偏心搅拌时的固液悬浮特性进行了研究，物料选用固相体积分数为15%、粒径为135 mm的球形玻璃珠-水两相体系，采用标准k-e湍流模型模拟液相流动，采用欧拉多相流模型模拟悬浮过程，分析了偏心率对搅拌流型、颗粒浓度分布及能量消耗的影响. 结果表明，偏心搅拌时浓度分布比中心搅拌更为均匀，可改善固液悬浮效果，且具有节能功效；不同偏心率的改善效果不同，偏心率e=0.21时悬浮效果最理想，此时的临界悬浮转速约为中心搅拌时的80%，消耗的功率约为中心搅拌时的90%.

关键词: 四折叶桨, 搅拌槽, 偏心搅拌, 固液悬浮

Abstract: Solid-liquid suspension performance in an eccentrically stirred tank was numerically investigated by using Fluent software. The two-phase system studied consisted of globose glass beads and water. Solid particle volume fraction was 15%, and the particle diameter 135 mm. Standard k-e turbulent model was used to simulate the steady liquid phase flow field, and the unsteady solid-liquid suspension process was simulated with the Eulerian multiphase model. The flow pattern, solids particles concentration distribution and power consumption were extensively analyzed. The results show that, compared with the concentric agitation, the eccentric agitation led to a more homogeneous particle concentration distribution, improved the suspension performance and saved energy. Besides, the improvement of solid-liquid suspension performance varied with the eccentricity. In this work, solid particles reached the best suspension when the eccentricity, e, was 0.21. The critical suspension velocity and power consumption were about 80% and 90% of those in the concentric agitation respectively.

Key words: four-pitched-blade turbine, stirred tank, eccentric agitation, solid-liquid suspension

中图分类号:

TQ027.3

杨锋苓周慎杰张翠勋陈莲芳. 偏心搅拌槽固液悬浮特性[J]. , 2008, 8(6): 1064-1069.

YANG Feng-Ling Yang Shenjie Zhou ZHANG Cui-xun CHEN Lian-fang. Investigation on Solid-Liquid Suspension Performance in an Eccentrically Stirred Tank[J]. , 2008, 8(6): 1064-1069.

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