水平窄矩形通道内液固两相的流动特性

doi:10.16085/j.issn.1000-6613.2017-1744

化工进展 ›› 2018, Vol. 37 ›› Issue (06): 2092-2100.DOI: 10.16085/j.issn.1000-6613.2017-1744

水平窄矩形通道内液固两相的流动特性

任立波^1,2, 赵新强¹, 张少峰¹

1 河北工业大学化工学院, 天津 300132;
2 上海板换机械设备有限公司, 上海 201508

收稿日期:2017-08-17 修回日期:2017-10-23 出版日期:2018-06-05 发布日期:2018-06-05
通讯作者: 张少峰,教授,博士生导师,研究方向为化工过程多相流。
作者简介:任立波(1983-),博士后,工程师。E-mail:by101010@163.com。
基金资助:
河北省科学技术研究与发展计划项目（12276711D）。

Hydrodynamic investigation of liquid-solid flows in horizontal narrow rectangular channel

REN Libo^1,2, ZHAO Xinqiang¹, ZHANG Shaofeng¹

1 School of Chemical Engineering, Hebei University of Technology, Tianjin 300132;
2 Shanghai Heat Transfer Equipment Co., Ltd., Shanghai 201508

Received:2017-08-17 Revised:2017-10-23 Online:2018-06-05 Published:2018-06-05

摘要/Abstract

摘要： 液固两相输运研究主要集中于圆管，窄矩形通道内液固两相水平流动特性和固相扩散特性的研究鲜见报道。在12mm高的水平窄矩形通道内，采用实验研究和计算流体力学-离散单元法（CFD-DEM）数值模拟相结合的方法研究了玻璃珠-水液固两相流动，揭示了压力梯度特性、固相流动特性及其统计学特性、固相扩散特性变化规律。结果表明：在固相运动过程中，形成稀密两相共存的流动结构，密相在水平方向上被加速且向上运动；随着固相浓度增加，固相沿垂向的分布更加均匀，但固相速度非对称分布增强；固相垂向扩散强度随固相浓度增加而减弱。沿垂向将流道分为3个区域：近壁区、颗粒高频碰撞区和颗粒稀疏区。在近壁区，黏性底层-湍流层交界面与颗粒相互作用并将颗粒向流道中心挤压，导致沿流向的固相速度分量和固相体积分散波动较大；在颗粒高频碰撞区，在垂直方向上颗粒无序运动造成其垂向速度分量波动比近壁区和颗粒稀疏区的大；沿流向的固相速度分量和固相体积分数标准差值在整个颗粒高频碰撞区内保持在较小的变化范围，然后在颗粒稀疏区内迅速降低为零。

关键词: 计算流体力学-离散单元法, 液固, 水平窄矩形通道

Abstract: Extensive research on the liquid-solid two-phase transportation in horizontal circular tubes has been conducted, but the liquid-solid two-phase hydrodynamics and the solid phase diffusion characteristics in narrow rectangular channels are rarely reported. The glass beads-water two-phase hydrodynamics in horizontal narrow rectangular channel with 12mm height are investigated by the approach of experimental method and CFD-DEM simulation. The pressure gradient characteristics, the solid phase flow characteristics, the statistical properties, and the solid phase diffusion characteristics are explored. Simulation results showed that a dilute disperse phase and a dense cluster phase were formed in the process of solid movement. The dense cluster phase is elevated and accelerated along the horizontal direction. Increasing solid concentration can reduce the non-uniform degree of the solid distribution while enhance the asymmetry of the solid vertical velocity profiles. The vertical solid dispersion intensity can be suppressed with the increase of the solid concentration. Three distinct regions are identified along the vertical direction, corresponding to the near-wall region, the solid highly-collisional region, and the dilute particle-laden region, respectively. The viscous-turbulent interface interacts with the particles in the near-wall region, which drives the particles away from the bottom wall and thus leads to the greatest standard variances of the solid stream-wise velocity and the solid concentration. In the solid highly-collisional region, the fluctuation of the solid vertical velocity is larger because of the chaos motion than that in two other regions. The standard variances of the solid stream-wise velocity and the solid concentration keep little change in the solid highly-collisional flow region and then decay rapidly to zero in the dilute particle-laden region.

Key words: CFD-DEM, liquid-solid, horizontal narrow rectangular channel

中图分类号:

TK12

任立波, 赵新强, 张少峰. 水平窄矩形通道内液固两相的流动特性[J]. 化工进展, 2018, 37(06): 2092-2100.

REN Libo, ZHAO Xinqiang, ZHANG Shaofeng. Hydrodynamic investigation of liquid-solid flows in horizontal narrow rectangular channel[J]. Chemical Industry and Engineering Progress, 2018, 37(06): 2092-2100.

参考文献

[1] DAAS M, SRIVASTAVA R, SKUDARNOV P, et al. Sensitivity analysis of the influence of slurry characteristics and pipe size on Wasp model's accuracy[J]. Powder Technology, 2008, 185(1):36-42.
[2] RAVELET F, BAKIR F, KHELLADI S, et al. Experimental study of hydraulic transport of large particles in horizontal pipes[J]. Experimental Thermal & Fluid Science, 2013, 45(2):187-197.
[3] LEE M S, MATOUSEK V, CHUNG C K, et al. Pipe size effect on hydraulic transport of jumoonjin sand-experiments in a dredging test loop[J]. Terra. Et. Aqua., 2005, 99:3-10.
[4] KUASHAL D R, TOMITA Y. Experimental investigation for near-wall lift of coarser particles in slurry pipeline using γ-ray densitometer[J]. Powder Technology, 2007, 172(3):177-187.
[5] MATOUSEK V. Pressure drops and flow patterns in sand-mixture pipes[J]. Experimental Thermal and Fluid Science, 2002, 26(6/7):693-702.
[6] KUASHAL D R, SATO K, TOYOTA T, et al. Effect of particle size distribution on pressure drop and concentration profile in pipeline flow of highly concentrated slurry[J]. International Journal of Multiphase Flow, 2005, 31(7):809-823.
[7] JASSON S, SUMNER R J, GILLIES R G, et al. The effect of particle shape on pipeline friction for Newtonian slurries of fine particles[J]. Canadian Journal of Chemical Engineering, 2000, 78(4):717-725.
[8] JASSON S, SHOOK C A. Anomalous friction in slurry flows[J]. Canadian Journal of Chemical Engineering, 2000, 78(4):726-730.
[9] GILLIES R G, SHOOK C A, XU J. Modelling heterogeneous slurry flows at high velocities[J]. Canadian Journal of Chemical Engineering, 2010, 82(5):1060-1065.
[10] ROCO M C, SHOOK C A. Modeling of slurry flow:the effect of particle size[J]. Canadian Journal of Chemical Engineering, 2010, 61(4):494-503.
[11] HASHEMI S A, SADIGHIAN A, SHAH S I A, et al. Solid velocity and concentration fluctuations in highly concentrated liquid-solid (slurry) pipe flows[J]. International Journal of Multiphase Flow, 2014, 66(7):46-61.
[12] THOMAS A D. Predicting the deposit velocity for horizontal turbulent pipe flow of slurries[J]. International Journal of Multiphase Flow,1979, 5(2):113-129.
[13] GILLIES R G, SCHAAN J, SUMNER R J, et al. Deposition velocities for newtonian slurries in turbulent flow[J]. Canadian Journal of Chemical Engineering, 2010, 78(4):704-708.
[14] MATOUSEK V. Predictive model for frictional pressure drop in settling-slurry pipe with stationary deposit[J]. Powder Technology, 2009, 192(3):367-374.
[15] 王光谦,倪晋仁.固液两相流流速分布特性的试验研究[J]. 水利学报, 1992(11):43-49. WANG G Q, NI J R. Experimental study on velocity distribution characteristics of solid-liquid two-phase flows[J]. Journal of Hydraulic Engineering, 1992(11):43-49.
[16] LIU Q Q, SINGH V P. Fluid-solid interaction in particle-laden flows[J]. Journal of Engineering Mechanics, 2004, 130(12):1476-1485.
[17] 夏建新, 倪晋仁. 水沙流中颗粒脉动特性[J]. 水利学报, 2003(7):7-13. XIA J X, NI J R. Characteristics of particle pulsation in water-sand flows[J]. Journal of Hydraulic Engineering, 2003(7):7-13.
[18] 钱锐, 蔡保元. 管道固体物料输运最佳流速确定及其应用[J]. 设计与研究, 2001(6):1-2, 8. QIAN R, CAI B Y. Determination of optimum flow velocity for conveying solid material in pipeline and its application[J]. Pipeline Technique and Equipment, 2001(6):1-2, 8.
[19] MEI R. An approximate expression for the shear lift force on a spherical particle at finite reynolds number[J]. International Journal of Multiphase Flow, 1992, 18(1):145-147.
[20] SUN R, XIAO H. Diffusion-based coarse graining in hybrid continuum-discrete solvers:applications in CFD-DEM[J]. International Journal of Multiphase Flow, 2015, 72(23):233-247.
[21] WASP E J, KENNY J P, GANDHI R L, Solid-liquid flow slurry pipeline transportation[M]. Houston:Gulf Publishing Company, 1979:9-16.
[22] WILSON K C, SANDERS R S, GILLIES R G, et al. Verification of the near-wall model for slurry flow[J]. Powder Technology, 2010, 197(3):247-253.
[23] CAPECELATRO J, DESJARDINS O. Eulerian-Lagrangian modeling of turbulent liquid-solid slurries in horizontal pipes[J]. International Journal of Multiphase Flow, 2013, 55:64-79.
[24] KU J H, CHO H H, KOO J H. Heat transfer characteristics of liquid-solid suspension flow in a horizontal pipe[J]. Ksme International Journal, 2000, 14(10):1159-1167.

水平窄矩形通道内液固两相的流动特性

Hydrodynamic investigation of liquid-solid flows in horizontal narrow rectangular channel

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