固相颗粒在旋流场形成过程中的运动分析

doi:10.16085/j.issn.1000-6613.2018-0084

摘要/Abstract

摘要：

通过CFD-DEM耦合计算方法模拟不同粒径颗粒在FX-50水力旋流器内的运动行为，分析旋流器内旋流分离场的形成过程，连续相的运动采用求解平均化的Navier-Stokes方程得到，离散相的运动通过离散元法计算。采用欧拉-拉格朗日方法，通过Freestream曳力模型传递相间数据，分析了流体的速度场、压力场，颗粒群的速度、受力、颗粒-颗粒和颗粒-壁面的接触作用力。结果表明，当循环流与入口流汇合时，颗粒速度损失较大；当旋流场稳定后，60μm粒径颗粒群在旋流器锥段的堆积最严重，分离速度较70μm、80μm颗粒低；颗粒平均速度的变化为先减小再增大，直到以后的稳定变化。旋流场未稳定时颗粒在竖直方向的运移速度大于旋流场稳定后竖直方向的运移速度，80μm颗粒竖直方向平均速度始终大于60μm和70μm。颗粒-颗粒和颗粒-壁面的接触过程中，颗粒的受力以法向方向为主，当颗粒与壁面接触时，所受合力最大；由于流动前期颗粒在旋流器内运动轨迹不稳定，颗粒随机碰撞明显，导致颗粒平均接触力波动较大，当旋流场达到稳定状态以后，数值改变很小。

关键词: 计算流体力学-离散单元法, 水力旋流器, 计算流体力学, 离散单元法, 欧拉-拉格朗日, Freestream曳力模型

Abstract:

The CFD-DEM(computational fluid dynamics-discrete element method) coupling calculation method was used to simulate the movement of particles with different particle sizes in the FX-50 hydrocyclone, which analyzed the formation process of the separation field. The continuous phase was obtained by solving the averaged Navier-Stokes equation. The movement of the discrete phase was calculated by the discrete element method. The fluid vlocity and pressure field, particle group velocity, total force, particle-particle and particle-wall contact force was analyzed by Eulerian-Lagrangian method and Freestream drag model. It was shown that the particle velocity loss was relatively large at the confluence of recirculation flow and inlet flow. The particles with diameter of 60μm showed the greatest possibility to accumulate at the cone part of the cyclone and the lowest separation efficiency compared to those particles with diameters of 70μm and 80μm. The variation of the average velocity of the particles experienced the process of decrease first and then increase until its final steady state. The velocity of the particle was larger in the unstable swirl field than that in the stable swirl field vertically. Furthermore, the average vertical speed of particles with 80μm was always greater than that of particles of 60μm and 70μm. In the process of particle-particle and particle-wall contact, the force of the particle was mainly in the normal direction. When the particle was in contact with the wall, the force of contact was the maximum. Due to the instability of the particles trajectory in the early transient flow, the random collisions obviously, resulting in a large fluctuation of the average contact force of the particles. While the fluctuation became unconspicuous when the swirl field reached a steady state.

Key words: CFD-DEM, hydrocyclone, computational fluid dynamics, discrete element method, Eulerian-Lagrangian, Freestream drag model

中图分类号:

TE992.3

刘洪斌,张进,肖慧娜,谢超. 固相颗粒在旋流场形成过程中的运动分析[J]. 化工进展, 2019, 38(03): 1236-1243.

Hongbin LIU,Jin ZHANG,Huina XIAO,Chao XIE. Movement analysis of solid particles during the formation of swirl field[J]. Chemical Industry and Engineering Progress, 2019, 38(03): 1236-1243.

图/表 16

图1 旋流器XY截面

表1 水力旋流器截面尺寸

几何特征	尺寸	几何特征	尺寸
直径D	50mm	直段长度H	40mm
溢流管直径d ₀	13mm	溢流管插入深度h ₀	25mm
底流管直径 d _s	10mm	锥角θ	15°
入口截面a×a	12mm×12mm

图2 网格模型

图3 不同网格数量下的切向速度曲线

表2 接触参数

接触对象	恢复系数	静摩擦系数	动摩擦系数
颗粒-颗粒	0.3	0.3	0.01
颗粒-壁面	0.3	0.2	0.01

表3 计算模型中使用的材料参数

材料	参数	数值
固相	密度/kg·m^?3	2500
	粒径/μm	60、70、80
	泊松比	0.25
	剪切模量/MPa	10
	入口颗粒速度/m·s^?1	2.9
液相	密度/kg·m^?3	998.2
	黏度/Pa·s	0.001
	入口速度/ m·s^?1	3
壁面	密度/ kg·m^?3	1200
	泊松比	0.3
	剪切模量/MPa	10

图4 XY截面的速度分布云图

图5 XY截面压力分布云图

图6 固相颗粒在2.0s的速度云图

图9 固相颗在2.0s的受力云图

图10 固相颗粒平均合力曲线

图11 固相颗粒竖直方向平均合力曲线

图12 颗粒与颗粒的平均切向接触力

图13 颗粒与颗粒的平均法向接触力

图14 颗粒与壁面的平均切向接触力

图15 颗粒与壁面的平均法向接触力

参考文献 20

1	任连城, 梁政, 钟功祥, 等 . 基于CFD的水力旋流器流场模拟研究[J]. 石油机械, 2005, 33(11): 15-17.
	REN L C , LIANG Z , ZHONG G X , et al . CFD-based simulation of flow field of hydrocyclones [J]. China Petroleum Machinery, 2005, 33(11): 15-17.
2	黄思 . 水力旋流器内油水分离过程的三维数值模拟[J]. 华南理工大学学报(自然科学版), 2006, 34(11): 25-28.
	HUANG S . 3D numerical simulation of oil water separation in hydrocyclone[J]. Journal of South China University of Technology (Natural Science Edition), 2006, 34(11): 25-28.
3	刘晓敏, 檀润华, 蒋明虎, 等 . 水力旋流器结构形式及参数关系研究[J]. 机械设计, 2005, 22(2): 26-29.
	LIU X M , TAN R H , JIANG M H , et al . Research on structural from and parametric relations of hydrocyclones[J]. Journal of Machien Design, 2005, 22(2): 26-29.
4	苏劲, 袁智, 侍玉苗, 等 . 水力旋流器细粒分离效率优化与数值模拟[J]. 机械工程学报, 2011, 47(20): 183-190.
	SU J , YUAN Z , SHI Y M , et al . Separation efficiency optimization of liquid-solid hydrocyclone and numerical simulation [J]. Journal of Mechanical Engineering, 2011, 47(20): 183-190.
5	张亭, 王卫兵, 冯静安, 等 . 水力旋流器固液分离效率优化控制仿真[J]. 计算机仿真, 2016, 33(8): 210-213.
	ZHANG T , WANG W B , FENG J A , et al . Numerical simulation of the solid-liquid separation flow field in hydrocyclone [J]. Computer Simulation, 2016, 33(8): 210-213.
6	SRIPRIYA R , SURESH N , CHANDRA S , et al . The effect of diameter and height of the inserted rod in a dense medium cyclone to suppress air core [J]. Minerals Engineering, 2013, 42: 1-8.
7	喻黎明, 邹小艳, 谭弘, 等 . 基于CFD-DEM耦合的水力旋流器水沙运动三维数值模拟[J]. 农业机械学报, 2016, 47(1): 126-132.
	YU L M , ZOU X Y , TAN H , et al . 3D numerical simulation of water and sediment flow in hydrocyclone based on coupled CFD-DEM [J]. Transactions of the Chinese Society for Agricultural Machinery, 2016, 47(1): 126-132.
8	黄思, 杨富翔, 宿向辉 . 运用CFD-DEM耦合模拟计算离心泵内非稳态固液两相流动[J]. 科技导报, 2014, 32(27): 28-31.
	HUANG S , YANG F X , SU X H . Unsteady numerical simulation for solid-liquid two-phase flow in centrifugal pump by CFD-DEM coupling [J]. Science & Technology Review, 2014, 32(27): 28-31.
9	任立波 . 稠密颗粒两相流的CFD-DEM耦合并行算法及数值模拟[D]. 济南: 山东大学, 2015.
	REN L B . A parallel CFD-DEM coupling model and numerical simulation of dense particulate two-phase flows [D]. Jinan: Shandong University, 2015.
10	CHU K W , WANG B , YU A B , et al . CFD-DEM modelling of multiphase flow in dense medium cyclones [J]. Powder Technology, 2009, 193(3): 235-247.
11	CHU K W , KUANG S B , YU A B , et al . Prediction of wear and its effect on the multiphase flow and separation performance of dense medium cyclone [J]. Minerals Engineering, 2014, 56(2): 91-101.
12	唐波 . 基于颗粒运动行为调控的旋流器分离过程研究及结构设计[D]. 上海: 华东理工大学, 2016.
	TANG B . Numerical study of the separation process and structure design by regulating the flow behavior of particle phase in hydrocyclones [D]. Shanghai: East China University of Science and Technology, 2016.
13	喻黎明, 谭弘, 邹小艳, 等 . 基于CFD-DEM耦合的迷宫流道水沙运动数值模拟[J]. 农业机械学报, 2016, 47(8): 65-71.
	YU L M , TAN H , ZOU X Y , et al . Numerical simulation of water and sediment flow in labyrinth channel based on coupled CFD-DEM [J]. Transactions of the Chinese Society for Agricultural Machinery, 2016, 47(8): 65-71.
14	胡国强, 等 . 颗粒系统的离散元素法分析仿真[M]. 武汉: 武汉理工大学出版社, 2010: 25.
	HU G Q , et al . Analysis and simulation of granular system by discrete element method using EDEM [M]. Wuhan: Wuhan University of Technology Press, 2010: 25.
15	孙其诚, 王光谦 . 颗粒物质力学导论[M]. 北京: 科学出版社, 2009: 16.
	SUN Q C , WANG G Q . Analysis of the force of particulate matter [M]. Beijing: Science Press, 2009: 16.
16	QIU L C , WU C Y . A hybrid DEM/CFD approach for solid-liquid flows [J]. Journal of Hydrodynamics, Ser. B, 2014, 26(1): 19-25.
17	TONG Z B , YANG R Y , CHU K W , et al . Numerical study of the effects of particle size and polydispersity on the agglomerate dispersion in a cyclonic flow [J]. Chemical Engineering Journal, 2010, 164(2/3): 432-441.
18	HSIEH K T , RAJAMANI R K . Mathematical model of the hydrocyclone based on physics of fluid flow [J]. AIChE Journal, 2010, 37(5): 735-746.
19	李建明, 陈文梅, 苏晓东 . 旋流器排口比对固粒轴向流场的影响[J]. 化工机械, 1995，22(3): 132-135.
	LI J M , CHEN W M , SU X D . Influence of the cone ratio of hydrocyclones on axial velocity fields of solid particles [J]. Chemical Engineering & Machinery, 1995，22(3): 132-135.
20	NEESSE T , DUECK J . Dynamic modelling of the hydrocyclone [J]. Minerals Engineering, 2007, 20(4): 380-386.

[1]	王云飞, 秦蕊, 郑利军, 李焱, 李清平. 旋转填充床CFD模拟研究进展[J]. 化工进展, 2023, 42(S1): 1-9.
[2]	孙继鹏, 韩靖, 唐杨超, 闫汉博, 张杰瑶, 肖苹, 吴峰. 硫黄湿法成型过程数值模拟与操作参数优化[J]. 化工进展, 2023, 42(S1): 189-196.
[3]	罗成, 范晓勇, 朱永红, 田丰, 崔楼伟, 杜崇鹏, 王飞利, 李冬, 郑化安. 中低温煤焦油加氢反应器不同分配器中液体分布的CFD模拟[J]. 化工进展, 2023, 42(9): 4538-4549.
[4]	卜治丞, 焦波, 林海花, 孙洪源. 脉动热管计算流体力学模型与研究进展[J]. 化工进展, 2023, 42(8): 4167-4181.
[5]	邱沫凡, 蒋琳, 刘荣正, 刘兵, 唐亚平, 刘马林. 气固流化床化学反应数值模拟中颗粒尺度模型研究进展[J]. 化工进展, 2023, 42(10): 5047-5058.
[6]	颜子涵, 陈群云, 李卓, 付融冰, 李彦伟, 吴志根. 改进型土壤破碎混拌结构的性能数值分析与优化[J]. 化工进展, 2022, 41(S1): 72-80.
[7]	彭德其, 冯源, 王依然, 谭卓伟, 俞天兰, 吴淑英. 立式缩放管内液固颗粒群浓度分布与汇聚特性[J]. 化工进展, 2022, 41(9): 4662-4672.
[8]	古新, 张前欣, 王超鹏, 方运阁, 李宁, 王永庆. U形导流板换热器传热和阻力性能分析[J]. 化工进展, 2022, 41(7): 3465-3474.
[9]	徐涵卓, 刘志浩, 孙宝昌, 张亮亮, 邹海魁, 罗勇, 初广文. 流体驱动旋转装备应用与数值模拟方法研究进展[J]. 化工进展, 2022, 41(6): 2806-2817.
[10]	陈龙, 李霞霞, 李伟祥, 戚锐, 邓鑫, 吴斌鑫. 聚丙烯非织造布熔喷过程的计算流体力学模拟研究进展[J]. 化工进展, 2022, 41(2): 537-553.
[11]	朱明军, 胡大鹏. 操作参数对三相卧螺离心机油水砂分离性能影响模拟及实验分析[J]. 化工进展, 2022, 41(10): 5188-5199.
[12]	王戈, 孙志伟, 谭蔚, 邱威, 朱国瑞. 异形纤维阵列过滤特性的数值模拟[J]. 化工进展, 2022, 41(1): 30-39.
[13]	王彦谦, 王远洋. 微反应器中费托合成的研究进展[J]. 化工进展, 2021, 40(S2): 185-191.
[14]	亢嘉妮, 何立东, 范文强, 杨扬. 环氧乙烷装置T形三通管件故障原因分析与改进[J]. 化工进展, 2021, 40(S1): 32-42.
[15]	王宇, 潘振海. 水平及竖直基底上微小固着液滴的蒸发特性分析[J]. 化工进展, 2021, 40(7): 3632-3644.