窄筛分颗粒气固流态化特性数值模拟研究Numerical simulation study on gas-solid fluidization characteristics of the particles with narrow size distribution
郭昊乾,李雪飞,李小亮
GUO Haoqian,LI Xuefei,LI Xiaoliang
摘要(Abstract):
为更好地指导工业生产,了解不同粒径颗粒在气固流化床中的状态以及流化床中颗粒分布情况,针对气固流化床中窄筛分颗粒流态化特性进行数值模拟研究。通过流场模拟软件分析在相同流化床中不同粒径段的颗粒(46~80、106~113、185~221μm)和不同流化床进气速度条件下所能达到的体积分数和流化床层高度以及达到这一指标所需时间,并采用欧拉-欧拉模型和SIMPLE算法计算不同气速条件下的颗粒体积分数、速度分布。结果表明,在相同气速条件下,颗粒粒径增大,导致流化床内颗粒体积分数最高点与最低点的差距变大,颗粒分布不均匀性增加,同时床层整体高度下降,床层内颗粒密度上升,颗粒体积分数下降,流化效果降低;相同颗粒粒径情况下,增加气速可降低流化床内部颗粒的体积分数,增加气体与固体颗粒的接触面积,增强流化效果,但减少了流化床内部颗粒速度矢量分布达到均匀的时间,颗粒分布不均匀性更加明显。
In order to better guide the industrial production,understand the state of particles of different particle sizes in the gas-solid fluidized bed and the distribution of particles in the fluidized bed,the fluidization characteristics of the narrow-screened particles in the gassolid fluidized bed were numerically simulated.The flow field simulation software was used to analyze the volume fraction and the height of the fluidized bed and the time required to reach this target under the conditions of particles with different particle sizes( 46-80,106-113,185-221 μm) in the same fluidized bed and different inlet velocity of the fluidized bed. The Euler-Euler model and SIMPLE algorithm were used to calculate the particle volume fraction and velocity distribution under different gas velocity conditions.The results show that the increase in particle size causes the larger difference between the highest point and the lowest point of the particle volume fraction in the fluidized bed under the same gas velocity,meanwhile,the unevenness of particle distribution increases,the overall height of the bed decreases,the particles in the bed density increases,the fluidization decreases with the decrease of the volume fraction of the particles.In the case of the same particle size,increasing the gas velocity can reduce the volume fraction of particles inside the fluidized bed,increase the contact area of the gas and solid particles,and enhance the fluidization effect.However,the time of the particle velocity vector distribution inside the fluidized bed reaching a uniform is reduced,and the uneven distribution of particles is more obvious.
关键词(KeyWords):
窄筛分;流态化;气固流化床;气泡
narrow size distribution;fluidization;gas-solid fluidized bed;bubble
基金项目(Foundation): 国家重点研发计划资助项目(2018YFB0605604);; 国家科技重大专项资助项目(2016ZX05045-005)
作者(Author):
郭昊乾,李雪飞,李小亮
GUO Haoqian,LI Xuefei,LI Xiaoliang
DOI: 10.13226/j.issn.1006-6772.19121001
参考文献(References):
- [1]李兰廷,吴涛,梁大明,等.活性焦脱硫脱硝脱汞一体化技术[J].煤质技术,2009(3):46-49.LI Lanting,WU tao,LIANG Daming,et al.A summary of combined desulfurization denitration and demercury technology using activated coke[J].Coal Quality Technology,2009(3):46-49.
- [2] LI G H,CHEN P Z.Technical challenges and progress in fluidized bed chemical vapor deposition of polysilicon[J]. Chinese Journal of Chemical Engineering,2011,19(5):747-753.
- [3] Zhang P,WANG Y G,GU X C,et al.Effect of operation parameters on fines formation during thermal decomposition of silane[J].Solar Energy,2017,155:75-81.
- [4] DUAN J H,FANG L,GAO S,et al.Numerical simulation and structural optimization of multi-compartment fluidized bed reactor for biomass fast pyrolysis[J]. Chemical Engineering&Processing:Process Intensification,2019,140:114-126.
- [5] QI X B,ZHANG H,ZHU J.Solids concentration in the fully developed region of circulating fluidized bed downers[J].Powder Technology,2008,183(3):417-425.
- [6]卢志明,朱沈瑾,石来民,等.单喷管鼓泡流化床流动特性的数值模拟[J].燃烧科学与技术,2015,21(5):408-414.LU Zhiming,ZHU Shenjin,SHI Laimin,et al.Numerical simulation of flow characteristics in a single nozzle bubbling fluidized bed[J].Journal of Combustion Science and Technology,2015,21(5):408-414.
- [7]王伟文,董海红,陈光辉,等.气固流化床内宽筛分硅粉颗粒流化特性的数值模拟[J].高校化学工程学报,2011,25(2):276-282.WANG Weiwen,DONG Haihong,CHEN Guanghui,et al.Numerical simulation of fluidization characteristics of wide sieved silica fume particles in gas-solid fluidized bed[J]. Journal of Chemical Engineering of Chinese University,2011,25(2):276-282.
- [8] GAO J,LAN X,FAN Y,et al.Hydrodynamics of gas-solid fluidized bed of disparately sized binary particles[J]. Chemical Engineering Science,2009,64(20):4302-4316.
- [9] TAGHIPOUR F,ELLIS N,WONG C..Experimental and computational study of gas-solid fluidized bed hydrodynamics[J].Chemical Engineering Science,2005,60(24):6857-6867.
- [10] DU W,BAO X,XU J,et al. Computational fluid dynamics(CFD)modeling of spouted bed:Influence of frictional stress,maximum packing limit and coefficient of restitution of particles[J]. Chemical Engineering Science,2006,61(14):4558-4570.
- [11] MOSTAFAZADEH M,RAHIMZADEH H,HAMZEI M.Numerical analysis of the mixing process in a gas-solid fluidized bed reactor[J].Powder Technology,2013,239:422-433.
- [12]薛莲金,李信宝,王渝程,等.基于欧拉-欧拉多相流模型对生物质快速热裂解的数值模拟[J].动力工程学报,2019,39(5):394-401.XUE Lianjin,LI Xinbao,WANG Yucheng,et al. Numerical simulation of rapid thermal cracking of biomass based on Euler-Euler multiphase flow model[J].Journal of Chinese Society of Power Engineering,2019,39(5):394-401.
- [13]陈光辉,祝华腾,郭秀玲,等.鼓泡破泡一体化高效精馏塔盘流动特性与CFD模拟[J].化工学报,2017,68(12):4633-4640.CHEN Guanghui,ZHU Huateng,GUO Xiuling,et al.Flow characteristics and CFD simulation of bubble-breaking integrated highefficiency distillation tray[J]. CIESC Journal,2017,68(12):4633-4640.
- [14]荆德吉,葛少成,刘剑.基于欧拉-欧拉模型的落煤塔控尘技术研究[J].中国安全科学学报,2012,22(10):126-132.JING Deji,GE Shaocheng,LIU Jian. Research on dust control technology of coal falling tower based on Euler-Euler model[J].China Safety Science Journal,2012,22(10):126-132.
- [15] RAY M,CHOWDHURY F,SOWINSKI A,et al.An Euler-Euler model for mono-dispersed gas-particle flows incorporating electrostatic charging due to particle-wall and particle-particle collisions[J]. Chemical Engineering Science,2019,197:327-344.