Numerical simulation of gas-solid flow characteristics in multi-jet cyclone

doi:10.3969/j.issn.0438-1157.2014.12.008

Abstract

Abstract: Based on Fluent 6.3.26, the gas-solids two-phase flow behavior and details of multi-jet cyclone with swirling based on nozzles, was simulated and analyzed with the Reynolds stress model (RSM) and discrete particle model (DPM). Compared with conventional cyclones, peak value of tangential velocity and average value of free-vortex reached 160 m·s^-1 and 130 m·s^-1 respectively, generating higher flow rotation intensity. Volume rates of downward flow kept declining along the central line, particularly in the stabilization region, inducing more chances for particles being entrained by inner upward flow with lower collection efficiency. Local roof wall-jet and circulating flow nearby the inlet of the hopper were typical secondary flows of multi-jet cyclone. Gross pressure loss of the separator was 27.43 kPa, consisting of outer swirl flow 4.57 kPa (21.8%), inner swirl flow 5.76 kPa (27.6%) in the nozzles region, and outer swirl flow 5.85 kPa (27.6%), inner swirl flow 4.01 kPa (18.9%) in the stabilization region. Particles with diameters larger than 10 μm could be collected completely with cut-diameter 1.6 μm, making it suitable for industrial application. Analyzing with the particle mechanical model in this paper, the critical diameter of particle that can be separated was 1—2 μm and particle concentration for particles large than 3 μm in the vortex finder was less than 0.15 g·m^-3.

Key words: multi-jet cyclone, gas-solid flow characteristics, swirling based on nozzles, numerical simulation, separation, flow

摘要： 基于商用软件Fluent 6.3.26,采用雷诺应力模型及DPM离散相模型并结合理论分析,对基于喷嘴造旋的射流式分离器内两相流动特性进行了模拟计算,得到了较为全面的两相流动规律与细节.结果显示,分离器内部切向速度峰值可达160 m·s^-1,自由涡区的切向速度约为130 m·s^-1,旋流强度明显高于传统旋风单管;沿轴向下,下行流流量逐次减少,其中稳流体顶部下行流降低最为明显,下行流减少致使颗粒卷入内旋流概率增加,分离效果下降;分离器内部局部存在顶部贴壁射流、射流区二次流及灰斗口旋涡流等次级流动;分离器压降约为27.43 kPa,喷嘴区内外旋流能耗分别为4.57 kPa(21.8%)、5.76 kPa(27.6%),稳流体区内外旋流能耗分别为5.85 kPa(27.6%)、4.01 kPa(18.9%);分离器对应的切割粒径较小,约为1.6 μm,极限粒径约为10 μm,符合工业应用要求;基于所建颗粒受力模型及模拟条件下,分离空间可分离的临界粒径为1～2 μm,3 μm及以上颗粒的逃逸浓度小于 0.15 g·m^-3,满足下游烟机对气流的净化要求.

关键词: 多喷嘴射流式分离器, 气固流动特性, 喷嘴造旋, 数值模拟, 分离, 流动

CLC Number:

TQ051.8

ZHAO Yan, XU Weiwei, WANG Jianjun, WANG Rui, GAO Guangcai, JIN Youhai. Numerical simulation of gas-solid flow characteristics in multi-jet cyclone[J]. CIESC Journal, 2014, 65(12): 4699-4708.

赵艳, 许伟伟, 王建军, 王锐, 高光才, 金有海. 多喷嘴射流式分离器内气固流动特性的数值模拟[J]. 化工学报, 2014, 65(12): 4699-4708.

References 20

[1]	Xie Kaiyun (谢凯云), Yan Tao (阎涛). Commercial application of new type BSX 3rd-stage cyclone separator in FCC unit [J]. Petroleum Refinery Engineering (炼油技术与工程), 2010, 40 (4):30-32
[2]	Li Daohong (李道宏). Application of windspout separator in FCC energy recovery system [J]. Petroleum Processing and Petrochemicals (石油炼制与化工), 1994, 25 (8): 41-44
[3]	Ling Zhiguang (凌志光), Huang Cunkui (黄存魁). Investigation of 3D flow field in vortex type cyclone separator [J]. Acta Mechanica Sinica (力学学报), 1989, 21 (3): 266-272
[4]	Wang Jianjun (王建军), Tan Huimin (谭慧敏), Xu Weiwei (许伟伟), Wang Xinhua (王新华), Jin Youhai (金有海). Numerical study on gas-solid two-phase flow in guide vane cyclone tube with different dust discharge structure [J]. CIESC Journal (化工学报), 2010, 61 (9):2257-2264
[5]	Tan Huimin (谭慧敏), Wang Jianjun (王建军), Ma Yanjie (马艳杰), Jin Youhai (金有海). Analysis of the influence of dust discharge cone geometry on the gas-solid flow field in tangential inlet cyclone separator [J]. Journal of Chemical Engineering of Chinese Universities (高校化学工程学报), 2011, 25 (4): 590-596
[6]	Wu Xiaolin (吴小林), Xiong Zhiyi (熊至宜), Ji Zhongli (姬忠礼), Shi Mingxian (时铭显). Numerical simulation of processing vortex core in cyclone separator [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2007, 58 (2): 383-390
[7]	Song Jianfei (宋健斐), Wei Yaodong (魏耀东), Shi Mingxian (时铭显). Asymmetry of gas-phase flow field in cyclone separator [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2005, 56 (8): 1397-1402
[8]	Xu Weiwei (许伟伟), Jin Youhai (金有海), Wang Jianjun (王建军). Control of escaped particles by slotted vortex finder in PSC type cyclone tube [J]. CIESC Journal (化工学报), 2010, 61 (1): 55-59
[9]	Shukla S K, Shukla P, Ghosh P. Evaluation of numerical schemes using different simulation methods for the continuous phase modeling of cyclone separators [J]. Advanced Powder Technology, 2011, 22 (2): 209-219
[10]	Tan Huimin (谭慧敏), Wang Jianjun (王建军), Qi Chenggang (亓成刚), Jin Youhai (金有海). Back mixing of particles in guide vane separator [J]. CIESC Journal (化工学报), 2011, 62 (3): 716-722
[11]	Cui Jie (崔洁), Chen Xueli (陈雪莉), Gong Xin (龚欣), Wang Fuchen (王辅臣). Numerical simulation of three-dimension flow field in a new-type cyclone separator with a radial inlet structure [J]. Journal of Chemical Engineering of Chinese Universities (高校化学工程学报), 2010, 24 (3): 388-394
[12]	Wang Haigang (王海刚), Liu Shi (刘石). Application and comparison of different turbulence models in the three-dimensional numerical simulation of cyclone separators [J]. Journal of Engineering for Thermal Energy and Power (热能动力工程), 2003, 18 (4): 337-343
[13]	El-Batsh H M. Improving cyclone performance by proper selection of the exit pipe [J]. Applied Mathematical Modelling, 2013, 37 (7): 5286-5303
[14]	Gao Cuizhi (高翠芝), Sun Guogang (孙国刚), Dong Ruiqian (董瑞倩). Effect of vortex finder on axial velocity distribution patterns in cyclones [J]. CIESC Journal (化工学报), 2010, 61 (9): 2409-2416
[15]	Chen J, Liu X. Simulation of a modified cyclone separator with a novel exhaust [J]. Separation and Purification Technology, 2010, 73 (2): 100-105
[16]	Liu Meili (刘美丽) , Mao Yu (毛羽) , Wang Jiangyun (王江云). Impact of linkage type between primary and secondary cyclone on oil-gas distribution in FCC [J]. Acta Petrolei Sinica: Petroleum Processing Section (石油学报:石油加工) , 2010, 26 (5):718-724
[17]	Khairy Elsayed, Chris Lacor. Optimization of the cyclone separator geometry for minimum pressure drop using mathematic models and CFD methods [J].Chemical Engineering Science, 2010, 65 (22): 6048-6058
[18]	David Winfield, Mark Cross, Nick Croft, David Paddison, Iran Craig. Performance comparison of a single and triple tangential inlet gas separator inlet gas separation cyclone: a CFD study [J]. Powder Technology, 2013, 235: 520-531
[19]	Wang Jiangyun (王江云), Mao Yu (毛羽), Liu Meili (刘美丽), Wang Juan (王娟). Numerical simulation of strongly swirling flow in cyclone separation by using an advanced RNG k-ε model [J]. Acta Petrolei Sinica: Petroleum Processing Section (石油学报: 石油加工), 2010, 26 (1): 8-13
[20]	Yuan Zhulin (袁竹林), Zhu Liping (朱立平), Geng Fan (耿凡), Peng Zhengbiao (彭正标). Gas Solid Two Phase Flow and Numerical Simulation (气固两相流动与数值模拟) [M]. Nanjing: Southeast University Press, 2013: 34