提升管反应器不同喷嘴角度的气固流动特性研究

›› 2019, Vol. 50 ›› Issue (8): 89-95.

提升管反应器不同喷嘴角度的气固流动特性研究

王胜胜,刘丙超,祝晓琳,李春义

中国石油大学（华东）重质油国家重点实验室

收稿日期:2018-12-26 修回日期:2019-03-02 出版日期:2019-08-12 发布日期:2019-08-27
通讯作者: 李春义 E-mail:chyli@upc.edu.cn

STUDY ON GAS-SOLID FLOW CHARACTERISTICS IN RISER REACTOR WITH DIFFERENT NOZZLE ANGLES

Wang Shengsheng,Liu Bingchao,Zhu Xiaolin,Li Chunyi

Received:2018-12-26 Revised:2019-03-02 Online:2019-08-12 Published:2019-08-27
Contact: Li Chunyi E-mail:chyli@upc.edu.cn

摘要/Abstract

摘要： 在大型循环流化床冷态模拟试验装置上对喷嘴与提升管竖直方向的不同夹角进行了考察。对3种不同夹角结构下的颗粒浓度轴径向分布、瞬时颗粒浓度信号以及概率密度进行了分析研究，结果表明：在预提升段和输送段3种结构并无明显差别，颗粒浓度以及瞬时信号波动的差别主要集中在喷嘴上方附近区域；相比于传统等径提升管而言，变径提升管内床层固含率增加，颗粒浓度分布更加均匀，颗粒浓度梯度减小，有利于气固两相的混合与接触；在变径提升管内，随着喷嘴角度的增大，气体在整个截面上的扩散速度增加，径向分布更加均匀，气固分离现象得到了有效抑制，气固湍动剧烈，接触效率较高。

关键词: 提升管反应器, 喷嘴, 颗粒浓度, 接触效率

Abstract: The effect of angles between nozzle and riser in vertical direction on the flow properties was investigated in a large CFB cold simulation test device. The axial and radial distributions of particle concentration，instantaneous particle concentration signal and probability density analysis in three angles cases were investigated. The results showed that in the pre-lift section and the conveying section，no significant difference between the three cases was found，and the difference existed mainly in the vicinity zone above the nozzle; compared with the traditional equal-diameter riser，the solid-holdup of the bed in the variable-diameter riser increased，the particle distribution was more uniform, but the particle concentration gradient reduced，which is beneficial to the mixing and contact of the gas-solid two phases. As the nozzle angle increased，the diffusion velocity of the gas increased over the entire section，the radial distribution was more uniform，the gas-solid separation phenomenon was effectively suppressed，the gas-solid turbulence was more severe，resulting in more effective contact in the variable-diameter riser.

Key words: riser reactor, nozzle, particle concentration, contact efficiency

王胜胜刘丙超祝晓琳李春义. 提升管反应器不同喷嘴角度的气固流动特性研究[J]. , 2019, 50(8): 89-95.

Wang Shengsheng Liu Bingchao Zhu Xiaolin Li Chunyi. STUDY ON GAS-SOLID FLOW CHARACTERISTICS IN RISER REACTOR WITH DIFFERENT NOZZLE ANGLES [J]. , 2019, 50(8): 89-95.

参考文献

［1］陈俊武 . 催化裂化工艺与工程［M］．北京:中国石化出版社，2005:605-732
［2］Zhu H, Zhu J. Characterization of fluidization behavior in the bottom region of CFB risers[J]. Chemical Engineering Journal, 2008, 141(1–3):169-179.
［3］Guan G, Fushimi C, Ishizuka M, et al. Flow behaviors in the downer of a large-scale triple-bed combined circulating fluidized bed system with high solids mass fluxes[J]. Chemical Engineering Science, 2011, 66(18):4212-4220.
［4］吴文龙, 韩超一, 李春义, 等. 变径提升管反应器扩径段内气固流动特性研究[J]. 石油炼制与化工, 2014, 45(11):54-59.
［5］甘洁清, 李春义, 杨朝合, 等. 多流型新型提升管冷模实验研究[J]. 石油学报（石油加工）, 2012, 28(2):188-194.
［6］Dong W, Wang W, Li J. A multiscale mass transfer model for gas–solid riser flows: Part 1 — Sub-grid model and simple tests[J]. Chemical Engineering Science, 2008, 63(10):2798-2810.
［7］Dong W, Wang W, Li J. A multiscale mass transfer model for gas–solid riser flows: Part II—Sub-grid simulation of ozone decomposition[J]. Chemical Engineering Science, 2008, 63(10):2811-2823.
［8］范怡平，晁忠喜，卢春喜，等．催化裂化提升管预提升段气固两相流动特性的研究［J］．石油炼制与化工， 1999， 30 (9):43-47
［9］Cui H, Mostoufi N, Chaouki J. Characterization of dynamic gas–solid distribution in fluidized beds[J]. Chemical Engineering Journal, 2000, 79(2):133-143.
［10］Zhu X , Yang C , Li C , et al. Comparative study of gas–solids flow patterns inside novel multi-regime riser and conventional riser[J]. Chemical Engineering Journal, 2013, 215-216(Complete):188-201.
［11］祝晓琳. 变径提升管反应器内气固两相流动特性研究及应用探索[D]. 2014.
［12］苏鲁书, 刘丙超, 朱晴晴,等. 预提升气对循环流态化气力输送的影响[J]. 石油化工, 2017, 46(5):572-579.
［13］刘清华, 杨朝合, 张欢, 等. 扩径段参数对变径提升管内气固流动的影响[J]. 炼油技术与工程, 2009, 39(1):8-13.
［14］Qiang G . Radial Non-uniformity Index Research on High-density, High-flux CFB Riser with Stratified Injection[J]. China Petroleum Processing & Petrochemical Technology, 2012, 14(4):64-72.
［15］刘丙超, 王胜胜, 苏鲁书, 等. 多层进气提升管扩径预提升段流动特性研究[J]. 石油炼制与化工, 2018, 49(4):51-57.

[1]	余立公. 催化裂化装置采用LTAG工艺回炼不同物料的效果[J]. 石油炼制与化工, 2023, 54(6): 18-25.
[2]	刘丙超王胜胜苏鲁书祝晓琳李春义. 多层进气提升管扩径预提升段流动特性研究[J]. , 2018, 49(4): 51-57.
[3]	苏鲁书刘丙超张善鹤李春义. 进气喷嘴位置对循环流化床反应器循环量的影响[J]. 石油炼制与化工, 2017, 48(9): 40-45.
[4]	苏鲁书李春义张洪菡李修仪. 预提升对循环流化床反应器中气固流动特性的影响[J]. 石油炼制与化工, 2017, 48(2): 94-100.
[5]	韩超一吴文龙陶蕾李春义. 双循环流化床提升管中气固流动特性及接触效率研究[J]. 石油炼制与化工, 2016, 47(3): 16-24.
[6]	李欣疏刘雪东李柏贤李振才. FCC进料雾化喷嘴结构对内部流场及混合特性的影响[J]. , 2016, 47(2): 21-25.
[7]	薄守石王剑白飞孙兰义. 不同进料形式鼓泡床反应器流动特性的模拟研究[J]. 石油炼制与化工, 2016, 47(2): 9-15.
[8]	韩超一陈晓成吴文龙李春义. 内构件对变径提升管内气固流动特性的影响[J]. 石油炼制与化工, 2016, 47(1): 5-10.
[9]	杜玉朋张成涛杨朝合. 两段提升管催化裂解多产丙烯工艺十集总反应动力学模型[J]. 石油炼制与化工, 2015, 46(12): 47-52.
[10]	吴文龙韩超一李春义杨朝合. 变径提升管反应器扩径段内气固流动特性研究[J]. 石油炼制与化工, 2014, 45(11): 54-59.
[11]	李志超王璐杨朝合李春义. FCC环管进料喷嘴对提升管中气固流动结构的影响[J]. 石油炼制与化工, 2014, 45(1): 47-50.
[12]	祝然沈本贤刘纪昌. 减压蜡油催化裂化结构导向集总动力学模型研究[J]. 石油炼制与化工, 2013, 44(2): 37-42.
[13]	李志超张志强杨朝合李春义. 催化裂化提升管中的流动结构及气固接触效率[J]. 石油炼制与化工, 2012, 43(12): 59-63.