Predicting vaporization of feedstock in zoning catalytic cracking by UNIFAC model

doi:10.3969/j.issn.0438-1157.2014.07.031

Abstract

Abstract: A novel zoning catalytic cracking (ZCC), which processed vacuum gas oil (VGO) and vacuum residue (VR) in different zones under respective optimal conditions to avoid competitive adsorption effect, was proposed. Aiming at comparing routine fluid catalytic cracking (FCC) with ZCC, vaporization of feedstock was predicted with the UNIFAC model. Vaporization of feedstock was higher than 70% (mass) in both ZCC and FCC under investigated conditions. Higher oil-catalyst-mixing temperature, less atomized steam and lower VR blending ratio were beneficial to feedstock vaporization. Vaporization of feedstock decreased by 5.44%－7.53%(mass) when VR blending ratio increased from 30%(mass) to 50%(mass). When VR blending ratio was lower than 50%(mass), vaporization of separate feedstocks in ZCC was lower than that of blending feedstock in routine FCC. When VR blending ratio reached 50%(mass), separate feeding used in ZCC was more beneficial to vaporization of feedstock. That was the result of the influence of dispersion effect of VGO on VR and competitive vaporization between VGO and VR.

Key words: petroleum, prediction, vaporization, fluid catalytic cracking, UNIFAC model

摘要： 以不同减压馏分油（VGO）/减压渣油（VR）混合比例的重油为研究对象，采用基团贡献模型（UNIFAC）预测了常规催化裂化工艺（FCC）与分区催化裂化工艺（ZCC）中原料的汽化率。在所考察的催化裂化油剂混合条件下，原料的汽化率均大于70%（质量分数）。高油剂混合温度使饱和蒸气压升高，而大雾化水蒸气量有利于降低油气分压使泡露点温度降低，均使原料汽化率升高。VR掺炼比例对原料汽化率影响很大，当掺炼比例从30%（质量分数）提高至50%（质量分数）时，原料汽化率降低5.44%～7.53%（质量分数）。当VR掺炼比例较低（<50%）时，常规FCC工艺比ZCC工艺的原料汽化率高，当VR掺炼比例达到50%时，ZCC工艺的分开进料方式更有利于原料的汽化。这取决于VGO对VR的分散作用和VGO与VR的竞争汽化造成的影响。

关键词: 石油, 预测, 汽化, 催化裂化, UNIFAC模型

CLC Number:

TE624

JIN Nan, WANG Gang, XU Chunming, GAO Jinsen. Predicting vaporization of feedstock in zoning catalytic cracking by UNIFAC model[J]. CIESC Journal, 2014, 65(7): 2710-2716.

金楠, 王刚, 徐春明, 高金森. 采用UNIFAC模型预测催化裂化分区转化中原料的汽化率[J]. 化工学报, 2014, 65(7): 2710-2716.

References 22

[1]	Qu Guohua(瞿国华). Important orientation of China's refining industry in 21th century—processing heavy and superheavy crude oil[J]. Sino-Global Energy(中外能源), 2007, 12(3): 54-62
[2]	Chen Junwu(陈俊武), Lu Hanwei(卢捍卫). Prospects of status and role of FCC in refinary—FCC will continue to play a leading role in petroleum refining industry[J]. Acta Petrolei Sinica: Petroleum Processing Section (石油学报:石油加工), 2003, 19(1): 1-10
[3]	Leclère K, Briens C, Gauthier T, Bayle J, Bergougnou M,Guigon P. Liquid vaporization in a fluidized bed[J]. Industrial & Engineering Chemistry Research, 2001, 40(23): 5415-5420
[4]	Mirgain C, Briens C, Pozo M D, Loutaty R, Bergougnou M. Modeling of feed vaporization in fluid catalytic cracking[J]. Industrial & Engineering Chemistry Research, 2000, 39(11): 4392-4399
[5]	Xu Chunming(徐春明), Lü Lianggong(吕亮功), Tang Qinglin(唐清林), Lin Shixiong(林世雄). Catalyst cracking reaction pathway and on-line sampling in commercial riser[J]. Journal of the University of Petroleum: Edition of Natural Science (石油大学学报: 自然科学版), 1997, 21(2): 72-75
[6]	Buchanan J S. Analysis of heating and vaporization of feed droplets in fluidized catalytic cracking risers[J]. Industrial & Engineering Chemistry Research, 1994, 33(12): 3104-3111
[7]	Mo Weijian(莫伟坚), Lin Shixiong(林世雄), Wang Guangxun(王光埙), Yang Guanghua(杨光华). Study on the vaporization process of oil droplets in catalytic cracking unit[J]. Acta Petrolei Sinica: Petroleum Processing Section (石油学报:石油加工), 1990, 6(3): 1-10
[8]	Xu Chunming(徐春明), Zhang Qihao(张琪皓), Liu Junxia(刘军霞). A method and its device of determining residue vaporization[P]: CN, 00105545.3. 2000-08-30
[9]	Gao H, Wang G, Wang H, Chen J, Xu C, Gao J. A conceptual catalytic cracking process to treat vacuum residue and vacuum gas oil in different reactors[J]. Energy & Fuels, 2012, 26(3): 1870-1879
[10]	Gao H, Wang G, Li R, Xu C, Gao J. Study on the catalytic cracking of heavy oil by proper cut for higher conversion and desirable products[J]. Energy & Fuels, 2012, 26(3): 1880-1891
[11]	Wu Xianzhong(吴献忠), Cui Xiaoyu(崔晓钰), Li Meiling(李美玲). Estimation of refrigerant mixture phase equilibrium with UNIFAC model [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2005, 56(10): 1832-1836
[12]	Zhou Yongchang(周永昌), Zhao Suoqi(赵锁奇), Xu Zhiming(许志明), Liang Yongmei(梁咏梅). New group contribution method for estimating average boiling point of heavy oil fractions [J]. Journal of Chemical Industry and Engineering(China) (化工学报), 2004, 55(8): 1224-1229
[13]	Xu C, E H, Chung K. Predicting vaporization of residual by UNIFAC model and its implications to RFCC operations[J]. Energy & Fuels, 2003, 17(3): 631-636
[14]	E Hong(鄂红), Fu Jiawen(富嘉文), Chen Zehui(陈泽辉), Shou Deqing(寿德清). Study on the prediction of VLE for petroleum fractions from Xinjiang crude oil with UNIFAC method[J]. Journal of the University of Petroleum: Edition of Natural Science (石油大学学报: 自然科学版), 1997, 21(1): 72-76
[15]	Xiong Yan(熊焰), Ding Jing(丁靖), Yu Dahong(虞大红), Peng Changjun(彭昌军), Liu Honglai(刘洪来). Group contribution method for prediction of thermophysical properties and phase behavior of ionic liquids[J]. CIESC Journal(化工学报), 2012, 63(3): 667-676
[16]	Fang Wenjun(方文军), Xu Bin(徐斌), Yu Qingsen(俞庆森), Lin Ruisen(林瑞森), Wang Guoping(王国平). Thermochemical property prediction on basis of H NMR determination for petroleum fractions[J]. Journal of Chemical Industry and Engineering(China) (化工学报), 2002, 53(4): 417-421
[17]	Gmehling J, Rasmussen P, Fredenslund A. Vapor-liquid equilibriums by UNIFAC group contribution. Revision and extension[J]. Industrial & Engineering Chemistry Process Design and Development, 1982, 21(1): 118-127
[18]	Jensen T, Fredenslund A, Rasmussen P. Pure-component vapor pressures using UNIFAC group contribution[J]. Industrial & Engineering Chemistry Fundamentals, 1981, 20(3): 239-246
[19]	Kikic I, Alessi P, Rasmussen P, Fredenslund A. On the combinatorial part of the UNIFAC and UNIQUAC models[J]. The Canadian Journal of Chemical Engineering, 1980, 58(2): 253-258
[20]	Hamza H H, Mikolaj P G. Vapor-liquid equilibrium of petroleum fractions single fraction and binary systems[J]. Journal of Chemical and Engineering Data, 1977, 22(3): 285-289
[21]	Leclère K, Briens C, Gauthier T, Bayle J, Guigon P, Bergougnou M. Experimental measurement of droplet vaporization kinetics in a fluidized bed[J]. Chemical Engineering and Processing: Process Intensification, 2004, 43(6): 693-699
[22]	Sun Yiqun(孙益群), Gao Yongcan(高永灿). Application of heavy oil emulsification technology in RFCC process[J]. Industrial Catalysis(工业催化), 2008, 16(9): 46-50