Modeling and simulation of continuous catalytic reforming reactor

doi:10.3969/j.issn.0438-1157.2012.11.031

CIESC Journal ›› 2012, Vol. 63 ›› Issue (11): 3591-3596.DOI: 10.3969/j.issn.0438-1157.2012.11.031

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Modeling and simulation of continuous catalytic reforming reactor

LIANG Chao, ZHANG Quanling

Institute of Cyber-system and Control, Zhejiang University, Hangzhou 310027, Zhejiang, China

Received:2012-08-04 Revised:2012-08-12 Online:2012-11-05 Published:2012-11-05
Supported by:
supported by the National Key Technology R&D Program(2012BAF10B04)and the Fundamental Research Funds for the Central Universities.

催化重整装置反应器的建模与仿真

梁超, 张泉灵

浙江大学智能系统与控制研究所, 浙江杭州 310027

通讯作者: 张泉灵
作者简介:梁超(1988-),男,硕士研究生。
基金资助:
国家科技支撑计划项目(2012BAF10B04);中央高校基本科研业务费专项资金。

Abstract

Abstract: This paper developed a new kinetic model for catalytic reforming reactions based on the lumping theory and catalytic reforming reaction mechanisms.The developed model thoroughly analyzed the mutual reaction relationships among paraffin,cycloparaffin and aromatics,and covered most related reactions included in the continuous catalytic reforming progress.In order to resolve the challenges of the parameter estimation,the number of estimated parameters was decreased to 99 through reasonable supposition and the originally complex reaction network was split into several simpler sub-networks according to the number of carbon atoms.An iteration method combined of BFGS and SQP algorithms was then implemented to increase the accuracy of the parameter estimation.The developed model was used to simulate a continuous catalytic reforming reactor for verifying the model accuracy.And the simulation result showed that the model successfully predicted the reformate composition in the reactor and was proved to be able to meet the accuracy requirement of the industrial applications.

Key words: catalytic reforming, kinetic model, parameter estimation

摘要： 针对催化重整装置的流程模拟,基于集总理论与催化重整反应机理,提出了一种反应器的模型。该模型的反应网络较全面地考虑了烷烃、环烷烃及芳烃之间的反应关系,覆盖了重整反应过程中的大部分反应。为了降低参数估计的难度,通过合理假设将待估参数数量减少至99个,并将复杂的反应网络依据碳原子数划分为C₆~C₁₁₊六个反应子网络,再采用BFGS算法与SQP算法相结合的分组迭代估计方法以降低参数估计的误差。通过催化重整装置的模拟计算对模型进行了验证,结果表明,模型能够对反应产物组成进行较准确的预测,可满足现代工业应用对模型精度的需求。

关键词: 催化重整, 动力学模型, 参数估计

CLC Number:

TQ018

LIANG Chao, ZHANG Quanling. Modeling and simulation of continuous catalytic reforming reactor[J]. CIESC Journal, 2012, 63(11): 3591-3596.

梁超, 张泉灵. 催化重整装置反应器的建模与仿真[J]. 化工学报, 2012, 63(11): 3591-3596.

References 13

[1]	Hu Yongyou(胡永有),Su Hongye(苏宏业).The research summarize of catalytic reforming unit simulation[J].Control and Instruments in Chemical Industry(化工自动化及仪表),2002,29(2):19-23
[2]	Wang Lianshan(王连山),Zhang Quanling(张泉灵),Liang Chao(梁超).A 38-lumped kinetic model for reforming reaction and its application in continuous catalytic reforming[J].CIESC Journal(化工学报),2012,63(4):1076-1082
[3]	Mills G A,Heinemann H,Oblad A G.Catalytic mechanism[J].Ind. Eng. Chem.,1953,45(1):134-137
[4]	Lin Shixiong(林世雄).Petroleum Refining Engineering(石油炼制工程)[M].3rd ed.Beijing:Petroleum Industry Press,2000:473
[5]	Froment G F.The kinetics of complex catalytic reactions[J].Chem. Eng. Sci.,1987,42(5):1073-1087
[6]	Ramage M P,Graziani K P,Krambeck F J.Development of mobil’s kinetic reforming model[J].Chem. Eng. Sci.,1980,35:41-48
[7]	Taskar U,Riggs J B.Modeling and optimization of a semiregenerative catalytic naphtha reformer[J].AIChE J.,1997,43(3):740-753
[8]	Hu Yongyou(胡永有),Su Hongye(苏宏业),Chu Jian(褚健).Modeling and simulation of commercial catalytic reformers[J].Journal of Chemical Engineering of Chinese Universities(高校化学工程学报),2003,17(4):418-424
[9]	Weng Huixin(翁惠新),Jiang Hongbo(江洪波),Chen Zhi(陈志).Lumped model for catalytic reforming(Ⅱ):Experiment design and kinetic parameter estimation[J].Journal of Chemical Industry and Engineering(China)(化工学报),1994,45(5):531-537
[10]	Krane H G,Croh A B,Shulman B D.Reactions in catalytic reforming of naphthas//Murphree E V.Proceedings of the 5th World Petroleum Congress[C].New York,USA:1959:39-51
[11]	Hou Weifeng(侯卫锋).Simulation and optimization of naphtha catalytic reforming process and its application.Hangzhou:Zhejiang University,2006
[12]	Zhou Hongjun(周红军),Shi Mingliang(石铭亮),Weng Huixin(翁惠新),Ling Zeji(凌泽济),Jiang Hongbo(江洪波).Lumped kinetic model of aromatic type catalytic naphtha reforming[J].Acta Petrolei Sinica:Petroleum Processing Section(石油学报:石油加工),2009,25(4):545-550
[13]	Hou Weifeng(侯卫锋),Su Hongye(苏宏业),Hu Yongyou(胡永有),Chu Jian(褚健).Lumped kinetics model and its on-line application to commercial catalytic naphtha reforming process[J].Journal of Chemical Industry and Engineering(China)(化工学报),2006,57(7):1605-1611

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Modeling and simulation of continuous catalytic reforming reactor

催化重整装置反应器的建模与仿真

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