Methanol to propylene process using moving bed technology and its engineering study

doi:10.3969/j.issn.0438-1157.2014.01.001

Abstract

Abstract: A novel moving bed process for methanol to propylene (MMTP), and conducts engineering analysis for this process were presented. Firstly, according to the principle that the reactor must be matched with reaction catalyst deactivation, the most matching reactor for ZSM-5 catalysts (with mid-level deactivation) is moving bed. Moreover, the MMTP process can not only exert higher propylene selectivity of the catalyst, but also can utilize medium particle circulation rate for reaction and regeneration to serialize and stabilize high yield of propylene process. Secondly, regarding the strong exothermal characteristics of the MMTP reaction, two kinds of processes, fluidized bed one-step operation and fixed bed two-step operation, are compared. Based on the comparison results, it is concluded that the two-step operation of MMTP process can allocate reasonable reaction heat and control product distribution with flexibility. Finally, through integration of heat-exchange network optimization and alcohol-oil refining process, MMTP process owns high propylene yield on the basis of water and energy saving. On the basis of current MMTP process, 10000 t·a^-1 propylene technology package design has been completed. In summary, MMTP owns visible competitive advantages both on technique and economics, which has high application potential in industry.

Key words: methanol to propylene, moving bed, alcohol and oil refining, two-step route, deactivation, optimization

摘要： 提出了一种新型的移动床甲醇制丙烯工艺（MMTP）并进行工程化分析。首先，根据反应器必须与催化剂的反应失活速率相匹配的原则，认为移动床是与失活速率处于中等水平的ZSM-5催化剂相匹配的最佳反应器。因此，MMTP工艺在充分发挥ZSM-5催化剂多产丙烯优势的基础上，结合移动床的中等循环速率进行反应-再生，从而实现催化剂高产丙烯的连续化与稳定化；其次，针对MTP反应的强放热特点，对比了流化床工艺的一步法操作与固定床工艺的两步法操作，发现MMTP工艺采用两步法操作既能合理地分配反应热，又能灵活地调控产品分布；最后，通过换热网络的优化设计与醇油共炼的工艺集成，使得MMTP工艺在节水节能的同时仍具有高丙烯收率。目前，在现有的MMTP工艺技术基础上，已经完成1万吨丙烯/年的工艺包设计，技术和经济的竞争优势十分明显，市场推广应用前景广阔。

关键词: 甲醇制丙烯, 移动床, 醇油共炼, 两步法, 失活, 优化

CLC Number:

TQ028.8

YAN Lixia, JIANG Yuntao, JIANG Binbo, LIAO Zuwei, HUANG Zhengliang, WANG Jingdai, YANG Yongrong, WANG Xieqing. Methanol to propylene process using moving bed technology and its engineering study[J]. CIESC Journal, 2014, 65(1): 2-11.

严丽霞, 蒋云涛, 蒋斌波, 廖祖维, 黄正梁, 王靖岱, 阳永荣, 汪燮卿. 移动床甲醇制丙烯技术的工艺与工程[J]. 化工学报, 2014, 65(1): 2-11.

References 31

[1]	Lee K Y, Lee H K. Influence of catalyst binders on the acidity and catalytic performance of HZSM-5 zeolites for methanol-to-propylene (MTP) process: single and binary binder system[J]. Topics in Catalysis, 2010, 53(3/4): 247-253
[2]	Zhang Minghui (张明辉). The necessity and feasibility about the Chinese industrial development on coal to olefins[J]. Chemical Techno-Economics(化工技术经济), 2006, 24(1): 17-20
[3]	Wang Ke(王科), Li Yang(李杨), Chen Peng(陈鹏). Progress on methanol to propylene process and the catalyst preparing technology[J]. Natural Gas Chemical Industry(天然气化工), 2009, 34(5): 63-76
[4]	Zhang Jingzhong(张静忠), Dai Guihua(戴桂华), Meng Qiang(孟强). Problem discussion of catalyst loss of FMTP techinque[J]. Henan Chemical Industry(河南化工), 2011, 28(2): 34-36
[5]	Li Lixin(李立新), Ni Jinfang(倪进方), Li Yansheng(李延生). Progress and commentary on separating technology of methanol to olefins[J]. Chemical Industry and Engineering Progress(化工进展), 2008, 27(9): 1332-1335
[6]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Liu Ye(刘烨), Wang Xieqing(汪燮卿). Conversion of oxygenate to propylene using moving bed technology[P]: CN, 200810161675.9. 2012-02-01
[7]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Liu Ye(刘烨), Wang Xieqing(汪燮卿). Invention of horizontal moving bed reactor that is fit for oxygenate to propylene reaction[P]: CN, 200810120838.9. 2012-06-13
[8]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Liu Ye(刘烨), Wang Xieqing(汪燮卿). Invention of radial moving bed reactor that is fit for oxygenate to propylene reaction[P]: CN, 200810120839.3. 2011-08-03
[9]	James G S. Petroleum Refining Processes[M]. New York: Marcel Dekker Inc., 2002
[10]	Robert A M. Handbook of Petroleum Refining Processes[M]. 2nd ed. New York: McGraw Hill, 1997
[11]	Xu Cheng'en(徐承恩). Catalytic Reforming Technology and Engineering (催化重整工艺与工程)[M]. Beijing: Chinese Petrochemical Press(中国石化出版社), 2006: 27
[12]	Lesthaeghe D, J Van D M, et al. Full theoretical cycle for both ethylene and propylene formation during methanol-to-olefin conversion in H-ZSM-5[J]. Chemcatchem., 2011, 3(1): 208-212
[13]	Li Chen(李晨), Li Jixia(李继霞), Li Jun(李俊). Industrial development and current situation of methanol to olefins[J]. Chemical Industry and Engineering Progress(化工进展), 2010, 29: 315-317
[14]	Wang Yao(王垚), Wei Fei(魏飞), Qian Zhen(钱震), et al. The technology and reactor design of fluidized catalytic cracking to produce propylene[P]: CN, 200610144290.2. 2009-10-21
[15]	Zhu Jie(朱杰), Cui Ning(崔宁), Chen Yuanjun(陈元君), et al. Progress of methanol to propylene[J]. CIESC Journal(化工学报), 2010, 61(7): 1674-1684
[16]	Yang Yongrong(阳永荣), Yan Lixia(严丽霞), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Technology to produce propylene[P]: CN, 201210424711.2. 2013-02-13
[17]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Technology that convert oxygenate to propylene[P]: CN, 200910100049.3. 2013-03-20
[18]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Invention of tube moving bed reactor that is fit for oxygenate to propylene reaction[P]: CN, 201010175837.1. 2013-05-08
[19]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Technology that convert methanol to propylene[P]: CN, 201010172218.7. 2012-11-14
[20]	Jiang Kun(姜坤). Study on two-stage process for conversion of methanol to propylene[D]. Hangzhou: Zhejiang University, 2013
[21]	Haw J F, Song W G, Marcus D M, et al. Mechanism of methanol to hydrocarbon catalysis[J]. Accounts of Chemical Research, 2003, 36: 317-326
[22]	Michael S. Methanol-to-hydrocarbons: catalytic materials and their behavior[J]. Microporous and Mesoporous Materials, 1999, 29: 3-18
[23]	Frerich J K. Methanol-to-hydrocarbons: process technology[J]. Microporous and Mesoporous Materials, 1999, 29: 49-66
[24]	Kalnes T N, Wei D H, lover B K. Conversion of an alcoholic oxygenate to propylene using moving bed and an etherification step[P]: CN, 200580031355.6. 2011-05-11
[25]	Yang Yongrong(阳永荣), Tong Guohong(童国红), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Conversion of methanol to propylene with multi-stage moving bed reactor system[P]: CN, 201110100711.2. 2011-11-16
[26]	Yang Yongrong(阳永荣), Yu Xianbo(虞贤波), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Temperature controlling technology in multi-stage moving bed reactor[P]: CN, 201110100583.1. 2011-12-14
[27]	Yu Xianbo(虞贤波). A study on moving bed methanol to propylene reaction process[D]. Hangzhou: Zhejiang University, 2012
[28]	Tang Yueqi(唐玥祺). Research on the hydrodynamics of moving-bed reactor for methanol to propene[D]. Hangzhou: Zhejiang University, 2012
[29]	Yang Yongrong(阳永荣), Yan Lixia(严丽霞), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Technology to produce propylene with low energy consumption[P]: CN, 201310251451.8. 2013
[30]	Yang Yongrong(阳永荣), Yan Lixia(严丽霞), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Process that convert methanol to propylene using moving bed technology[P]: CN, 201210437364.7. 2013-02-27
[31]	Yang Yongrong(阳永荣), Yan Lixia(严丽霞), Wang Jingdai(王靖岱), Wang Xieqing(汪燮卿). Semi-continuous process that convert methanol to propylene using moving bed technology[P]: CN, 201110208634.2. 2012-02-08