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Citation: LIU Mei-jia, WANG Gang, ZHANG Zhong-dong, TIAN Ai-zhen. Study on hydrogen transfer reaction in C5 hydrocarbons catalytic pyrolysis[J]. Journal of Fuel Chemistry and Technology, ;2021, 49(1): 104-112. doi: 10.19906/j.cnki.JFCT.2021006 shu

Study on hydrogen transfer reaction in C5 hydrocarbons catalytic pyrolysis

  • 1.

    State Key Laboratory of Heavy Oil, China University of Petroleum (Beijing), Beijing 102249, China

  • 2.

    Petrochemical Research Institute, PetroChina, Beijing 102206, China

  • 3.

    Petrochina Petrochemical Research Institute Lanzhou Petrochemical Research Center, Lanzhou 730060, China

  • Corresponding author: WANG Gang, wanggang@cup.edu.cn ZHANG Zhong-dong, zhangzhongdong@petrochina.com.cn
  • Received Date: 31 August 2020
    Revised Date: 30 September 2020

    Fund Project: The project was supported by Technology Development Project of China National Petroleum Corporation-Research and Development of Upgrading Technology for the Transformation of Oil Refining to Chemical Industry (2019A-1809) and Development and Application of Flexible Catal Cracking Gasoline Olefins Conversion (CCOC) (KYWX-19-019)

Figures(7)

  • The cracking reaction mechanism of C5 hydrocarbons(n-pentane, 1-pentene) was analyzed. It is found that according to the ideal carbanion reaction mechanism and free radicals reaction mechanism, the molar selectivity of the cracking of n-pentane and 1-pentene to lower olefins (C2H4+C3H6+C4H8) is 50% and 100%, respectively. However, using MFI-30 zeolite, the molar selectivity of catalytic cracking of n-pentane and 1-pentene to light olefins at 650 ℃ is 23.41% and 56.79%, respectively, suggesting that 26.59% and 43.21% of light olefins have undergone hydrogen transfer reactions. The effects of different zeolites and key reaction temperature on the hydrogen transfer reaction during the catalytic pyrolysis of C5 hydrocarbons were further investigated. The results show that the zeolite with small pore structure and low acid density and higher reaction temperature can inhibit the hydrogen transfer reaction to varying degrees, thereby increasing the selectivity of light olefins. At 650 ℃, as the zeolite changes from the FAU with a large pore structure and high acid content to the MFI-120 with a small pore structure and low acid content, the hydrogen transfer coefficient HTC of the catalytic pyrolysis of n-pentane and 1-pentene is reduced by 96.86% and 50.58%, respectively, and the coke selectivity is reduced from 11.91% and 20.77% to 0.75% and 0.89%, respectively. However, the selectivity of the lower olefins increases from 14.25% and 25.14% to 46.28% and 62.58%, respectively.
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    1. [1]

      LIU Z Y, ZHANG Z D, YANG C H, GAO X H. Domestic technology developments on high-efficiency heavy oil conversion FCC catalysts’ industrialization[J]. Appl Petrochem Res,2015,5(4):269−275.  doi: 10.1007/s13203-015-0133-y

    2. [2]

      WANG Gang, SUN Jing, FANG Dong, XIAO Jun, NAN Jie, GAO Jin-sen. Molecular-refining oriented strategy of catalytic cracking for processing heavy oil[J]. Sci Sin Chim,2018,48(4):362−368.  doi: 10.1360/N032017-00169

    3. [3]

      LI C Y, YANG C H, SHAN H H. Maximizing propylene yield by two-stage riser catalytic cracking of heavy oil[J]. Ind Eng Chem Res,2007,46(14):4914−4920.  doi: 10.1021/ie061420l

    4. [4]

      ZAMOSTNY P, BELOHLAV Z, STARKBAUMOVA L, PATERA J. Experimental study of hydrocarbon structure effects on the composition of its pyrolysis products[J]. J Anal Appl Pyrolysis,2010,87(2):207−216.

    5. [5]

      WANG Wei-ran, ZHANG Wen-bin, WANG Gang, LAN Xing-ying, XU Chun-ming, GAO Jin-sen. Research on the main influencing factors in the process of FCC gasoline secondary cracking to increase propylene production[J]. J Fuel Chem Technol,2009,31(1):67−72.

    6. [6]

      XU You-hao, CUI Shou-ye, WANG Xie-qing. Study on the bimolecular cracking reaction of FCC gasoline olefins and its ratio to bimolecular hydrogen transfer reaction[J]. Pet Process Petrochem,2007,38(9):1−5.  doi: 10.3969/j.issn.1005-2399.2007.09.001

    7. [7]

      POTAPENKO O V, DORONIN V P, SOROKINA T P, KROL O V, LIKHOLOBOVET V A. A study of intermolecular hydrogen transfer from naphthenes to 1-hexene over zeolite catalysts[J]. Appl Catal A: Gen, 2016, 516, 153-159.

    8. [8]

      BORTNOVSKY O, SAZAMA P, WICHTERLOVA B. Cracking of pentenes to C2-C4 light olefins over zeolites and zeotypes[J]. Appl Catal A: Gen,2005,287(2):203−213.  doi: 10.1016/j.apcata.2005.03.037

    9. [9]

      HOU X, QIU Y, ZHANG X W, LIU G Z. Analysis of reaction pathways forn-pentane cracking over zeolites to produce light olefins[J]. Chem Eng J,2016,307(1):372−381.

    10. [10]

      THIVASASITH A, MAIHOM T, PENGPANICH S, WATTANAKIT C. Nanocavity effects of various zeolite frameworks on n-pentane cracking to light olefins: Combination studies of DFT calculations and experiments[J]. Phys Chem Chem Phys,2019,21(40):22215−22223.  doi: 10.1039/C9CP03871J

    11. [11]

      KUBO K, LIDA H, NAMBA S, LGARASHI A. Selective formation of light olefin by n-heptane cracking over HZSM-5 at high temperatures[J]. Microporous Mesoporous Mater,2012,149(1):126−133.  doi: 10.1016/j.micromeso.2011.08.021

    12. [12]

      TREACY M M J, FOSTER M D. Packing sticky hard spheres into rigid zeolite frameworks[J]. Microporous Mesoporous Mater,2009,118(1/3):106−114.  doi: 10.1016/j.micromeso.2008.08.039

    13. [13]

      HOU X, NI N, WANG Y, ZHU W J, QIU Y, DIAO Z H, LIU G Z, ZHANG X W. Roles of the free radical and carbenium ion mechanisms in pentane cracking to produce light olefins[J]. J Anal Appl Pyrolysis,2019,138:270−280.

    14. [14]

      ZHANG R, WANG Z X, LIU H Y, LIU Z C, LIU G L, MENG X H. Thermodynamic equilibrium distribution of light olefins in catalytic pyrolysis[J]. Appl Catal A: Gen,2016,522:165−171.  doi: 10.1016/j.apcata.2016.05.009

    15. [15]

      HAAG W, DESSAU R. Duality of mechanism for acid-catalyzed paraffin cracking[C]// Proceedings of the 8th International Congress on Catalysis, 1984.

    16. [16]

      CORMA A, MONTON J B, ORCHILLES A V. Cracking of n-heptane on a HZSM-5 zeolite. The influence of acidity and pore structure[J]. Appl Catal,1985,16(1):59–74.

    17. [17]

      ZHANG Y, ZHAO R X, SANCHEZSANCHEZ M, HALLER G L, HU J Z, BERMEJODEVAL R, LIU Y, LERCHER J A. Promotion of protolytic pentane conversion on H-MFI zeolite by proximity of extra-framework aluminum oxide and Brønsted acid sites[J]. J Catal,2019,370:424−433.  doi: 10.1016/j.jcat.2019.01.006

    18. [18]

      LUO Yu-ran. "Chemical Bond Energy Data Handbook"[J]. Scientia,2005,50(8):759−759.  doi: 10.3321/j.issn:0023-074X.2005.08.021

    19. [19]

      HUANG X, AIHEMAITIJIANG D, XIAO W D. Reaction pathway and kinetics of C3–C7 olefin transformation over high-silicon HZSM-5 zeolite at 400–490 °C[J]. Chem Eng J,2015,280(15):222−232.

    20. [20]

      CNUDDE P, DE WISPELAERE K, VAN D M J, WAROQUIER M, SPEYBROECK V V. Effect of temperature and branching on the nature and stability of alkene cracking intermediates in H-ZSM-5[J]. J Catal,2017,345:53−69.  doi: 10.1016/j.jcat.2016.11.010

    21. [21]

      ZHU Hua-yuan, HE Ming-yuan, ZHANG Xin, SONG Jia-qing. Hydrogen transfer reaction of n-hexane on several different molecular sieves[J]. Pet Process Petrochem,2001,(9):39−42.  doi: 10.3969/j.issn.1005-2399.2001.09.011

    22. [22]

      XU You-hao. Discussion on the role of hydrogen transfer reaction in olefin conversion[J]. Pet Process Petrochem,2002,(1):38−41.  doi: 10.3969/j.issn.1005-2399.2002.01.009

    23. [23]

      ZHU Xiang-xue, SONG Yue-qin, LI Hong-bing, LIU Sheng-lin, SUN Xin-de, XU Long-ya. Thermodynamic study on the catalytic cracking of butene to propylene/ethylene[J]. Chin J Catal,2005,26(2):22−28.

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