Oligomerization of pent-1-ene over zeolite catalysts

Oligomerization of pent-1-ene is an effective process for synthesis of high-quality environmentally friendly fuel components. Catalytic properties of H-zeolites FAU, OFF, MOR, ВЕА, MTW and MFI were studied for synthesis of pentene oligomers in an autoclave at 110–200 °C. The wide-pore structure of H-Y and H-Beta (18) zeolites and the high concentration of acid sites were established to cause the high oligomerization activity to obtain 97–100 % yields of oligomers. Oligomers obtained over these catalysts comprised, depending on the reaction conditions, 30–73 % dimers, 25–50 % trimers and 2–14 % oligomers with more than three monomer units (n > 3). Fine-pore zeolites (H-ZSM-5) and zeolites with one-dimensional channel systems (H-OFF, H-MOR, H-ZSM-12) were less active to oligomerization of pent-1-ene, decenes being the main reaction products.

1. Ipatieff V.N. // Industrial and Engineering Chemistry. 1935. V. 27. № 9. P. 1067-1069.

2. Davis M.E. // AlChE Journal. 1991. V. 37. № 2. P. 310.

3. Kholer E., Schmidt F., Wernicke H.J., De Pontes M., Roberts H.L. Hydrocarbons Technol. Int, Summer 1995.

4. Düker A., Lichtscheidl J., Altwicker C. ERTC 14th Annual Meeting, Germany, Berlin, November 9-11 2009.

5. Cruz V.J., Izquierdo J.F., Cunill F., Tejero J., Iborra M., Fité C. // React. Funct. Polym. 2005. V. 65. P. 149-160.

6. Kulkarni A., Kumar A., Goldman A.S., Celik F.E. // Catal. Comm. 2016. V. 75. Р. 98-102.

7. US Patent 4335009, 1982.

8. Ceska J., Zilkova N., Nachtigall P. // Industrial Studies in Surface Science and Catalysis. 2005. V. 158. P. 1201-1212.

9. Casagrande M., Storaro L., Lenarda M., Rossini S. // Catal. Comm. 2005. V. 6. P. 568-572.

10. Shah N.F., Sharma M.M. // React. Funct. Polym. 1993. V. 19. P. 181-190.

11. Marchionna M., Girolamo M.D., Patrini R. // Catal. Today. 2001. V. 65. P. 397-403.

12. Cruz V.J., Bringué R., Cunill F., Izquierdo J.F., Tejero J., Iborra M., Fite C. // J. Catal. 2006. V. 238. № 2. P. 330-341.

13. Cruz V.J., Izquierdo J.F., Cunill F., Tejero J., Iborra M., Fité C., Bringué R. // React. Funct. Polym. 2007. V. 67. P. 210-224.

14. Catani R., Mandreoli M., Rossini S., Vaccari A. // Catal. Today. 2002. V. 75. P. 125-131.

15. Schmidt R., Welch R.B., Randolph B.B. // Energy and Fuels. 2008. V. 22. P. 1148-1155.

16. Höchtl M., Jentys A., Vinek H. // Appl. Catal. A. 2001. V. 207. P. 397-405.

17. Föttinger K., Kinger G., Vinek H. // Appl. Catal. A. 2003. V. 249. P. 205-212.

18. US Patent 9567267, 2017.

19. Granollers M., Izquierdo J.F., Tejero J., Iborra M., Fité C., Bringué R., Cunill F. // Ind. Eng. Chem. Res. 2010. V. 49. P. 3561-3570.

20. Corma A., Martinez C., Doskocil E. // J. Catal. 2013. V. 300. P. 183-196.

21. Bertrand-Drira C., Cheng X.-W., Cacciaguerra T., Trens P., Melinte G., Ersen O., Minoux D., Finiels A., Fajula F., Gerardin C. // Microporous Mesoporous Mater. 2015. V. 213. P. 142-149.

22. Díaz-Rey M.R., Paris C., Martínez-Franco R., Moliner M., Martínez C., Corma A. // ACS Catal. 2017. V. 7. P. 6170-6178.

23. Горшунова К.К., Травкина О.С., Кустов Л.М., Кутепов Б.И. // Журнал физической химии. 2016. Т. 90. № 3. С. 429—435.

24. Gorshunova K.K., Travkina O.S., Kapustin G.I., Kustov L.M., Pavlov M.L., Kutepov B.I. // Russian Journal of Physical Chemistry A. 2015. V. 89. № 5. P. 846-851.