The possibility, in principle, of high-temperature three-phase Fischer-Tropsch synthesis, which is implemented in the presence of iron-containing catalytic dispersions in a bubble column reactor, is demonstrated. The catalytic system is activated in situ in a CO stream. It is proved that the particle size of the iron-containing dispersion used as the catalyst for this process depends on the precursor solution injection technique and in no case does it exceed 50 nm. It is shown that the described three-phase high-temperature Fischer-Tropsch synthesis method makes it possible to achieve high process parameters, such as target products yield up to 138 g/m3 with 90% selectivity of products formation. The properties of the developed catalyst enable it to perform for a prolonged period with high conversions without impairment of process selectivity.
Similar content being viewed by others
References
D. A. Wood, C. Nwaoh, and B. F. Towler, J. Nat. Gas Sci. Eng., 9,196-208 (2012).
A. Galadima and O. Muraza, J Nat. Gas Sci. Eng., 25, 303-316 (2015).
D. A. Wood, J. Nat. Gas Sci. Eng., 26, 772-779 (2015).
Z. W. Tao, H. J. Li, J. W. Jianguang, et al., Fuel, 186, 587-596 (2016).
S. N. Khadzhiev and L. A. Vytnova, Neftekhim., 48, No. 2, 133-148 (2008).
A. N. Stranges, Studies in Surf. Sci. Catal., 163, 1-27 (2007).
M. E. Dry, Catal. Today, 71, 227-241 (2002).
H. Schulz, Appl. Catal. A: General, 186, 3-12 (1999).
B. Jager and R. Espinoza, Catal. Today, 23, 17-28 (1995).
A. de Klerk, Green Chem., 10, 1249-1279 (2008).
H. Mahmoudi, M. Mahmoudi, O. Doustdar, et al., Biofitels Eng., 2, No. 1, 11-31 (2017).
C. Boyer, J. Gazarian, V. Lecocq, et al. Oil & Gas Sci. Technol. Rev. IFP Energies nouvelles, 71, No. 44, 1-19 (2016).
S. N. Khadzhiev, A. Yu. Krylova, M. V. Kulikova, et al., Petrol. Chem., 53, No. 3, 152-156 (2013).
M. V. Kulikova, M. V. Chudakova, O. S. Dement’eva, et al., Petrol. Chem., 56, No. 6, 535-539 (2016).
S. N. Khadzhiev, Petrol. Chem., 56, No. 6, 465-479 (2016).
M. V. Kulikova, O. S. Dement'eva, M. V. Chudakova, et al., Izv. Vuzov, Khim. Khim Tekhnol., 61, No. 9-10, 73-78 (2018).
M. V. Kulikova, O. S. Dement’eva, and M. Yu. Gorshkova, Petrol. Chem., 58, No. 10, 855-862 (2018).
M. V. Kulikova and S. N. Khadzhiev, Neftekhim., 57, No. 6, 796-799 (2017).
M. V. Kulikova, A. Kh. Al Khazaradzhi, O. S. Dement’eva, et al., Neftekhim., 55, No. 5, 391-395 (2015).
M. V. Kulikova, Catal. Today, 2019 (in press).
M. V. Kulikova, A. E. Kuz'min, and O. B. Chupichev, Zh. Prikl. Khim., 91, No. 4, 528-532 (2018).
This work was carried out with the financial support of the Ministry of Science and Education of the Russian Federation (Agreement No. 14.607.21.0168, unique applied research identifier RFMEFI60717X0168). In this work, we used equipment of the center of collective use “New Petrochemical Processes, Polymer Composites, and Adhesives.”
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Khimiya i Tekhnologiya Topliv i Masel, No. 6, pp. 6 — 11, November—December, 2019.
Rights and permissions
About this article
Cite this article
Kulikova, M.V., Chudakova, M.V. & Dement’eva, O.S. Effect of Operating Conditions of High-Temperature Three-Phase Fischer-Tropsh Synthesis Pilot Plant on Key Process Parameters. Chem Technol Fuels Oils 55, 666–674 (2020). https://doi.org/10.1007/s10553-020-01080-3
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10553-020-01080-3