Effect of Hydroconversion Conditions on the Composition and Properties of an Ultrafine Mo-Containing Catalyst Formed in situ View Full Text


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Article Info

DATE

2020-10-08

AUTHORS

Kh. M. Kadiev, L. A. Zekel’, M. Kh. Kadieva, A. M. Gyul’maliev, A. E. Batov, M. Ya. Visaliev, A. U. Dandaev, E. E. Magomadov, N. A. Kubrin

ABSTRACT

The regularities of formation of suspensions of dispersed molybdenum-containing catalyst nanosized particles synthesized in situ in heavy petrochemical feedstock with various compositions are studied depending on hydroconversion conditions. Ammonium heptamolybdate is used as a precursor. The following parameters are varied in the experiments: the precursor catalyst concentration, within 0–1% molybdenum; feedstock composition, both group and fractional composition; sulfur concentration in the feedstock, in the range of 0.87–3.39%; and temperature, in the range of 420–450°C. It is found that the fraction of molybdenum sulfide in the composition of the catalyst grows and the concentration of coke in the hydroconversion residue insoluble in toluene decreases with increasing partial pressure of hydrogen sulfide in the reaction gas. Molybdenum compounds in the catalyst slightly affect the conversion of the fraction >500°C but substantially decrease the yield of condensation products. The rate constants and activation energy of the desulfurization reaction of vacuum residue in the presence of the dispersed catalyst are calculated. More... »

PAGES

1154-1163

Identifiers

URI

http://scigraph.springernature.com/pub.10.1134/s0965544120100059

DOI

http://dx.doi.org/10.1134/s0965544120100059

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1131540848


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