含钴和含镍重质原油提质催化剂：乙醇对催化裂化产物组成和结构的影响

IF 0.7 Q4 ENGINEERING, CHEMICAL

Catalysis in Industry Pub Date : 2025-01-27 DOI:10.1134/S2070050424700314

Kh. Kh. Urazov, N. N. Sviridenko, N. S. Sergeev, A. S. Akimov, V. D. Ogorodnikov

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引用次数: 0

摘要

研究了重质原油在含镍和含钴催化剂存在下，由适当的盐与乙醇混合原位生成的热转化产物。在催化过程中，轻馏分产率从51 wt %提高到63%，焦炭产率从3 wt %降低到2 wt %。在混合Ni+Co催化剂的情况下，观察到气体（5 wt %）和焦炭（0.1 wt %）的最低产率。热裂化产物中硫含量的降低（17%）和催化裂化产物中硫含量的降低（12 - 32rel %）主要是由于硫以气态产物的形式被去除。研究了重质原油裂解前后平均沥青质分子的结构基团特征。通过x射线衍射分析，在固裂产物中发现了Ni0.96S、Ni9S8和Co9S8相。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Cobalt- and Nickel-Containing Catalysts for Heavy Crude Oil Upgrading: Effect of Ethanol on the Composition and Structure of Catalytic Cracking Products

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Cobalt- and Nickel-Containing Catalysts for Heavy Crude Oil Upgrading: Effect of Ethanol on the Composition and Structure of Catalytic Cracking Products

Products from the thermal conversion of heavy crude oil in the presence of Ni- and Co-containing catalysts formed in situ from a mixture of appropriate salts with ethanol have been studied. In the catalytic process, the light fraction yield increases from 51 to 63% and the coke yield decreases from 3 to 2 wt % compared with the respective parameters of thermal cracking. In the case of a mixed Ni+Co catalyst, the lowest yields of gas (5 wt %) and coke (0.1 wt %) are observed. The decrease in sulfur content in both the thermal cracking (by 17%) and catalytic cracking products (by 12–32 rel %) occurs primarily due to the removal of sulfur in the form of gaseous products. The structural group characteristics of average asphaltene molecules before and after heavy crude oil cracking have been studied. Using X-ray diffraction analysis, Ni_0.96S, Ni₉S₈, and Co₉S₈ phases have been identified in the solid cracking products.

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来源期刊

Catalysis in Industry ENGINEERING, CHEMICAL-

CiteScore

1.30

自引率

14.30%

发文量

期刊介绍： The journal covers the following topical areas: Analysis of specific industrial catalytic processes: Production and use of catalysts in branches of industry: chemical, petrochemical, oil-refining, pharmaceutical, organic synthesis, fuel-energetic industries, environment protection, biocatalysis; technology of industrial catalytic processes (generalization of practical experience, improvements, and modernization); technology of catalysts production, raw materials and equipment; control of catalysts quality; starting, reduction, passivation, discharge, storage of catalysts; catalytic reactors.Theoretical foundations of industrial catalysis and technologies: Research, studies, and concepts : search for and development of new catalysts and new types of supports, formation of active components, and mechanochemistry in catalysis; comprehensive studies of work-out catalysts and analysis of deactivation mechanisms; studies of the catalytic process at different scale levels (laboratory, pilot plant, industrial); kinetics of industrial and newly developed catalytic processes and development of kinetic models; nonlinear dynamics and nonlinear phenomena in catalysis: multiplicity of stationary states, stepwise changes in regimes, etc. Advances in catalysis: Catalysis and gas chemistry; catalysis and new energy technologies; biocatalysis; nanocatalysis; catalysis and new construction materials.History of the development of industrial catalysis.