Structural and compositional evolution of coal tar toluene insoluble during slurry-phase hydrocracking

•This study investigates the impact of hydrocracking on the structure and composition of coal tar toluene insoluble.•The concentrations of toluene insoluble initially decreased and then increased as the increase of reaction temperature.•The decrease involved decomposition along with the removal of h...

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Bibliographic Details
Published in:Fuel (Guildford) 2017-09, Vol.203, p.352-359
Main Authors: Du, Juntao, Deng, Wenan, Li, Jinlu, Li, Chuan, Du, Feng, Zhang, Zailong, Yang, Tengfei, Sun, Qiang, Cao, Xiangpeng
Format: Article
Language:English
Subjects:
Aromatic compounds
Biological evolution
Catalysts
Coal tar
Coal tar toluene insoluble
Coke
Coke formation
Composition
Evolution
Heteroatoms groups
High temperature
Hydrocracking
Low temperature
Mesophase
Oil
Oxygen
Oxygen compounds
Slurries
Slurry-phase hydrocracking
Structure
Studies
Tar
Thermal decomposition
Toluene
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Summary:•This study investigates the impact of hydrocracking on the structure and composition of coal tar toluene insoluble.•The concentrations of toluene insoluble initially decreased and then increased as the increase of reaction temperature.•The decrease involved decomposition along with the removal of heteroatoms groups at low temperatures.•The increase was induced by coke formation via the stacking of rich-oxygen compounds at high temperatures.•The Fe1−xS was formed by self-sulfurized from inorganic matters and was studied. Toluene insoluble (TI) is an important heavy components of coal tar. It significantly affects on residues upgrading and coke formation during slurry-phase hydrocracking. The structural and compositional evolution of TI were investigate in hydrocracking experiments with oil-soluble catalysts. Experiment results showed that the concentrations of TI after hydrocracked initially decreased and then increased as the increase of reaction temperature. And TI consisted organic aromatic compounds and inorganic species. At low temperatures, the TI evolution involved the thermal decomposition along with the elimination of heteroatoms groups. The Fe1−xS was formed by self-sulfurized from inorganic matters and was studied. At relatively high temperatures, the TI evolution included both mesophase and coke formation through the aromatic sheet stacking of rich-oxygen compounds. On the basis of experimental studies, the pathway of the TI evolution was proposed for slurry-phase hydrocracking.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2017.04.139