Experimental study of kukersite oil shale pyrolysis by solid heat carrier

The investigation of oil shale pyrolysis in the experimental retorting system by solid heat carrier (silica sand) was conducted. Modeling of the heat and mass transfer processes in the retorting system was performed with use of simplified mathematical model. It was shown that the radiation heat exch...

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Bibliographic Details
Published in:Fuel processing technology 2017-04, Vol.158, p.123-129
Main Authors: Gerasimov, Gennady, Khaskhachikh, Vladimir, Potapov, Oleg
Format: Article
Language:English
Subjects:
Ashes
Decomposition kinetics
Heat and mass transfer
Heat exchange
Heat exchangers
Heat transfer
Mass transfer
Oil shale
Oil shale pyrolysis
Pyrolysis
Radiation
Rotary drum reactor
Shale oil yield
Silicon dioxide
Solid heat carrier
Volatile compounds
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Summary:The investigation of oil shale pyrolysis in the experimental retorting system by solid heat carrier (silica sand) was conducted. Modeling of the heat and mass transfer processes in the retorting system was performed with use of simplified mathematical model. It was shown that the radiation heat exchange plays the main role in the heat transfer between oil shale particles and solid heat carrier under the conditions of volatiles release. The maximum yield of the shale oil amounts to 73% at temperature of experiment of 560°C, which exceeds the data obtained in the Fisher assay on 20%. The conditions that lead to increase in maximum yield of shale oil in the industrial UTT units with the rotary drum reactor were ascertained. They are mainly associated with a decrease in the solid heat carrier (ash) temperature, which leads to the inhibition of secondary reactions between ash and the acidic compounds of the shale oil. •Oil shale pyrolysis by solid heat carrier was investigated experimentally.•The radiation heat exchange plays the main role in the heat transfer.•The maximum shale oil yield in experiments amounts to 73% from mass of kerogen.•The identification of conditions that lead to maximum yield of shale oil was realized.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2016.12.016