A two-phase model of shale pyrolysis

•A two-phase and two-temperature mathematical model of oil shale thermal decomposition is proposed.•In the process of thermal decomposition of shale, a significant role is played by the phenomena of interphase transfer.•A transition of the process to an thermal explosive mode is theoretically possib...

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Published in	Fuel (Guildford) Vol. 228; pp. 132 - 139
Main Authors	Knyazeva, A.G, Maslov, A.L., Martemyanov, S.M.
Format	Journal Article
Language	English
Published	Elsevier Ltd 15.09.2018
Subjects	Chemical kinetics Darcy’s law Electromagnetic heating Oil shale Thermal decomposition Electromagnetic heating Darcy’s law Oil shale Thermal decomposition Chemical kinetics
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Abstract	•A two-phase and two-temperature mathematical model of oil shale thermal decomposition is proposed.•In the process of thermal decomposition of shale, a significant role is played by the phenomena of interphase transfer.•A transition of the process to an thermal explosive mode is theoretically possible. There are various methods of oil shale thermal processing with the purpose to generate primary energy product – so-called shale gas. However, methods that do not require the extraction of rock to the surface (in-situ methods) are of special interest. In these methods, shale gas is extracted directly from the stratum as it is heating up, in one way or another. This paper presents a model of in-situ oil shale heating. In comparison to known papers, this model describes processes under “non-equilibrium” conditions. The model takes into account chemical reactions, the flow of the gaseous decomposition products of in pores, concentration expansion phenomenon and interphase heat and mass transfer. Examples of the numerical realization of two individual tasks are provided. The problems on the reaction initiation in shale plate by heat flux from surface and plane shale layer decomposition under electric heating were examined. It was shown that chemical heat release essentially changes the summary heat balance in the system. The work unveiled several ways of reaction development, including explosion and slow decomposition.
AbstractList	•A two-phase and two-temperature mathematical model of oil shale thermal decomposition is proposed.•In the process of thermal decomposition of shale, a significant role is played by the phenomena of interphase transfer.•A transition of the process to an thermal explosive mode is theoretically possible. There are various methods of oil shale thermal processing with the purpose to generate primary energy product – so-called shale gas. However, methods that do not require the extraction of rock to the surface (in-situ methods) are of special interest. In these methods, shale gas is extracted directly from the stratum as it is heating up, in one way or another. This paper presents a model of in-situ oil shale heating. In comparison to known papers, this model describes processes under “non-equilibrium” conditions. The model takes into account chemical reactions, the flow of the gaseous decomposition products of in pores, concentration expansion phenomenon and interphase heat and mass transfer. Examples of the numerical realization of two individual tasks are provided. The problems on the reaction initiation in shale plate by heat flux from surface and plane shale layer decomposition under electric heating were examined. It was shown that chemical heat release essentially changes the summary heat balance in the system. The work unveiled several ways of reaction development, including explosion and slow decomposition.
Author	Maslov, A.L. Martemyanov, S.M. Knyazeva, A.G
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Cites_doi	10.1007/s10973-013-3524-2 10.1016/0016-2361(87)90153-0 10.1016/S0016-2361(98)00131-8 10.1016/0016-2361(90)90320-P 10.1016/0016-2361(89)90318-9 10.1088/1742-6596/552/1/012012 10.1021/bk-2010-1032.ch010 10.1016/0016-2361(87)90055-X 10.2118/118958-PA 10.1021/ef00034a017 10.1016/0016-2361(83)90064-9 10.1016/j.marpetgeo.2016.06.001 10.1007/BF02369861 10.1021/ef00025a034 10.1016/j.fuel.2009.06.036
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Keywords	Electromagnetic heating Darcy’s law Oil shale Thermal decomposition Chemical kinetics
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