2D and 3D CFD modelling of a reactive turbulent flow in a double shell supercritical water oxidation reactor

[Display omitted] ► CFD modelling of a double shell supercritical water oxidation reactor. ► 2D and 3D modelling of the turbulent flow fields. ► Comparison between the moving reference frame model and the sliding mesh model. ► Use of a EDC combustion model for the oxidation reaction. ► Validation by...

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Veröffentlicht in:The Journal of supercritical fluids 2012-05, Vol.65, p.25-31
Hauptverfasser: Moussiere, S., Roubaud, A., Boutin, O., Guichardon, P., Fournel, B., Joussot-Dubien, C.
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Sprache:eng
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Zusammenfassung:[Display omitted] ► CFD modelling of a double shell supercritical water oxidation reactor. ► 2D and 3D modelling of the turbulent flow fields. ► Comparison between the moving reference frame model and the sliding mesh model. ► Use of a EDC combustion model for the oxidation reaction. ► Validation by comparison with experimental temperature measurement. In order to design and define appropriate dimensions for a supercritical oxidation reactor, a comparative 2D and 3D simulation of the fluid dynamics and heat transfer during an oxidation process has been performed. The solver used is a commercial code, Fluent 6.2®. The turbulent flow field in the reactor, created by the stirrer, is taken into account with a k–ω model and a swirl imposed to the fluid. In the 3D case the rotation of the stirrer can be modelled using the sliding mesh model and the moving reference frame model. This work allows comparing 2D and 3D velocity and heat transfer calculations. The predicted values (mainly species concentrations and temperature profiles) are of the same order in both cases. The reactivity of the system is taken into account with a classical Eddy Dissipation Concept combustion model. Comparisons with experimental temperature measurements validate the ability of the CFD modelling to simulate the supercritical water oxidation reactive medium. Results indicate that the flow can be considered as plug flow-like and that heat transfer is strongly enhanced by the stirring.
ISSN:0896-8446
1872-8162
DOI:10.1016/j.supflu.2012.02.019