Ultrahigh-Temperature Continuous Reactors Based on Electrothermal Fluidized Bed Concept

Ultrahigh-Temperature Continuous Reactors Based on Electrothermal Fluidized Bed Concept

Authors introduce an ultrahigh-temperature (i.e., 2500–3000 °C) continuous fluidized bed furnace, in which the key operating variable is specific electrical resistance of the bed. A correlation has been established to predict the specific electrical resistance for the natural graphite-based precurso...

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Veröffentlicht in:Journal of fluids engineering 2016-04, Vol.138 (4)
Hauptverfasser: Fedorov, Sergiy S, Singh Rohatgi, Upendra, Barsukov, Igor V, Gubynskyi, Mykhailo V, Barsukov, Michelle G, Wells, Brian S, Livitan, Mykola V, Gogotsi, Oleksiy G
Format: Artikel
Sprache:eng
Schlagworte:
Chaos theory
Computational fluid dynamics
Electrical resistance
Fluidized beds
Markets
Mathematical models
Reactors
Resistivity
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Zusammenfassung:Authors introduce an ultrahigh-temperature (i.e., 2500–3000 °C) continuous fluidized bed furnace, in which the key operating variable is specific electrical resistance of the bed. A correlation has been established to predict the specific electrical resistance for the natural graphite-based precursors. Fluid dynamics models have been validated with the data from a fully functional prototype reactor. Data collected demonstrated that the difference between the calculated and measured values of specific resistance is approximately 25%; due to chaotic nature of electrothermal fluidized bed processes, this discrepancy was deemed acceptable. Optimizations proposed allow producing natural graphite-based end product with the purity level of 99.98 + wt. %C for battery markets.
ISSN:0098-2202
1528-901X
DOI:10.1115/1.4031689