Effect of the Calorific Intensity of Combustion Chamber on Production of Synthesis Gas in Partial Oxidation of Methane–Oxygen Mixtures in the Combustion Mode

Effect of the Calorific Intensity of Combustion Chamber on Production of Synthesis Gas in Partial Oxidation of Methane–Oxygen Mixtures in the Combustion Mode

Optimal design of a flow-through chemical reactor with increased calorific intensity was experimentally sought for in partial oxidation of natural gas by oxygen at oxidant excess factors in the range 0.27 < α < 0.4. It was shown that this reactor with a chamber for additional turbulent mixing...

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Veröffentlicht in:Russian journal of applied chemistry 2018-10, Vol.91 (10), p.1588-1596
Hauptverfasser: Buravtsev, N. N., Kolbanovskii, Yu. A., Rossikhin, I. V., Bilera, I. V.
Format: Artikel
Sprache:eng
Schlagworte:
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Combustion chambers
Fluid dynamics
Industrial Chemistry/Chemical Engineering
Natural gas
Organic chemistry
Oxidation
Physicochemical Studies of Systems and Processes
Plug flow chemical reactors
Reagents
Supercritical pressures
Synthesis gas
Turbulent mixing
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Zusammenfassung:Optimal design of a flow-through chemical reactor with increased calorific intensity was experimentally sought for in partial oxidation of natural gas by oxygen at oxidant excess factors in the range 0.27 < α < 0.4. It was shown that this reactor with a chamber for additional turbulent mixing of the starting components, turbulizer, and supercritical pressure difference at the outlet from the combustion chamber can provide a combustion mode close to the process in the plug-flow reactor. The increase in the calorific intensity of the combustion chamber of the reactor as a result of a decrease in its volume leads to full conversion of the starting reagents and to lower carbon-black formation.
ISSN:1070-4272
1608-3296
DOI:10.1134/S107042721810004X