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High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes
SJR: 0.137 SNIP: 0.341 CiteScore™: 0.43

ISSN Imprimir: 1093-3611
ISSN On-line: 1940-4360

High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes

DOI: 10.1615/HighTempMatProc.v13.i2.120
pages 241-246

ESTIMATION OF PERSPECTIVITY OF STEAM-PLASMA METHANE CONVERSION

A. N. Bratsev
Institute for Electrophysics and Electric Power RAS (IEE RAS), Russia, 191186, Saint-Petersburg, Dvortsovaya nab., 18
V. A. Kuznetsov
Institute for Electrophysics and Electric Power RAS (IEE RAS), Dvortsovaya nab., 18, 191186, St.-Petersburg, Russia
V. E. Popov
Institute for Electrophysics and Electric Power RAS (IEE RAS), Russia, 191186, Saint-Petersburg, Dvortsovaya nab., 18
A. A. Ufimtsev
Institute of Problems of Electrophysics of the Russian Academy of Sciences, Dvortsovaya nab. 18, St.-Petersburg, Russia
S. V. Shtengel
Institute for Electrophysics and Electric Power RAS (IEE RAS), Russia, 191186, Saint-Petersburg, Dvortsovaya nab., 18

RESUMO

The work is dedicated to determination of the main time and power characteristics of the process of methane steam-plasma conversion and weight-dimension parameters in a cylindrical reactor with application of the plasma generator of alternating current. Characteristics of steam-plasma conversion process are calculated in kinetic approximation. The synthesis-gas has a high temperature (1400-1800 K) and calorific value of (∼30 MJ/kg) at the reactor outlet. The process has high power efficiency (90%), productivity (1.0-1.5 MW/m3) and methane utilization quotient (70-99%). The parameters of steam-plasma and steam catalytic conversion of methane are compared.

Referências

  1. Ponomarev-Stepnoi N.N. and Stolyarevsky A.Ya., Absorption of hydrogen by the carbonic nanostructures.

  2. Rutberg Ph.G.., Bratsev A.N., and Ufimtsev A.A., Plasmochemical technologies for processing of hydrocarbonic raw material with syngas production.

  3. Bratsev A.N. , Popov V.E., Rutberg A.F., and Shtengel S.V., The installation for plasma gasification of different types of waste.

  4. Kustshev S.A., Nakonechny G.V., Ovchinnikov R.B., Popov V.E., Popov S.D., Serba E.O. et al, The Characteristic Features of Operation of The High Voltage Plasma Generator of Alternating Current in the Experimental Plant of Plasma High-Temperature Gasification of Solid Organic.

  5. Piel A and Platiau D, Etude des technologies de thermolyse des dechets menagers.

  6. Carter G.W. and Tsangaris A.V., Plasma gasification of biomedical waste.

  7. Van Den Oostercamp P, Vagner E, and Ross J, Achievements in synthesis-gas production.

  8. Goulding PS, Jones SL, and Judd R, Development of the BG Compact for Application in Fuel Cell Systems.

  9. Slovetsky D.I., Plasmachemical Processes for Production of Pure Hydrogen.

  10. Deminsky M, Jivotov V, Potapkin B, Rusanov V, Plasma-assisted production of hydrogen from hydrocarbons.