Evaluation of the Thermal Effect of Arc Plasma in the Plasma-Driven Partial Oxidation of Octane

Evaluation of the Thermal Effect of Arc Plasma in the Plasma-Driven Partial Oxidation of Octane

The on-board reforming technique for de-NOx is attracting increasing interest because of the fast start-up and size of the device. However, due to the limited amount of energy available from the battery, a full understanding of the characteristics of the plasma reforming reaction is important to opt...

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Bibliographic Details
Published in:Plasma chemistry and plasma processing Vol. 40; no. 2; pp. 483 - 497
Main Authors: Dinh, Duy Khoe, Lee, Dae Hoon, Iqbal, Muzammil, Kang, Hongjae, Choi, Seongil, Jung, Chan Mi, Song, Young-Hoon, Jo, Sungkwon, Kim, Kwan-Tae
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2020
Springer Nature B.V
Subjects:
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Classical Mechanics
Electric power
Energy conversion efficiency
Energy efficiency
Gas temperature
Hydrogen production
Inorganic Chemistry
Mechanical Engineering
Octane
Optimization
Original Paper
Oxidation
Plasma
Power consumption
Power efficiency
Power management
Reforming
Rotating plasmas
Synthesis gas
Temperature effects
Thermal environments
Plasma reformer
Reaction heat
Gasoline reforming
Rotating arc
Thermal activation
Plasma chemistry
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Summary:The on-board reforming technique for de-NOx is attracting increasing interest because of the fast start-up and size of the device. However, due to the limited amount of energy available from the battery, a full understanding of the characteristics of the plasma reforming reaction is important to optimise this technology to achieve hydrogen production with minimal power consumption. This paper reports the relative role of the thermal effect of plasma in octane oxidation induced by rotating arc plasma. The thermal effect or gas temperature increased with increased electric power; the conversion of the electric energy to heat was estimated to be higher than 40%. The increased thermal effect was the main consequence of further increasing the plasma power, which controlled the syngas yield and was the main determinant of the energy efficiency of the reaction. In comparison, although the O 2 /C ratio was the main parameter determining the thermal environment in the reactor, it had only a small influence on the energy efficiency of the reaction. The optimal O 2 /C ratio for maximum energy efficiency depends on the electric power (e.g. the optimal O 2 /C was 0.8 at 80 W and 0.5 at 280 W). The results provide guidance for determining the optimal conditions for plasma-driven reforming processes.
ISSN:0272-4324
1572-8986
DOI:10.1007/s11090-019-10054-1