Abstract
Economically and ecologically, the thermal decomposition of methane is a promising process for large scale hydrogen production. In this experimental study, the non-catalytic decomposition of methane in the presence of small amounts of carbon dioxide was analyzed. At large scales, natural gas or biomethane are possible feedstocks for the thermal decomposition and can obtain up to 5% carbon dioxide. Gas recycling can increase the amount of secondary components even further. Experiments were conducted in a packed flow reactor at temperatures from 1250 to 1350 K. The residence time and the amounts of carbon dioxide and hydrogen in the feed were varied. A methane conversion of up to 55.4% and a carbon dioxide conversion of up to 44.1% were observed. At 1300 K the hydrogen yield was 95% for a feed of methane diluted in nitrogen. If carbon dioxide was added to the feed at up to a tenth with regard to the amount of supplied methane, the hydrogen yield was reduced to 85%. Hydrogen in the feed decreases the reaction rate of the methane decomposition and increases the carbon dioxide conversion.
Highlights
Today, approximately 96% of hydrogen is produced by methane steam reforming, oil/naphtha reforming and coal gasification [1]
The hydrogen yield was 95% for a feed of methane diluted in nitrogen
If carbon dioxide was added to the feed at up to a tenth with regard to the amount of supplied methane, the hydrogen yield was reduced to 85%
Summary
Approximately 96% of hydrogen is produced by methane steam reforming, oil/naphtha reforming and coal gasification [1]. All of these processes result in a significant amount of CO2 emission. Electrochemical water splitting (water electrolysis) in combination with renewably produced electricity is under consideration for hydrogen production [4]. From economic and ecological perspectives the thermal decomposition of methane (TDM) could be an interesting alternative for largescale hydrogen production [6,7,8]. Methane is dissociated to solid carbon and hydrogen: CH4
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