Methane Pyrolysis for Hydrogen Production: Specific Features of Using Molten Metals

Published data on noncatalytic pyrolysis of natural gas in molten metals are analyzed. The most illustrative results obtained in the past two decades are described. The use of molten metals as reaction medium allows solving the problem of coking of pyrolysis reactors owing to the flotation of the ca...

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Published in:Russian journal of applied chemistry 2020-05, Vol.93 (5), p.625-632
Main Authors: Parfenov, V. E., Nikitchenko, N. V., Pimenov, A. A., Kuz’min, A. E., Kulikova, M. V., Chupichev, O. B., Maksimov, A. L.
Format: Article
Language:English
Subjects:
Bubbling
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Coking
Conversion
Flotation
High temperature
Hydrogen production
Industrial Chemistry/Chemical Engineering
Liquid metals
Metal surfaces
Metals
Natural gas
Pyrolysis
Reactors
Reviews
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cited_by cdi_FETCH-LOGICAL-c353t-6f83aec42beb473f73dca2a4e7ca71d70123654ab55a33bc7452dfdcce674fd03
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container_end_page 632
container_issue 5
container_start_page 625
container_title Russian journal of applied chemistry
container_volume 93
creator Parfenov, V. E.
Nikitchenko, N. V.
Pimenov, A. A.
Kuz’min, A. E.
Kulikova, M. V.
Chupichev, O. B.
Maksimov, A. L.
description Published data on noncatalytic pyrolysis of natural gas in molten metals are analyzed. The most illustrative results obtained in the past two decades are described. The use of molten metals as reaction medium allows solving the problem of coking of pyrolysis reactors owing to the flotation of the carbon formed to the molten metal surface. The use of liquid metal bubbling reactors allowing the process to be performed at temperatures of up to 1200°С is considered. The maximal conversion was 78% at 1175°С and feeding rate of 50 mL min –1 . The major factors favoring more complete conversion of natural gas in the processes under consideration are elevated temperature, decreased gas bubble size due to the use of bubbling systems of various types, and longer residence time of the gas in the heat carrier due to an increase in the reactor length or to use of various types of packing.
doi_str_mv 10.1134/S1070427220050018
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subjects Bubbling
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Coking
Conversion
Flotation
High temperature
Hydrogen production
Industrial Chemistry/Chemical Engineering
Liquid metals
Metal surfaces
Metals
Natural gas
Pyrolysis
Reactors
Reviews
title Methane Pyrolysis for Hydrogen Production: Specific Features of Using Molten Metals
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