Dynamic modelling of methanation reactors during start-up and regulation in intermittent power-to-gas applications

Power-to-gas is a pathway for the storage of intermittent renewable energy in a chemical form; energy surpluses can be exploited to produce hydrogen (via electrolysis) that can then react with carbon dioxide to produce synthetic methane by using catalytic cooled reactors. Methanation unit has been designed and optimized, defining the number of involved reactors, the number of parallel tubes for each reactor and the staged CO2 injection to moderate the maximum temperature throughout the reactors. The produced synthetic natural gas (SNG) must have a methane content at least equal to 95 mol.-%, achieved by involving a series of 3 cooled reactors. Dynamic behavior of the as-designed system has been investigated for two cases that can occur when a power-to-gas system is operated intermittently: start-up from reactor hot standby and system operated at partial load. Methanation system requires about 130 s to reach the targeted methane content when it is started up from hot standby. In order to broaden the system rangeability (the minimum percentage of full load), different CO2 staged injection should be carried out: part of carbon dioxide bypasses first and second reactor and it is directly conveyed to the third one. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Power-to-gas is a method for storing intermittent renewable energy in a chemical form, converting energy surpluses into hydrogen and then synthetic methane. The system includes optimized methanation units to ensure methane content, with dynamic behavior studied for startup and partial load operation scenarios. Various CO2 staged injections are used to broaden system rangeability.