Metabolic heat production impacts industrial upscaling of ex situ biomethanation trickle-bed reactors

Conversion of electrical energy and CO₂ to a chemical energy carrier in the form of biomethane, can be carried out through the process chain of biomethanation. Although this process provides a promising source of fossil-free natural gas, limited experience with upscaling still hampers its industrial...

Full description

Saved in:
Bibliographic Details
Published inEnergy conversion and management Vol. 299; p. 117769
Main Authors Engelbrecht, Nicolaas, Sieborg, Mads U., Ottosen, Lars D.M., Kofoed, Michael V.W.
Format Journal Article
LanguageEnglish
Published 01.01.2024
Subjects
administrative management
biogas
carbon dioxide
cooling
electric power
energy conversion
heat production
hydrodynamics
methane production
natural gas
temperature
thermal stability
Online AccessGet full text

Cover

More Information
Summary:Conversion of electrical energy and CO₂ to a chemical energy carrier in the form of biomethane, can be carried out through the process chain of biomethanation. Although this process provides a promising source of fossil-free natural gas, limited experience with upscaling still hampers its industrial maturation. Through methanation of raw biogas in a 225 L pilot-scale trickle-bed reactor by use of electrolysis-derived H₂, this work uniquely elucidates how metabolic heat from the exothermic biomethanation process present both a challenge and opportunity for upscaling the biomethanation technology. For the first time, a trickle-bed reactor subject to periodic trickling is characterised based on axial temperature profiles as a result of exothermic heat release, in up-flow and down-flow gas configurations. At maximum, reactor core temperatures in the upper thermophilic range (78 and 83 °C) were recorded in certain axial locations, respectively, for substrate gas flow rates of 3.0 and 7.5 NLCO₂/Lᵣₑₐcₜₒᵣ/d. During a long-term continuous period at 3.0 NLCO₂/Lᵣₑₐcₜₒᵣ/d, biomethane production with a CH₄ content of ≥95 vol% was measured, in both the reactor’s up-flow and down-flow gas configurations. The alternating flow directions and periodic trickling affected both hydrodynamic factors and thermal stability, showing the importance of preheating and humidifying gaseous feed streams and the implementation of a metabolic heat management strategy, by way of cooling, to provide thermal and reaction stability for future upscaling of trickle-bed biomethanation reactors for biological power-to-gas.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0196-8904
DOI:10.1016/j.enconman.2023.117769