Evaluation of process performance, energy consumption and microbiota characterization in a ceramic membrane bioreactor for ex-situ biomethanation of H2 and CO2

Abstract

The performance of a pilot ceramic membrane bioreactor for the bioconversion of H₂ and CO₂ to bioCH₄ was evaluated in thermophilic conditions. The loading rate was between 10 and 30 m³ H₂/m³_reactor d and the system transformed 95% of H₂ fed. The highest methane yield found was 0.22 m³ CH₄/m³ H₂, close to the maximum stoichiometric value (0.25 m³ CH₄/m³ H₂) thus indicating that archaeas employed almost all H₂ transferred to produce CH₄. k_La value of 268 h^-1 was reached at 30 m³ H₂/m³_reactor d. DGGE and FISH revealed a remarkable archaeas increase related to the selection-effect of H₂ on community composition over time. Methanothermobacter thermautotrophicus was the archaea found with high level of similarity. This study verified the successful application of membrane technology to efficiently transfer H₂ from gas to the liquid phase, the development of a hydrogenotrophic community from a conventional thermophilic sludge and the technical feasibility of the bioconversion.

Keywords: Biomethane; Ex-situ upgrading; Hydrogenotrophic archaea; MBR; Methanation.