Electrifying with High-Temperature Water Electrolysis to Produce Syngas from Wood via Oxy-Gasification, Leading to Superior Carbon Conversion Yield for Methanol Synthesis

• Published in: Applied sciences Vol. 11; no. 6; p. 2672
• Main Authors: Larose, Sylvain, Labrecque, Raynald, Mangin, Patrice
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.03.2021
• Subjects: Biofuels; Biogenic materials; Biomass; biomass gasification; Carbon dioxide; carbon yield; electrification; Electrolysis; Emissions; Energy conversion efficiency; Energy efficiency; Forest residues; Fossil fuels; Gasification; Greenhouse effect; Greenhouse gases; High temperature; Hydroelectric power; methanol production; Process heat; Raw materials; Regional planning; regional sustainability; Simulation; solid oxide electrolysis; Steam; Sustainability; Synthesis gas; Yield
• ISSN: 2076-3417; 2076-3417
• DOI: 10.3390/app11062672

Due to concerns regarding fossil greenhouse gas emissions, biogenic material such as forest residues is viewed nowadays as a valuable source of carbon atoms to produce syngas that can be used to synthesise biofuels such as methanol. A great challenge in using gasified biomass for methanol production is the large excess of carbon in the syngas, as compared to the H2 content. The water–gas shift (WGS) reaction is often used to add H2 and balance the syngas. CO2 is also produced by this reaction. Some of the CO2 has to be removed from the gaseous mixture, thus decreasing the process carbon yield and maintaining CO2 emissions. The WGS reaction also decreases the overall process heat output. This paper demonstrates the usefulness of using an extra source of renewable H2 from steam electrolysis instead of relying on the WGS reaction, for a much higher performance of syngas production from gasification of wood in a simple system with a fixed-bed gasifier. A commercial process simulation software is employed to predict that this approach will be more efficient (overall energy efficiency of about 67%) and productive (carbon conversion yield of about 75%) than relying on the WGS reaction. The outlook for this process that includes the use of the solid oxide electrolyser technology appears to be very promising because the electrolyser has the dual function of providing all of the supplemental H2 required for syngas balancing and all the O2 required for the production of a suitable hot raw syngas. This process is conducive to biomethanol production in dispersed, small plants using local biomass for end-users from the same geographical area, thus contributing to regional sustainability.