Synergistic methanol and DME production via thermochemical hydrogen and calcium looping CO2 capture in decentralised biogas-fuelled power plants
Navid Kousheshi, Ata Chitsaz, Mortaza Yari, Ali Saberi Mehr
Abstract
This research examines a cohesive system that integrates Solid Oxide Fuel Cells (SOFC) fuelled by biogas, a Calcium Looping (CaL) CO 2 collecting mechanism, and a thermochemical hydrogen generation unit. The system is designed to create energy, sequester CO 2 , and synthesise methanol and Dimethyl Ether (DME) as useful byproducts. We examine the efficiency, CO 2 collection capability, and economic feasibility of this decentralised biogas power plant using a thermodynamic and techno-economic study. Our results demonstrate that the SOFC system attains a net electrical efficiency of 56.6 % in independent operation. Nevertheless, the incorporation of the CaL and hydrogen production units diminishes this efficiency to 20.9 %, indicative of the energy requirements for CO 2 collection and fuel generation operations. The CaL system exhibited CO2 collection efficiencies ranging from 76 % to 99 %, correlating with enhanced synthesis of methanol and DME at elevated capture rates. At a CO 2 capture efficiency of 99 %, the system generates 1273.4 kg of methanol and 458.4 kg of DME for each megawatt-hour of energy produced. The techno-economic research indicated that capital expenditure is primarily influenced by the SOFC system (43 %) and CaL unit (30 %), whilst methanol and DME production represent 9 % and 13 % of the investment, respectively. Operational expenditure is mostly influenced by fuel and raw material expenses, accounting for 48 % of the total. This integrated system exhibits the capacity to markedly decrease CO 2 emissions while generating renewable fuels, presenting a feasible alternative for decentralised, sustainable energy production. • Introduces an innovative process for DME and green methanol from captured CO 2 . • Combines SOFC, CaL CO 2 capture, and hydrogen for sustainable power generation. • Achieves up to 99 % CO 2 capture with methanol and DME as valuable by-products. • System efficiency at 90.7 % through optimised heat recovery processes. • SOFC and CaL systems are primary capital cost drivers; fuel impacts operational costs.