Thermodynamic modelling and optimisation of a green hydrogen-blended syngas-fueled integrated PV-SOFC system

Developing an effective energy transition roadmap is crucial in the face of global commitments to achieve net zero emissions. While renewable power generation systems are expanding, challenges such as curtailments and grid constraints can lead to energy loss. To address this, surplus electricity can be converted into green hydrogen, serving as a key component in the energy transition. This research explores the use of renewable solar energy for powering a proton exchange membrane electrolyser to produce green hydrogen, while a downdraft gasifier fed by municipal solid waste generates hydrogen-enriched syngas. The blended fuel is then used to feed a Solid Oxide Fuel Cell (SOFC) system. The study investigates the impact of hydrogen content on the performance of the fuel cell-based power plant from thermodynamics and exergoeconomic perspectives. Multiobjective optimisation using a genetic algorithm identifies optimal operating conditions for the system. Results show that blending hydrogen with syngas increases combined heat and power efficiency by up to 3%, but also raises remarkably the unit product cost and reduces carbon dioxide emissions. Therefore, the optimal values for hydrogen content, current density, temperatures, and other parameters are determined. These findings contribute to the design and operation of an efficient and sustainable energy generation system.

Automated summary

Developing an effective energy transition roadmap is crucial in achieving global commitments to net zero emissions. This research explores the use of renewable solar energy and municipal solid waste to produce hydrogen, which is then used in a fuel cell system to improve energy efficiency and sustainability. The findings contribute to the design and operation of efficient energy generation systems.