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Thermodynamic Analysis of a Conceptual Fixed-Bed Solar Thermochemical Cavity Receiver–Reactor Array for Water Splitting Via Ceria Redox Cycling

Song Yang, Lifeng Li, Bo Wang, Sha Li, Jun Wang, Peter D. Lund, Wojciech Lipiński

2021Frontiers in Energy Research17 citationsDOIOpen Access PDF

Abstract

We propose a novel solar thermochemical receiver–reactor array concept for hydrogen production via ceria redox cycling. The receiver–reactor array can improve the solar-to-fuel efficiency by realizing the heat recuperation, reduction, and oxidation processes synchronously. A linear matrix model and a lumped parameter model are developed to predict thermal performance of the new solar thermochemical system. The system thermal performance is characterized by heat recovery effectiveness of solid-phase and solar-to-fuel efficiency. Investigated parameters include reduction temperature, oxygen partial pressure, number of receiver–reactors, concentration ratio, and gas-phase heat recovery effectiveness. For baseline conditions, the solid-phase heat recovery effectiveness and the solar-to-fuel efficiency are found to be 81% and 27%, respectively. For perfect gas-phase heat recovery and a solar concentration ratio of 5,000, the solar-to-fuel efficiency exceeds 40%.

Topics & Concepts

Thermochemical cycleWater splittingMaterials scienceHydrogenNuclear engineeringThermalHeat recovery ventilationTemperature cyclingThermal efficiencyThermodynamicsHydrogen productionChemistryChemical engineeringPhysicsHeat exchangerCombustionPhysical chemistryPhotocatalysisEngineeringOrganic chemistryBiochemistryCatalysisChemical Looping and Thermochemical ProcessesCarbon Dioxide Capture TechnologiesAdsorption and Cooling Systems
Thermodynamic Analysis of a Conceptual Fixed-Bed Solar Thermochemical Cavity Receiver–Reactor Array for Water Splitting Via Ceria Redox Cycling | Litcius