Abstract
This work aims at investigating the reduction/oxidation (redox) reaction kinetics on iron oxide pellets under different operating conditions of thermochemical hydrogen storage. In order to reduce the iron oxide pellets (90% Fe2O3, 10% stabilizing cement), hydrogen (H2) is applied in different concentrations with nitrogen (N2), as a carrier gas, at temperatures between between 700 ∘C and 900 ∘C, thus simulating the charging phase. The discharge phase is triggered by the flow of a mixture out of steam (H2O) and N2 at different concentrations in the same temperature range, resulting in the oxidizing of the previously reduced pellets. All investigations were carried out in a thermo-gravimetric analyzer (TGA) with a flow rate of 250mL/min. To describe the obtained kinetic results, a simplified analytical model, based on the linear driving force model, was developed. The investigated iron oxide pellets showed a stable redox performance of 23.8% weight reduction/gain, which corresponds to a volumetric storage density of 2.8kWh/(L bulk), also after the 29 performed redox cycles. Recalling that there is no H2 stored during the storage phase but iron, the introduced hydrogen storage technology is deemed very promising for applications in urban areas as day-night or seasonal storage for green hydrogen.
Highlights
The adverse effects of climate change have become more and more obvious [1].The reason behind this development is identified in the global energy-related greenhouse and CO2 gas emissions
The reaction kinetics of the ironaoxide samples are determined by the setup, analyzer depicted device
The second subsection introduces the effect of the composition of the reacting gas flow during the reduction and oxidation phases according to Table 2 on the reaction kinetics
Summary
The adverse effects of climate change have become more and more obvious [1]. The reason behind this development is identified in the global energy-related greenhouse and CO2 gas emissions. These are periodically flattening out, they have increased by an average of 1% per year over the last ten years [2]. By an intelligent combination of wind, solar, as well as bio energy with efficient energy storage along with an effective power recovery system, a decentralized “green” energy supply can be realized. Different energy sectors of industrial plants and urban residential areas can be supplied with “green”
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