Calcium Manganite Based Materials for Thermochemical Energy Storage in High Temperature Solar Thermal Plants: Materials Screening

Authors

DOI:

https://doi.org/10.52825/solarpaces.v2i.906

Keywords:

Thermochemical Energy Storage Cycles, Redox Materials, Perovskites

Abstract

The urgent need for sustainable energy supply requires maximum exploitation of renewable energy sources. The latter, being of intermittent nature, need to be coupled with efficient energy storage. Solar-thermal power-plants are inherently compatible with thermal storage, which is a cost-efficient method of storing energy for later use but the field is currently dominated by sensible heat molten salts used as heat storage media but with a maximum operating temperature of about 560oC. Certain ceramic materials, able to induce reversible reduction-oxidation reactions under air flow, are promising alternatives to molten salts because they can withstand much higher temperatures (>1000oC) and thus can be integrated with high-efficiency air-Brayton thermodynamic cycles. At the same time the chemical energy stored/released during such reduction-oxidation reactions can boost energy storage density by up to 10 times cf. sensible only concepts. In this framework, Ca-Mn-based perovskite compositions were demonstrated to function effectively as energy storage materials. The current work offers insights on material synthesis parameters to achieve relatively high purity Ca-Mn-based compositions and subsequently optimize their redox performance in the course of a preliminary 5-cycle campaign. Moreover, the occurring structural transitions and their corresponding heat effects are also discussed and elaborated upon. This study is the first step towards the, currently in progress, process of synthesising – at multi kg scale – and shaping these compositions into extruded honeycomb-like monolithic structures for subsequent future application in lab- and pilot-scale high temperature thermochemical energy storage systems.

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References

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Published

2024-08-28

How to Cite

Pagkoura, C., Kastrinaki, G., & Karagiannakis, G. (2024). Calcium Manganite Based Materials for Thermochemical Energy Storage in High Temperature Solar Thermal Plants: Materials Screening. SolarPACES Conference Proceedings, 2. https://doi.org/10.52825/solarpaces.v2i.906

Conference Proceedings Volume

Vol. 2 (2023): SolarPACES 2023, 29th International Conference on Concentrating Solar Power, Thermal, and Chemical Energy Systems

Section

Thermal Energy Storage Materials, Media, and Systems

License

Copyright (c) 2024 Chrysa Pagkoura, Georgia Kastrinaki, George Karagiannakis

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Received 2023-10-20
Accepted 2024-04-25
Published 2024-08-28

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