Optimization of the Coating Process of a Ca(OH)<sub>2</sub>‐Based Thermochemical Energy Storage Material

Lucke, Benjamin W.; Afflerbach, Sandra; Krumm, Wolfgang

doi:10.1002/cite.202300081

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2024

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Cited by 3 publications

References 48 publications

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Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Cosquillo Mejia,

Afflerbach,

Linder

et al. 2024

Energy Conversion and Management: X

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Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Cosquillo Mejia,

Afflerbach,

Linder

et al. 2024

Energy Conversion and Management: X

View full text Add to dashboard Cite

Optimization of ammonia and TEOS concentration for the development of Ca(OH)2@SiO2 nanocomposites for optimal energy storage performance

Ali,

Farooq,

Steiger

et al. 2024

Materials Chemistry and Physics

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Zero Emission Heating with Calcium Oxide and Water: Development and Demonstration of First Pilot Scale Thermochemical Heating System for Buildings

Schmidt,

Sourmelis,

Kühl

et al. 2024

Preprint

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Heat supply for residential buildings is still mainly based on fossil fuels and is thus a major CO2 emitter. Renewable heating remains a technological challenge, often for the reason that during cold weather periods heat demand increases drastically whereas renewable production minimizes. Reactive solids produced by renewable energy can be an energy storage and carrier to flexibly leverage the often extreme seasonal discrepancy of residential heat demand. This work demonstrates a fully integrated thermochemical heating system based on calcium oxide and water operational for the first time in a real building environment. With the extraction of the thermochemically stored energy at a temperature level of 60 °C we proved that the technology can be integrated into existing heating infrastructures of buildings, by replacing fossil fuel-based burners. This work advances the technology readiness level of thermochemical energy storage to validation in relevant environment.

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Optimization of the Coating Process of a Ca(OH)₂‐Based Thermochemical Energy Storage Material

Cited by 3 publications

References 48 publications

Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Optimization of ammonia and TEOS concentration for the development of Ca(OH)2@SiO2 nanocomposites for optimal energy storage performance

Zero Emission Heating with Calcium Oxide and Water: Development and Demonstration of First Pilot Scale Thermochemical Heating System for Buildings

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Optimization of the Coating Process of a Ca(OH)2‐Based Thermochemical Energy Storage Material

Cited by 3 publications

References 48 publications

Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Real-time visualization and experimental analysis of stabilized Ca(OH)2 granules for thermal energy storage

Optimization of ammonia and TEOS concentration for the development of Ca(OH)2@SiO2 nanocomposites for optimal energy storage performance

Zero Emission Heating with Calcium Oxide and Water: Development and Demonstration of First Pilot Scale Thermochemical Heating System for Buildings

Contact Info

Product

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Optimization of the Coating Process of a Ca(OH)₂‐Based Thermochemical Energy Storage Material