A Planar-Cavity Receiver Configuration for High-Temperature Solar Thermal Processes

Authors

DOI:

https://doi.org/10.52825/solarpaces.v2i.966

Keywords:

Concentrating Solar Power, Particle Receiver, Numerical Modeling

Abstract

Next-generation concentrating solar thermal power (CSP) technologies target a wide spectrum of applications including electricity generation, thermochemical processes, and industrial process heat for broad decarbonization potential. Many of these applications require higher temperatures than those of current commercial nitrate salt systems. Particulate materials are promising candidates for next-generation high-temperature heat transfer and low-cost storage media and can facilitate operation over a wide temperature range. However these materials necessitate novel receiver configurations to accept the high incident flux concentrations that enable high solar-to-thermal receiver efficiency. One option is a novel light-trapping planar cavity receiver configuration in which small cavity-like structures are formed from opaque planar surfaces such that a high incident flux concentration at the cavity aperture is reduced to a wall-absorbed solar flux concentration that is manageable within limited wall-to-particle heat transfer rates. The paper introduces the receiver configuration and provides calculated optical performance for a preliminary 50 MWt receiver design.

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Published

2024-08-28

How to Cite

Martinek, J., & Ma, Z. (2024). A Planar-Cavity Receiver Configuration for High-Temperature Solar Thermal Processes. SolarPACES Conference Proceedings, 2. https://doi.org/10.52825/solarpaces.v2i.966

Conference Proceedings Volume

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

Section

Receivers and Heat Transfer Media and Transport: Point Focus Systems

License

Copyright (c) 2024 Janna Martinek, Zhiwen Ma

Creative Commons License

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

Received 2023-12-05
Accepted 2024-04-08
Published 2024-08-28

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