Design of a Combined Heat Store and Heat Exchanger for CAES Systems

Bruno Cardenas; Seamus Garvey; James Rouse; Zahra Baniamerian; Daniel Pottie; Edward Barbour

doi:10.1049/rpg2.70064

Design of a Combined Heat Store and Heat Exchanger for CAES Systems

Bruno Cardenas^*
, Seamus Garvey
, James Rouse
, Zahra Baniamerian
, Daniel Pottie
, Edward Barbour

^*Corresponding author for this work

Birmingham Energy Institute

Research output: Contribution to journal › Article › peer-review

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Abstract

A combined heat store and heat exchanger unit (HSX) intended for compressed air energy storage (CAES) is presented. The unit is directly charged by the pressurised air emerging from the compression train, which removes the need for a secondary low-pressure air circuit. Salt is used as the thermal storage medium due to its good heat capacity, thermal conductivity, and its ability to accommodate the thermal expansion of the stainless-steel pipes. This paper uses a CAES system (15 MW, 12-h discharge) driven by an offshore wind turbine as a case study. There are not many commercial CAES systems in operation; however, the levelized cost of the heat storage subsystem of a CAES system (i.e. heat store, set of heat exchangers and ancillary low-pressure circuit) ranges between 45 and 48 £/MWh. Findings show that the most cost-effective design for a HSX has a capital cost of ∼£55k. This translates into a levelized cost of storage of ∼31.5 £/MWh. The roundtrip exergy efficiency of this design is 93.7 %. This accounts for heat-exergy and pressure-exergy losses; losses to ambient are not considered. A HSX unit can considerably reduce the overall cost of a CAES system.

Original language	English
Article number	e70064
Number of pages	20
Journal	IET Renewable Power Generation
Volume	19
Issue number	1
DOIs	https://doi.org/10.1049/rpg2.70064
Publication status	Published - 19 May 2025

Bibliographical note

Copyright:
© 2025 The Author(s). IET Renewable Power Generation published by John Wiley & Sons Ltd on behalf of The Institution of Engineering and Technology.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

compressed air energy storage
cost reduction
energy storage
heat exchangers
heat transfer
thermal energy storage

ASJC Scopus subject areas

Renewable Energy, Sustainability and the Environment

Access to Document

10.1049/rpg2.70064Licence: Creative Commons: Attribution (CC BY)

CardenasB2025DesignFinal published version, 4.11 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

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abstract = "A combined heat store and heat exchanger unit (HSX) intended for compressed air energy storage (CAES) is presented. The unit is directly charged by the pressurised air emerging from the compression train, which removes the need for a secondary low-pressure air circuit. Salt is used as the thermal storage medium due to its good heat capacity, thermal conductivity, and its ability to accommodate the thermal expansion of the stainless-steel pipes. This paper uses a CAES system (15 MW, 12-h discharge) driven by an offshore wind turbine as a case study. There are not many commercial CAES systems in operation; however, the levelized cost of the heat storage subsystem of a CAES system (i.e. heat store, set of heat exchangers and ancillary low-pressure circuit) ranges between 45 and 48 £/MWh. Findings show that the most cost-effective design for a HSX has a capital cost of ∼£55k. This translates into a levelized cost of storage of ∼31.5 £/MWh. The roundtrip exergy efficiency of this design is 93.7 \%. This accounts for heat-exergy and pressure-exergy losses; losses to ambient are not considered. A HSX unit can considerably reduce the overall cost of a CAES system.",

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AU - Garvey, Seamus

AU - Rouse, James

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AU - Barbour, Edward

PY - 2025/5/19

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AB - A combined heat store and heat exchanger unit (HSX) intended for compressed air energy storage (CAES) is presented. The unit is directly charged by the pressurised air emerging from the compression train, which removes the need for a secondary low-pressure air circuit. Salt is used as the thermal storage medium due to its good heat capacity, thermal conductivity, and its ability to accommodate the thermal expansion of the stainless-steel pipes. This paper uses a CAES system (15 MW, 12-h discharge) driven by an offshore wind turbine as a case study. There are not many commercial CAES systems in operation; however, the levelized cost of the heat storage subsystem of a CAES system (i.e. heat store, set of heat exchangers and ancillary low-pressure circuit) ranges between 45 and 48 £/MWh. Findings show that the most cost-effective design for a HSX has a capital cost of ∼£55k. This translates into a levelized cost of storage of ∼31.5 £/MWh. The roundtrip exergy efficiency of this design is 93.7 %. This accounts for heat-exergy and pressure-exergy losses; losses to ambient are not considered. A HSX unit can considerably reduce the overall cost of a CAES system.

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Design of a Combined Heat Store and Heat Exchanger for CAES Systems

Abstract

Bibliographical note

UN SDGs

Keywords

ASJC Scopus subject areas

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