A novel liquid air energy storage system using a combination of sensible and latent heat storage

Ju-Yeol Ryu; Adrian Alford; Graham Lewis; Yulong Ding; Yunren Li; Abdalqader Ahmad; Hyunjong Kim; Sung-Ho Park; Jong-Po Park; Simon Branch; Seunghan Yu; Changkook Ryu

doi:10.1016/j.applthermaleng.2021.117890

A novel liquid air energy storage system using a combination of sensible and latent heat storage

Ju-Yeol Ryu^*, Adrian Alford^*, Graham Lewis, Yulong Ding, Yunren Li, Abdalqader Ahmad, Hyunjong Kim, Sung-Ho Park, Jong-Po Park, Simon Branch, Seunghan Yu, Changkook Ryu

^*Corresponding author for this work

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

Abstract

This paper proposes a novel stand-alone liquid air energy storage (LAES) system to enhance round-trip efficiency (RTE) using a thermal energy storage system. Thermal energy storage comprises sensible heat storage with quartz and latent heat storage with cryogenic phase change material (PCM) for recycling cold energy from the LAES discharge process. The liquid air in the pressurized tank was released during the discharge cycle and used to store energy using PCM and quartz. The cryogenic phase change material melts at 110 K based on experimental result, making it possible to provide cold heat of fusion 61.62 kJ/kg at a constant temperature for air liquefaction. Thus, proposed system can effectively increase the cold energy recycle. In addition, the two-dimension numerical model allowed us to estimate the outlet temperature of sensible heat store without isothermal assumption by Biot Number. The proposed process is modified from Linde-Hampson, and a sensitivity analysis is performed using ASPEN HYSYS. The analysis shows that the implementation of energy recycling from the compressor and thermal store leads to a high round-trip efficiency (60.6%) higher than base case (34.4%) of LAES system. Therefore, the proposed system is a promising process in terms of simplification and high efficiency, cognizant of the integration of waste heat from industrial plants.

Original language	English
Article number	117890
Number of pages	11
Journal	Applied Thermal Engineering
Volume	203
Early online date	3 Dec 2021
DOIs	https://doi.org/10.1016/j.applthermaleng.2021.117890
Publication status	Published - 25 Feb 2022

Bibliographical note

Funding Information:
The authors gratefully acknowledge that this research was financially supported by the Korean Energy Technology Evaluation and Planning (No. 20188550000200) and the Department for Business, Energy & Industrial Strategy (No. 415000028360).

Publisher Copyright:
© 2021

Keywords

Energy Storage System
Latent heat storage
Liquid Air
Phase Change Material
Sensible heat storage

ASJC Scopus subject areas

Energy Engineering and Power Technology
Industrial and Manufacturing Engineering

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Cite this

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title = "A novel liquid air energy storage system using a combination of sensible and latent heat storage",

abstract = "This paper proposes a novel stand-alone liquid air energy storage (LAES) system to enhance round-trip efficiency (RTE) using a thermal energy storage system. Thermal energy storage comprises sensible heat storage with quartz and latent heat storage with cryogenic phase change material (PCM) for recycling cold energy from the LAES discharge process. The liquid air in the pressurized tank was released during the discharge cycle and used to store energy using PCM and quartz. The cryogenic phase change material melts at 110 K based on experimental result, making it possible to provide cold heat of fusion 61.62 kJ/kg at a constant temperature for air liquefaction. Thus, proposed system can effectively increase the cold energy recycle. In addition, the two-dimension numerical model allowed us to estimate the outlet temperature of sensible heat store without isothermal assumption by Biot Number. The proposed process is modified from Linde-Hampson, and a sensitivity analysis is performed using ASPEN HYSYS. The analysis shows that the implementation of energy recycling from the compressor and thermal store leads to a high round-trip efficiency (60.6%) higher than base case (34.4%) of LAES system. Therefore, the proposed system is a promising process in terms of simplification and high efficiency, cognizant of the integration of waste heat from industrial plants.",

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author = "Ju-Yeol Ryu and Adrian Alford and Graham Lewis and Yulong Ding and Yunren Li and Abdalqader Ahmad and Hyunjong Kim and Sung-Ho Park and Jong-Po Park and Simon Branch and Seunghan Yu and Changkook Ryu",

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AU - Ryu, Ju-Yeol

AU - Alford, Adrian

AU - Lewis, Graham

AU - Ding, Yulong

AU - Li, Yunren

AU - Ahmad, Abdalqader

AU - Kim, Hyunjong

AU - Park, Sung-Ho

AU - Park, Jong-Po

AU - Branch, Simon

AU - Yu, Seunghan

AU - Ryu, Changkook

N1 - Funding Information: The authors gratefully acknowledge that this research was financially supported by the Korean Energy Technology Evaluation and Planning (No. 20188550000200) and the Department for Business, Energy & Industrial Strategy (No. 415000028360). Publisher Copyright: © 2021

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N2 - This paper proposes a novel stand-alone liquid air energy storage (LAES) system to enhance round-trip efficiency (RTE) using a thermal energy storage system. Thermal energy storage comprises sensible heat storage with quartz and latent heat storage with cryogenic phase change material (PCM) for recycling cold energy from the LAES discharge process. The liquid air in the pressurized tank was released during the discharge cycle and used to store energy using PCM and quartz. The cryogenic phase change material melts at 110 K based on experimental result, making it possible to provide cold heat of fusion 61.62 kJ/kg at a constant temperature for air liquefaction. Thus, proposed system can effectively increase the cold energy recycle. In addition, the two-dimension numerical model allowed us to estimate the outlet temperature of sensible heat store without isothermal assumption by Biot Number. The proposed process is modified from Linde-Hampson, and a sensitivity analysis is performed using ASPEN HYSYS. The analysis shows that the implementation of energy recycling from the compressor and thermal store leads to a high round-trip efficiency (60.6%) higher than base case (34.4%) of LAES system. Therefore, the proposed system is a promising process in terms of simplification and high efficiency, cognizant of the integration of waste heat from industrial plants.

AB - This paper proposes a novel stand-alone liquid air energy storage (LAES) system to enhance round-trip efficiency (RTE) using a thermal energy storage system. Thermal energy storage comprises sensible heat storage with quartz and latent heat storage with cryogenic phase change material (PCM) for recycling cold energy from the LAES discharge process. The liquid air in the pressurized tank was released during the discharge cycle and used to store energy using PCM and quartz. The cryogenic phase change material melts at 110 K based on experimental result, making it possible to provide cold heat of fusion 61.62 kJ/kg at a constant temperature for air liquefaction. Thus, proposed system can effectively increase the cold energy recycle. In addition, the two-dimension numerical model allowed us to estimate the outlet temperature of sensible heat store without isothermal assumption by Biot Number. The proposed process is modified from Linde-Hampson, and a sensitivity analysis is performed using ASPEN HYSYS. The analysis shows that the implementation of energy recycling from the compressor and thermal store leads to a high round-trip efficiency (60.6%) higher than base case (34.4%) of LAES system. Therefore, the proposed system is a promising process in terms of simplification and high efficiency, cognizant of the integration of waste heat from industrial plants.

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A novel liquid air energy storage system using a combination of sensible and latent heat storage

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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