Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model

Couvreur, Kenny; Beyne, Wim; Tassenoy, Robin; Lecompte, Steven; De Paepe, Michel

Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model

Kenny Couvreur (UGent) , Wim Beyne (UGent) , Robin Tassenoy (UGent) , Steven Lecompte (UGent) and Michel De Paepe (UGent)

(2023) APPLIED THERMAL ENGINEERING. 219(Part B).

Author

Kenny Couvreur (UGent) , Wim Beyne (UGent) , Robin Tassenoy (UGent) , Steven Lecompte (UGent) and Michel De Paepe (UGent)

Organization

Department of Electromechanical, Systems and Metal Engineering

Project

INPATH-TES (PhD on Innovation Pathways for TES)
179P02516

Abstract

Correlations predicting the transient behavior of latent heat thermal energy storage systems without too many computational efforts are valuable for engineering practices. This characterization of latent heat thermal energy storage systems can be done with the recently developed charging time energy fraction method. This method allows fitting a predictive model for the outlet heat transfer fluid temperature of a latent thermal storage unit as a function of the input condition. The previous application of the method neglected heat transfer to the ambient. The present paper improves the charging time energy fraction method by proposing a heat loss model to the charging time energy fraction model. A finite volume model of a high-temperature thermal battery is used to validate the proposed heat loss model. The improved charging time energy fraction method is then used to characterize a high-temperature thermal battery by calibrating a model on 36 numerical charging experiments. The charging time prediction between energy fractions of 0 and 0.96 deviates maximally 2 % from the measured charging time over all 36 calibration experiments. The deviation increases near the end of the charging process, especially for slower charging experiments. Across the 36 calibration experiments, the worst prediction has an average absolute temperature difference of 0.50 degrees C with a maximum deviation of 2.58 degrees C at the very beginning of the charging where fast transients are occurring. The calibrated model is also compared to four numerical validation experiments and four real experiments. Overall it is shown that this low computational cost model with average calculation times of 2-3 ms can accurately predict the heat transfer fluid outlet temperature of latent thermal energy storage heat exchangers.

Keywords

Industrial and Manufacturing Engineering, Energy Engineering and Power Technology

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01GJG4K3Y9MV4567KWF9VKZAPR

MLA: Couvreur, Kenny, et al. “Characterization of a Latent Thermal Energy Storage Heat Exchanger Using a Charging Time Energy Fraction Method with a Heat Loss Model.” APPLIED THERMAL ENGINEERING, vol. 219, no. Part B, 2023, doi:10.1016/j.applthermaleng.2022.119526.
APA: Couvreur, K., Beyne, W., Tassenoy, R., Lecompte, S., & De Paepe, M. (2023). Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model. APPLIED THERMAL ENGINEERING, 219(Part B). https://doi.org/10.1016/j.applthermaleng.2022.119526
Chicago author-date: Couvreur, Kenny, Wim Beyne, Robin Tassenoy, Steven Lecompte, and Michel De Paepe. 2023. “Characterization of a Latent Thermal Energy Storage Heat Exchanger Using a Charging Time Energy Fraction Method with a Heat Loss Model.” APPLIED THERMAL ENGINEERING 219 (Part B). https://doi.org/10.1016/j.applthermaleng.2022.119526.
Chicago author-date (all authors): Couvreur, Kenny, Wim Beyne, Robin Tassenoy, Steven Lecompte, and Michel De Paepe. 2023. “Characterization of a Latent Thermal Energy Storage Heat Exchanger Using a Charging Time Energy Fraction Method with a Heat Loss Model.” APPLIED THERMAL ENGINEERING 219 (Part B). doi:10.1016/j.applthermaleng.2022.119526.
Vancouver: 1.
Couvreur K, Beyne W, Tassenoy R, Lecompte S, De Paepe M. Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model. APPLIED THERMAL ENGINEERING. 2023;219(Part B).
IEEE: [1]
K. Couvreur, W. Beyne, R. Tassenoy, S. Lecompte, and M. De Paepe, “Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model,” APPLIED THERMAL ENGINEERING, vol. 219, no. Part B, 2023.

@article{01GJG4K3Y9MV4567KWF9VKZAPR,
  abstract     = {{Correlations predicting the transient behavior of latent heat thermal energy storage systems without too many computational efforts are valuable for engineering practices. This characterization of latent heat thermal energy storage systems can be done with the recently developed charging time energy fraction method. This method allows fitting a predictive model for the outlet heat transfer fluid temperature of a latent thermal storage unit as a function of the input condition. The previous application of the method neglected heat transfer to the ambient. The present paper improves the charging time energy fraction method by proposing a heat loss model to the charging time energy fraction model. A finite volume model of a high-temperature thermal battery is used to validate the proposed heat loss model. The improved charging time energy fraction method is then used to characterize a high-temperature thermal battery by calibrating a model on 36 numerical charging experiments. The charging time prediction between energy fractions of 0 and 0.96 deviates maximally 2 % from the measured charging time over all 36 calibration experiments. The deviation increases near the end of the charging process, especially for slower charging experiments. Across the 36 calibration experiments, the worst prediction has an average absolute temperature difference of 0.50 degrees C with a maximum deviation of 2.58 degrees C at the very beginning of the charging where fast transients are occurring. The calibrated model is also compared to four numerical validation experiments and four real experiments. Overall it is shown that this low computational cost model with average calculation times of 2-3 ms can accurately predict the heat transfer fluid outlet temperature of latent thermal energy storage heat exchangers.}},
  articleno    = {{119526}},
  author       = {{Couvreur, Kenny and Beyne, Wim and Tassenoy, Robin and Lecompte, Steven and De Paepe, Michel}},
  issn         = {{1359-4311}},
  journal      = {{APPLIED THERMAL ENGINEERING}},
  keywords     = {{Industrial and Manufacturing Engineering,Energy Engineering and Power Technology}},
  language     = {{eng}},
  number       = {{Part B}},
  pages        = {{23}},
  title        = {{Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model}},
  url          = {{http://doi.org/10.1016/j.applthermaleng.2022.119526}},
  volume       = {{219}},
  year         = {{2023}},
}

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Characterization of a latent thermal energy storage heat exchanger using a charging time energy fraction method with a heat loss model

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