Current status of the thermohydraulic behavior of supercritical refrigerants : a review

Van Nieuwenhuyse, Jera; Lecompte, Steven; De Paepe, Michel

Current status of the thermohydraulic behavior of supercritical refrigerants : a review

Jera Van Nieuwenhuyse (UGent) , Steven Lecompte (UGent) and Michel De Paepe (UGent)

(2023) APPLIED THERMAL ENGINEERING. 218.

Author

Jera Van Nieuwenhuyse (UGent) , Steven Lecompte (UGent) and Michel De Paepe (UGent)

Organization

Department of Electromechanical, Systems and Metal Engineering

Project

Heat transfer to refrigerants in the near supercritical region

Abstract

Supercritical heat transfer has already been applied for decades, as it has several benefits such as improved thermal efficiency of the thermodynamic cycle. Accurate knowledge about supercritical heat transfer and pressure drop of the different working fluids is required to design the heat exchangers and other components used in these systems. In literature, supercritical heat transfer of water and CO2 has already been widely investigated, the research involving refrigerants (for their application in low-temperature heat conversion systems) is however rather scarce. This paper gives an overview of the existing research on supercritical heat transfer. An overview of the applications, general characteristics and the main findings for water and other fluids are summarized. Due to the sharp variations in thermophysical properties, heat transfer and pressure drop cannot be accurately predicted on a single-phase based approach only. An in-detail review of the current research and status of knowledge about supercritical heat transfer of refrigerants is presented. The effect of the different investigated refrigerants and operating parameters on heat transfer and pressure drop, both for heating and cooling applications, is discussed. The remaining gaps in literature are highlighted, which include studies involving larger diameter tubes, horizontal flow, cooling heat transfer and pressure drop estimations and creation of a wider database for a more general correlation development and measurements on newer refrigerants (with low Global Warming Potentials) as these will become increasingly important in the near future. In addition, advances in numerical research should focus on development of suitable turbulence models. Overall, further improving the basic understanding of the fluid structure and occurrence of deteriorated heat transfer, as well as forming reliable models for the thermophysical properties are key in future efforts.

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-8767503

MLA: Van Nieuwenhuyse, Jera, et al. “Current Status of the Thermohydraulic Behavior of Supercritical Refrigerants : A Review.” APPLIED THERMAL ENGINEERING, vol. 218, 2023, doi:10.1016/j.applthermaleng.2022.119201.
APA: Van Nieuwenhuyse, J., Lecompte, S., & De Paepe, M. (2023). Current status of the thermohydraulic behavior of supercritical refrigerants : a review. APPLIED THERMAL ENGINEERING, 218. https://doi.org/10.1016/j.applthermaleng.2022.119201
Chicago author-date: Van Nieuwenhuyse, Jera, Steven Lecompte, and Michel De Paepe. 2023. “Current Status of the Thermohydraulic Behavior of Supercritical Refrigerants : A Review.” APPLIED THERMAL ENGINEERING 218. https://doi.org/10.1016/j.applthermaleng.2022.119201.
Chicago author-date (all authors): Van Nieuwenhuyse, Jera, Steven Lecompte, and Michel De Paepe. 2023. “Current Status of the Thermohydraulic Behavior of Supercritical Refrigerants : A Review.” APPLIED THERMAL ENGINEERING 218. doi:10.1016/j.applthermaleng.2022.119201.
Vancouver: 1.
Van Nieuwenhuyse J, Lecompte S, De Paepe M. Current status of the thermohydraulic behavior of supercritical refrigerants : a review. APPLIED THERMAL ENGINEERING. 2023;218.
IEEE: [1]
J. Van Nieuwenhuyse, S. Lecompte, and M. De Paepe, “Current status of the thermohydraulic behavior of supercritical refrigerants : a review,” APPLIED THERMAL ENGINEERING, vol. 218, 2023.

@article{8767503,
  abstract     = {{Supercritical heat transfer has already been applied for decades, as it has several benefits such as improved thermal efficiency of the thermodynamic cycle. Accurate knowledge about supercritical heat transfer and pressure drop of the different working fluids is required to design the heat exchangers and other components used in these systems. In literature, supercritical heat transfer of water and CO2 has already been widely investigated, the research involving refrigerants (for their application in low-temperature heat conversion systems) is however rather scarce. This paper gives an overview of the existing research on supercritical heat transfer. An overview of the applications, general characteristics and the main findings for water and other fluids are summarized. Due to the sharp variations in thermophysical properties, heat transfer and pressure drop cannot be accurately predicted on a single-phase based approach only. An in-detail review of the current research and status of knowledge about supercritical heat transfer of refrigerants is presented. The effect of the different investigated refrigerants and operating parameters on heat transfer and pressure drop, both for heating and cooling applications, is discussed. The remaining gaps in literature are highlighted, which include studies involving larger diameter tubes, horizontal flow, cooling heat transfer and pressure drop estimations and creation of a wider database for a more general correlation development and measurements on newer refrigerants (with low Global Warming Potentials) as these will become increasingly important in the near future. In addition, advances in numerical research should focus on development of suitable turbulence models. Overall, further improving the basic understanding of the fluid structure and occurrence of deteriorated heat transfer, as well as forming reliable models for the thermophysical properties are key in future efforts.}},
  articleno    = {{119201}},
  author       = {{Van Nieuwenhuyse, Jera and Lecompte, Steven and De Paepe, Michel}},
  issn         = {{1359-4311}},
  journal      = {{APPLIED THERMAL ENGINEERING}},
  language     = {{eng}},
  pages        = {{20}},
  title        = {{Current status of the thermohydraulic behavior of supercritical refrigerants : a review}},
  url          = {{http://doi.org/10.1016/j.applthermaleng.2022.119201}},
  volume       = {{218}},
  year         = {{2023}},
}

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Current status of the thermohydraulic behavior of supercritical refrigerants : a review

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