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Journal of Thermal Science

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2025 , Vol. 34 >Issue 5: 1925 - 1936

DOI: https://doi.org/10.1007/s11630-025-2176-4

Numerical Study on Phase Transition and Heat Transfer Characteristics of Over-Pressure Water in Mini-Channels for Oblique Detonation Combustion

  • SUN Wenjing ,
  • CHEN Jieru ,
  • ZHANG Jingzhou ,
  • LING Wenhui ,
  • ZHANG Yining
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  • 1. College of Energy and Power Engineering, Key Laboratory of Thermal Management and Energy Utilization of Aircraft, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China
    2. Beijing Power Machinery Institute, Beijing 100176, China

Online published: 2025-09-01

Supported by

The authors are gratefully for the financial supports provided by Science Center for Gas Turbine Project (P2022-B-II-028-001).

Copyright

Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2025
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Abstract

The oblique detonation chamber has an extreme high and uneven thermal load due to the fast exothermic combustion process induced by oblique shock wave. The active cooling technology of over-pressure water is an effective thermal protection method with the development of additive manufacturing technology. The realizable k-ε model coupling with Volume Fraction (VOF) model is applied to solve the boiling flow of cooling water in the mini-channels. The phase transition and heat transfer characteristics are systematically investigated under different pressures. The phase transition process is first observed in the position of oblique detonation wave, and the bubbly flow, the slug flow, the annular flow and the churn flow are captured in the characteristic cooling channel when boiling flow reaching steady stage. In the rear section of the channel, the uneven heat flux distribution of combustion chamber brings to the churn flow, which enhances the heat transfer compared to the annular flow. Compared to the atmospheric water, the appearances of churn flow and annular flow are significantly decreased with the increasing pressure, and they would disappear when the pressure is exceeding 0.5 MPa. The bubbly flow and slug flow play a dominant role when the pressure is higher than 1 MPa, showing that the over-pressure water can significantly enhance the cooling efficiency of the oblique detonation chamber. With the rise of water pressure, the time point of the appearance of phase transition is obviously lagged because of the increasing latent heat of vaporization, and the cooling efficiency is significantly increased due to the simpler phase transition in higher pressure, which means the over-pressure water could withstand longer heat load of oblique detonation engine.

Key words: oblique detonation chamber; over-pressure water; active cooling technology; phase transition; heat transfer characteristics

Cite this article

SUN Wenjing , CHEN Jieru , ZHANG Jingzhou , LING Wenhui , ZHANG Yining . Numerical Study on Phase Transition and Heat Transfer Characteristics of Over-Pressure Water in Mini-Channels for Oblique Detonation Combustion[J]. Journal of Thermal Science, 2025 , 34(5) : 1925 -1936 . DOI: 10.1007/s11630-025-2176-4

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