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AEROSPACE SHANGHAI, Volume. 42, Issue 2, 194(2025)

Numerical Simulation of Orbit-controlled Jet Considering Multi-physical Effects

Zhao WAN, Ruhao HUA, Qi CHEN*, Dingwu JIANG, and Xinguang WANG
Author Affiliations
  • Computational Aerodynamic Institute,China Aerodynamic Research and Development Center,Mianyang621000,,China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (17)
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    References (13)
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    Figures & Tables(17)
    Comparison of the pressure coefficient distributions under different P0

    Fig. 1. Comparison of the pressure coefficient distributions under different P0

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    Configuration and grids of the lifting body

    Fig. 2. Configuration and grids of the lifting body

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    Temperature field and jet interaction flow field structure

    Fig. 3. Temperature field and jet interaction flow field structure

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    Pressure and streamline distributions on the windward side

    Fig. 4. Pressure and streamline distributions on the windward side

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    Temperature distribution of the symmetry surface

    Fig. 5. Temperature distribution of the symmetry surface

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    Heat flux distribution on the windward side

    Fig. 6. Heat flux distribution on the windward side

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    CO2 component distribution on the symmetry surface

    Fig. 7. CO2 component distribution on the symmetry surface

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    Variation of the jet interaction force/moment with the Mach number (70 km)

    Fig. 8. Variation of the jet interaction force/moment with the Mach number 70 km

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    Variation of the jet interference factor with the Mach number

    Fig. 9. Variation of the jet interference factor with the Mach number

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    Variation of the jet interaction force/moment with the height (Ma=25)

    Fig. 10. Variation of the jet interaction force/moment with the height Ma=25

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    Variation of the jet interference factor with the height

    Fig. 11. Variation of the jet interference factor with the height

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    Pressure and streamline distribution on the windward in rarefied environment

    Fig. 12. Pressure and streamline distribution on the windward in rarefied environment

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    Distribution of pressure on the windward scale line

    Fig. 13. Distribution of pressure on the windward scale line

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    Influence of the rarefaction effect on the aerodynamic force/moment of the hot-gas jet interaction under different conditions

    Fig. 14. Influence of the rarefaction effect on the aerodynamic force/moment of the hot-gas jet interaction under different conditions

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    • Table 1. Chemical reaction models of the high-temperature air<sup>[<a class="aTag" href="#Ref_33" target="_self" style="display: inline;">33</a>]</sup>

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      Table 1. Chemical reaction models of the high-temperature air<sup>[<a class="aTag" href="#Ref_33" target="_self" style="display: inline;">33</a>]</sup>

      序号反应
      1N2+M1↔N+N+M1
      2O2+M2 ↔O+O+M2
      3NO+M3 ↔N+O+M3
      4O+NO ↔N+O2
      5O+N2 ↔N+NO
      6N+O ↔NO++e

    • Table 2. Chemical reaction models of the jet gas components<sup>[<a class="aTag" href="#Ref_34" target="_self" style="display: inline;">34</a>]</sup>

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      Table 2. Chemical reaction models of the jet gas components<sup>[<a class="aTag" href="#Ref_34" target="_self" style="display: inline;">34</a>]</sup>

      序号反应
      1CO2+M4 ↔CO+O+M4
      2CO+M5 ↔C+O+M5
      3CO2+O ↔ O2+CO
      4CO+NO ↔ CO2+N
      5CO+O ↔ O2+C
      6CO+N ↔NO+C
      7CO+CO ↔ CO2+C
      8H2O+M6 ↔H+OH+M6
      9H2+M7 ↔H+H+M7
      10OH+M8 ↔O+H+M8
      11OH+CO ↔CO2+H
      12OH+H2 ↔H2O+H
      13H+O2 ↔OH+O
      14O+H2 ↔OH+H
      15OH+OH ↔H2O+O

    • Table 3. Comparison of the separation lengths under different calculation conditions

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      Table 3. Comparison of the separation lengths under different calculation conditions

      P0/kPa风洞试验/mm本文CFD/mm文献DSMC[29]/mm
      6.7520.0018.0018.00
      37.0235.0033.0033.00
      145.3045.0044.8042.00
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    Zhao WAN, Ruhao HUA, Qi CHEN, Dingwu JIANG, Xinguang WANG. Numerical Simulation of Orbit-controlled Jet Considering Multi-physical Effects[J]. AEROSPACE SHANGHAI, 2025, 42(2): 194

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    Paper Information

    Category: Simulation and Analysis

    Received: Nov. 6, 2024

    Accepted: --

    Published Online: May. 26, 2025

    The Author Email:

    DOI:10.19328/j.cnki.2096-8655.2025.02.019

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology