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Simulation of liquid jet primary breakup in a supersonic crossflow under adaptive mesh refinement framework

Simulation of liquid jet primary breakup in a supersonic crossflow under adaptive mesh refinement framework
Simulation of liquid jet primary breakup in a supersonic crossflow under adaptive mesh refinement framework
Compressible two-phase flows were simulated based on the five-equation model under the Adaptive Mesh Refinement (AMR) framework to balance the requirements between space resolution and computational cost. And the simulation system was established in an open source software AMROC (Adaptive Mesh Refinement Object-oriented C++). A combination of Godunov method and wave propagation method was introduced to integrate numerical methods with the AMR algorithm. High speed and high liquid-gas density ratio are two main challenges in the simulation of liquid jet in a supersonic crossflow. To enhance the robustness of the simulation system, a MOON-type positivity preserving method was adopted in the development of the codes. Based on the system mentioned above, a liquid jet in a Mach 1.5 supersonic crossflow was simulated as the standard case to study the primary breakup process in the near field. The simulation captured the column and surface breakup which were the results of the development of the unstable waves in two directions respectively. The instabilities causing the surface breakup were found to be generated in the transonic region initially. Crossflow of a higher Mach number (Ma 1.8) was found being able to augment the in stable waves along the injection direction and increase the number of instabilities responsible for the surface breakup. While there was no obvious enhancement of the penetration in the condition of periodic injection, extra unstable waves were imposed on both of windward and leeward liquid surface. The introduced unstable waves had an improvement on the column and surface breakup.
Compressible two-phase model, Adaptive Mesh Refinement, Liquid jet, Primary breakup, Supersonic crossflow
1270-9638
456-473
Liu, Nan
899d32e0-6a21-450b-9f1a-d5648c0f49fb
Wang, Zhenguo
19cc9426-43ed-4cda-b150-dfc2e054049c
Sun, Mingbo
2df9eb75-e5d8-48cf-b8e1-00b0b77b3a90
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Wang, Hongbo
c3bc5031-2b17-4360-9100-a7680e967c8e
Liu, Nan
899d32e0-6a21-450b-9f1a-d5648c0f49fb
Wang, Zhenguo
19cc9426-43ed-4cda-b150-dfc2e054049c
Sun, Mingbo
2df9eb75-e5d8-48cf-b8e1-00b0b77b3a90
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Wang, Hongbo
c3bc5031-2b17-4360-9100-a7680e967c8e

Liu, Nan, Wang, Zhenguo, Sun, Mingbo, Deiterding, Ralf and Wang, Hongbo (2019) Simulation of liquid jet primary breakup in a supersonic crossflow under adaptive mesh refinement framework. Aerospace Science and Technology, 91, 456-473. (doi:10.1016/j.ast.2019.05.017).

Record type: Article

Abstract

Compressible two-phase flows were simulated based on the five-equation model under the Adaptive Mesh Refinement (AMR) framework to balance the requirements between space resolution and computational cost. And the simulation system was established in an open source software AMROC (Adaptive Mesh Refinement Object-oriented C++). A combination of Godunov method and wave propagation method was introduced to integrate numerical methods with the AMR algorithm. High speed and high liquid-gas density ratio are two main challenges in the simulation of liquid jet in a supersonic crossflow. To enhance the robustness of the simulation system, a MOON-type positivity preserving method was adopted in the development of the codes. Based on the system mentioned above, a liquid jet in a Mach 1.5 supersonic crossflow was simulated as the standard case to study the primary breakup process in the near field. The simulation captured the column and surface breakup which were the results of the development of the unstable waves in two directions respectively. The instabilities causing the surface breakup were found to be generated in the transonic region initially. Crossflow of a higher Mach number (Ma 1.8) was found being able to augment the in stable waves along the injection direction and increase the number of instabilities responsible for the surface breakup. While there was no obvious enhancement of the penetration in the condition of periodic injection, extra unstable waves were imposed on both of windward and leeward liquid surface. The introduced unstable waves had an improvement on the column and surface breakup.

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liquid breakup 0419 - Accepted Manuscript
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Accepted/In Press date: 7 May 2019
e-pub ahead of print date: 20 May 2019
Published date: August 2019
Keywords: Compressible two-phase model, Adaptive Mesh Refinement, Liquid jet, Primary breakup, Supersonic crossflow

Identifiers

Local EPrints ID: 430907
URI: http://eprints.soton.ac.uk/id/eprint/430907
ISSN: 1270-9638
PURE UUID: ff64bb3d-53df-42ba-8cc4-237cd1445261
ORCID for Ralf Deiterding: ORCID iD orcid.org/0000-0003-4776-8183

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Date deposited: 17 May 2019 16:30
Last modified: 16 Mar 2024 07:51

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Contributors

Author: Nan Liu
Author: Zhenguo Wang
Author: Mingbo Sun
Author: Ralf Deiterding ORCID iD
Author: Hongbo Wang

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