Investigation of shock focusing in a cavity with incident shock diffracted by an obstacle
Investigation of shock focusing in a cavity with incident shock diffracted by an obstacle
Experiments and numerical simulations were carried out in order to investigate the focusing of a shock wave in a test section after the incident shock has been diffracted by an obstacle. A conventional shock tube was used to generate the planar shock. Incident shock Mach numbers of 1.4 and 2.1 were tested. A high-speed camera was employed to obtain schlieren photos of the flow field in the experiments. In the numerical simulations, a weighed essential non-oscillation (WENO) scheme of third-order accuracy supplemented with structured dynamic adaptive mesh adaptation was adopted to simulate the shock wave interaction. Good agreement between experiments and numerical results is observed. The configurations exhibit shock reflection phenomena, shock-vortex interaction and – in particular – shock focusing. The pressure history in the cavity apex was recorded and compared with the numerical results. A quantitative analysis of the numerically observed shock reflection configurations is also performed by employing a pseudo-steady shock transition boundary calculation technique. Regular reflection, single Mach reflection and transitional Mach reflection phenomena are observed and are found to correlate well with analytic predictions from shock reflection theory.
shock focusing, shock diffraction, WENO, AMROC
169–177
Zhang, Qiang
72f405f7-b560-4e3b-861e-f95a3825648d
Chen, Xin
927cf7ef-386c-42b5-aac4-c35836675619
He, Li-Ming
35ee84a3-af57-4d1e-8d90-dc9012051b9f
Rong, Kang
e6719133-fc9c-45ed-8806-262c8747dbc5
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
1 March 2017
Zhang, Qiang
72f405f7-b560-4e3b-861e-f95a3825648d
Chen, Xin
927cf7ef-386c-42b5-aac4-c35836675619
He, Li-Ming
35ee84a3-af57-4d1e-8d90-dc9012051b9f
Rong, Kang
e6719133-fc9c-45ed-8806-262c8747dbc5
Deiterding, Ralf
ce02244b-6651-47e3-8325-2c0a0c9c6314
Zhang, Qiang, Chen, Xin, He, Li-Ming, Rong, Kang and Deiterding, Ralf
(2017)
Investigation of shock focusing in a cavity with incident shock diffracted by an obstacle.
Shock Waves, 27 (2), .
(doi:10.1007/s00193-016-0653-0).
Abstract
Experiments and numerical simulations were carried out in order to investigate the focusing of a shock wave in a test section after the incident shock has been diffracted by an obstacle. A conventional shock tube was used to generate the planar shock. Incident shock Mach numbers of 1.4 and 2.1 were tested. A high-speed camera was employed to obtain schlieren photos of the flow field in the experiments. In the numerical simulations, a weighed essential non-oscillation (WENO) scheme of third-order accuracy supplemented with structured dynamic adaptive mesh adaptation was adopted to simulate the shock wave interaction. Good agreement between experiments and numerical results is observed. The configurations exhibit shock reflection phenomena, shock-vortex interaction and – in particular – shock focusing. The pressure history in the cavity apex was recorded and compared with the numerical results. A quantitative analysis of the numerically observed shock reflection configurations is also performed by employing a pseudo-steady shock transition boundary calculation technique. Regular reflection, single Mach reflection and transitional Mach reflection phenomena are observed and are found to correlate well with analytic predictions from shock reflection theory.
Text
shock_focus_sub_rd.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 4 April 2016
e-pub ahead of print date: 7 May 2016
Published date: 1 March 2017
Keywords:
shock focusing, shock diffraction, WENO, AMROC
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 384828
URI: http://eprints.soton.ac.uk/id/eprint/384828
ISSN: 1432-2153
PURE UUID: b377c987-2e2f-4fdf-9bdc-7477f1e8d733
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Date deposited: 11 Jan 2016 16:39
Last modified: 15 Mar 2024 05:22
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Contributors
Author:
Qiang Zhang
Author:
Xin Chen
Author:
Li-Ming He
Author:
Kang Rong
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