Numerical Study of the Effects of Magnetohydrodynamic Field on Shock-Induced Flow Separation

Document Type : Original Article

Authors

1 استاد

2 ARI

Abstract

In the process of forming a reflective shock wave, the separation of the flow in the reflection site is a common phenomenon. This phenomenon, known as the shock-induced flow separation, sometimes leads to undesirable effects such as reducing the volume and disrupting the flow of air into the ramjet and scrarmjet engines. Therefore, we try to reduce these undesirable effects by different flow control methods. Magnetohydrodynamics is one of the advanced methods for controlling the flow, which shrinks the bubble separation by accelerating to the boundary layer by Lorentz force. The purpose of this research is the numerical study of the effects of this method on the separation caused by the reflection shock wave. The simulations are performed in two-dimensional conditions for different Hartmann numbers and the effects on flow characteristics such as pressure, velocity and flow stream line are investigated. The results indicate that the application of the magnetohydrodynamic field can significantly reduce the adverse pressure gradient and the vortex flow, and it can also reduce the size of the separation bubble by 40% and increase the skin friction coefficient by increasing the wall shear stress. Moreover, the application of the magnetohydrodynamic field can change the shock angle, causing the separation bubble to move forward by about 2% of the channel length.

Keywords


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Volume 9, Issue 2 - Serial Number 26
November 2021
Pages 17-28
  • Receive Date: 04 November 2019
  • Revise Date: 20 February 2020
  • Accept Date: 28 June 2020
  • Publish Date: 29 November 2021