Abstract
Shock boundary–layer interactions occur in many high-speed aerodynamic flows and they can have a notable impact on design considerations due to the aerodynamic and heat transfer effects. Consequently there is a notable interest in understanding the ability of computational tools to calculate the complex flow fields that can arise in a range of engineering applications. Three-dimensional complex shock boundary layer interaction studies are expensive in both time and computational resources. Although recent studies have begun to focus on the use of more complex computational methods such as large eddy simulations, the aim of this research is to assess the ability of steady Reynolds averaged Navier Stokes turbulence models to simulate the interaction of a planar shock impinging on a cylindrical body under supersonic conditions and to determine if these models have a role to play in engineering design applications. The performance of both eddy viscosity and Reynolds stress models are evaluated relative to an established experimental test case. The impact of Reynolds number and impinging shock strength are also considered. Of the eddy viscosity models it was shown that the Spalart-Allmaras model is unsuitable for this complex interaction and that the k- and Reynolds stress methods both gave notably better agreement with the measured surface static pressures. Overall it was considered that the Reynolds stress method was the best model as it also provided better agreement with the measured surface flow topology. It was concluded that, although a steady Reynolds averaged Navier Stokes approach has known limitations for this type of complex interaction, within an engineering context it can also provide useful results when applied appropriately.
Highlights
The topic of shock boundary layer interactions (SBLI) is a broad subject which has been the focus of extensive research over many years
The various turbulence models provide a range of results for the cylinder boundary layer at the position ahead of the SBLI
A shock–boundary layer interaction test case based on the complex configuration of planar oblique wave impinging onto the curved surface of a prismatic cylinder was computationally investigated
Summary
The topic of shock boundary layer interactions (SBLI) is a broad subject which has been the focus of extensive research over many years. For an aerofoil under high transonic conditions, a normal shock wave can form and interact with the boundary layer, typically on the suction side (Babinsky & Harvey, 2011). In this interaction, compression waves form near the wall as the boundary layer is unable to support the rise in static pressure across the shock. Further instances of nominally two-dimensional SBLIs have been investigated extensively, most notably for compression ramps and oblique shocks impinging on flat plates where it has been noted that the interaction depends on the nominal pressure rise across the shock as well as the state and characteristics of the approaching boundary layer (Arnal & Délery, 2004; Délery, Marvin, & Reshotko, 1986; Délery, & Coet, 1990; Délery, 1996). In nominally two-dimensional SBLIs, shock strength and angle, dependant on Mach number and geometry, along
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