Abstract
Blunt-body configurations are the most common geometries adopted for non-lifting re-entry vehicles. Hypersonic re-entry vehicles experience different flow regimes during flight due to drastic changes in atmospheric density. The conventional Navier-Stokes-Fourier equations with no-slip and no-jump boundary conditions may not provide accurate information regarding the aerothermodynamic properties of blunt-bodies in flow regimes away from the continuum. In addition, direct simulation Monte Carlo method requires significant computational resources to analyze the near-continuum flow regime. To overcome these shortcomings, the Navier-Stokes-Fourier equations with slip and jump conditions were numerically solved. A mixed-type modal discontinuous Galerkin method was employed to achieve the appropriate numerical accuracy. The computational simulations were conducted for different blunt-body configurations with varying freestream Mach and Knudsen numbers. The results show that the drag coefficient decreases with an increased Mach number, while the heat flux coefficient increases. On the other hand, both the drag and heat flux coefficients increase with a larger Knudsen number. Moreover, for an Apollo-like blunt-body configuration, as the flow enters into non-continuum regimes, there are considerable losses in the lift-to-drag ratio and stability.
Highlights
Blunt-body configurations are considered to be the most common choice for re-entry vehicles because of their ability to generate a high drag with reduced aerodynamic heating [1, 2]
This study investigates near-continuum gas flow over various blunt-bodies using the NSF equations with slip and jump conditions based on the mixed modal discontinuous Galerkin (DG) method
2.3 Discontinuous Galerkin method The governing equations (Eq (10)) are discretized over the computational domain using a mixed modal DG method based on the Bassi and Rebay formulation [26]
Summary
Blunt-body configurations are considered to be the most common choice for re-entry vehicles because of their ability to generate a high drag with reduced aerodynamic heating [1, 2]. In the DG method, shape functions are chosen so that both the field variable and its derivatives are considered discontinuous across the element boundaries, while the overall continuity of the computational domain is ensured [23, 24]. This feature avoids the need to assemble a computationally expensive global matrix, which is in contrast with the continuous Galerkin method [25]. This study investigates near-continuum gas flow over various blunt-bodies using the NSF equations with slip and jump conditions based on the mixed modal DG method.
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