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Improved Heat Transfer Prediction for High-Speed Flows over Blunt Bodies using Adaptive Mixed-Element Unstructured Grids

Gabriel Nastac, Robert Tramel, Eric J. Nielsen

2022AIAA SCITECH 2022 Forum20 citationsDOI

Abstract

View Video Presentation: https://doi.org/10.2514/6.2022-0111.vid Aerothermodynamic prediction is important for the design and analysis of many aerospace vehicles. Computational Fluid Dynamics (CFD) tools used for these predictions commonly rely on structured shock-aligned grids due to the strong shocks exhibited at high speeds. This work details the incorporation of an improved HLLE++ scheme for both perfect gas and thermochemical nonequilibrium flows, which robustly captures shock waves on both non-shock-aligned and shock-aligned grids. The HLLE++ scheme reduces the impact of eigenvalue limiting on flow solutions, which is required for Roe's scheme for high Mach number flows. An adapted grid approach is also demonstrated using mixed-element unstructured grids to improve heat prediction. Thin prismatic boundary layers are used with tetrahedra in the farfield and for capturing shock waves. Various results are presented for hypersonic flows over blunt bodies including cylinders, spheres, and capsules.

Topics & Concepts

Hypersonic speedMach numberShock (circulatory)Mesh generationMechanicsComputational fluid dynamicsShock waveUnstructured gridHeat transferComputer scienceAdaptive mesh refinementGridAerospace engineeringFinite element methodPhysicsComputational scienceGeometryEngineeringMathematicsThermodynamicsInternal medicineMedicineComputational Fluid Dynamics and AerodynamicsGas Dynamics and Kinetic TheoryPlasma and Flow Control in Aerodynamics
Improved Heat Transfer Prediction for High-Speed Flows over Blunt Bodies using Adaptive Mixed-Element Unstructured Grids | Litcius