A triangle-based unstructured finite-volume method is developed for chemically reactive hypersonic calculations. The method is based on a Steger-Warming fluxvector splitting approach generalized to mixtures of thermally perfect gases. Second-order-in-space and time accuracy is provided by limited flux blending and an implicit multi-stage time marching scheme. The final stiff non-linear problem resulting from discretization presents a very peculiar block diagonal structure. This allows a decoupling of the species and gas dynamic equations in smaller subproblems. A linear algebra argument based on M-matrix theory makes it possible also to show that the method guarantees positivity of species mass densities and vibrational energies under a reasonable CFL-like constraint. Finally, a set of 2-D numerical test cases illustrates the performance of the method.
A triangle-based unstructured finite-volume method for chemically reactive hypersonic flows
G Manzini
2001
Abstract
A triangle-based unstructured finite-volume method is developed for chemically reactive hypersonic calculations. The method is based on a Steger-Warming fluxvector splitting approach generalized to mixtures of thermally perfect gases. Second-order-in-space and time accuracy is provided by limited flux blending and an implicit multi-stage time marching scheme. The final stiff non-linear problem resulting from discretization presents a very peculiar block diagonal structure. This allows a decoupling of the species and gas dynamic equations in smaller subproblems. A linear algebra argument based on M-matrix theory makes it possible also to show that the method guarantees positivity of species mass densities and vibrational energies under a reasonable CFL-like constraint. Finally, a set of 2-D numerical test cases illustrates the performance of the method.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
