A discontinuous Galerkin‐based sharp‐interface method to simulate three‐dimensional compressible two‐phase flow |
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| Authors: | S. Fechter C.‐D. Munz |
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| Affiliation: | Institute of Aerodynamics and Gas Dynamics, University of Stuttgart, Stuttgart, Germany |
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| Abstract: | A numerical method for the simulation of compressible two‐phase flows is presented in this paper. The sharp‐interface approach consists of several components: a discontinuous Galerkin solver for compressible fluid flow, a level‐set tracking algorithm to follow the movement of the interface and a coupling of both by a ghost‐fluid approach with use of a local Riemann solver at the interface. There are several novel techniques used: the discontinuous Galerkin scheme allows locally a subcell resolution to enhance the interface resolution and an interior finite volume Total Variation Diminishing (TVD) approximation at the interface. The level‐set equation is solved by the same discontinuous Galerkin scheme. To obtain a very good approximation of the interface curvature, the accuracy of the level‐set field is improved and smoothed by an additional PNPM‐reconstruction. The capabilities of the method for the simulation of compressible two‐phase flow are demonstrated for a droplet at equilibrium, an oscillating ellipsoidal droplet, and a shock‐droplet interaction problem at Mach 3. Copyright © 2015 John Wiley & Sons, Ltd. |
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| Keywords: | DNS discontinuous Galerkin compressible multiphase flow sharp‐interface resolution ghost‐fluid method |
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