An adaptive high-order hybrid scheme for compressive, viscous flows with detailed chemistry
An adaptive high-order hybrid scheme for compressive, viscous flows with detailed chemistry
A hybrid weighted essentially non-oscillatory (WENO)/centered-difference numerical method, with low numerical dissipation, high-order shock-capturing, and structured adaptive mesh refinement (SAMR), has been developed for the direct numerical simulation of the multicomponent, compressible, reactive Navier–Stokes equations. The method enables accurate resolution of diffusive processes within reaction zones. The approach combines time-split reactive source terms with a high-order, shock-capturing scheme specifically designed for diffusive flows. A description of the order-optimized, symmetric, finite difference, flux-based, hybrid WENO/centered-difference scheme is given, along with its implementation in a high-order SAMR framework. The implementation of new techniques for discontinuity flagging, scheme-switching, and high-order prolongation and restriction is described. In particular, the refined methodology does not require upwinded WENO at grid refinement interfaces for stability, allowing high-order prolongation and thereby eliminating a significant source of numerical diffusion within the overall code performance. A series of one-and two-dimensional test problems is used to verify the implementation, specifically the high-order accuracy of the diffusion terms. One-dimensional benchmarks include a viscous shock wave and a laminar flame. In two-space dimensions, a Lamb–Oseen vortex and an unstable diffusive detonation are considered, for which quantitative convergence is demonstrated. Further, a two-dimensional high-resolution simulation of a reactive Mach reflection phenomenon with diffusive multi-species mixing is presented.
weighted essentially non-oscillatory, detonation, adaptive mesh refinement, navier–stokes, direct numerical simulation, reacting compressible flow
7598-7630
Ziegler, J.L.
4b9c77fd-d615-4cef-81cd-3424e7dbf8fb
Deiterding, R.
ce02244b-6651-47e3-8325-2c0a0c9c6314
Shepherd, J.E.
f6315474-4e98-43a9-915c-6be4f539326e
Pullin, D.I.
920b5885-0adb-4bcd-985a-fbf537b9782d
20 August 2011
Ziegler, J.L.
4b9c77fd-d615-4cef-81cd-3424e7dbf8fb
Deiterding, R.
ce02244b-6651-47e3-8325-2c0a0c9c6314
Shepherd, J.E.
f6315474-4e98-43a9-915c-6be4f539326e
Pullin, D.I.
920b5885-0adb-4bcd-985a-fbf537b9782d
Ziegler, J.L., Deiterding, R., Shepherd, J.E. and Pullin, D.I.
(2011)
An adaptive high-order hybrid scheme for compressive, viscous flows with detailed chemistry.
Journal of Computational Physics, 230 (20), .
(doi:10.1016/j.jcp.2011.06.016).
Abstract
A hybrid weighted essentially non-oscillatory (WENO)/centered-difference numerical method, with low numerical dissipation, high-order shock-capturing, and structured adaptive mesh refinement (SAMR), has been developed for the direct numerical simulation of the multicomponent, compressible, reactive Navier–Stokes equations. The method enables accurate resolution of diffusive processes within reaction zones. The approach combines time-split reactive source terms with a high-order, shock-capturing scheme specifically designed for diffusive flows. A description of the order-optimized, symmetric, finite difference, flux-based, hybrid WENO/centered-difference scheme is given, along with its implementation in a high-order SAMR framework. The implementation of new techniques for discontinuity flagging, scheme-switching, and high-order prolongation and restriction is described. In particular, the refined methodology does not require upwinded WENO at grid refinement interfaces for stability, allowing high-order prolongation and thereby eliminating a significant source of numerical diffusion within the overall code performance. A series of one-and two-dimensional test problems is used to verify the implementation, specifically the high-order accuracy of the diffusion terms. One-dimensional benchmarks include a viscous shock wave and a laminar flame. In two-space dimensions, a Lamb–Oseen vortex and an unstable diffusive detonation are considered, for which quantitative convergence is demonstrated. Further, a two-dimensional high-resolution simulation of a reactive Mach reflection phenomenon with diffusive multi-species mixing is presented.
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Published date: 20 August 2011
Keywords:
weighted essentially non-oscillatory, detonation, adaptive mesh refinement, navier–stokes, direct numerical simulation, reacting compressible flow
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 380639
URI: http://eprints.soton.ac.uk/id/eprint/380639
ISSN: 0021-9991
PURE UUID: 546ef0cf-1931-45dc-9e22-2ca9cf215d52
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Date deposited: 09 Sep 2015 09:36
Last modified: 15 Mar 2024 03:52
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Author:
J.L. Ziegler
Author:
J.E. Shepherd
Author:
D.I. Pullin
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