Improved Flux Formulations for Unsteady Low Mach Number Flows

Sachdev, Jai; Hosangadi, Ashvin; Sankaran,

doi:10.2514/6.2012-3067

Cited by 15 publications

(43 citation statements)

References 13 publications

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“…A particular problem with the AUSM + -up method is that the damping by the pressure difference term in the mass flux expression which is appropriate for steady low Mach number flow is too high for propagation of smooth acoustic signals in unsteady low Mach number flows. On the other hand, as observed by Sachdev et al [19], the dissipation is too low for propagation of acoustic discontinuities (low Mach number Riemann problems). So, it becomes very delicate to tune the pressure dissipation such that it functions properly for the different types of low Mach number flows.…”

Section: Introductionmentioning

confidence: 86%

“…However, we noted that the quality of the momentum interpolation, if properly defined for unsteady calculations in a Rhie-Chow-like manner (see [15][16][17]), was not reached for some tests at low Mach number. Improvement of predictions for unsteady low Mach number flows by the AUSM + -up scheme and the related SLAU scheme (Simple Low Dissipative AUSM) by introduction of Strouhal number dependence in the coefficient of the pressure dissipation term in the mass flux expression was also obtained by Sachdev et al [19]. These authors demonstrated that the scaling of the coupling coefficient has to be quite different for steady low Mach number problems and for unsteady low Mach number problems.…”

Section: Introductionmentioning

confidence: 89%

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Godunov-type schemes with an inertia term for unsteady full Mach number range flow calculations

Moguen

Delmas

Perrier

et al. 2015

Journal of Computational Physics

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International audienceAn inertia term is introduced in the AUSM+-up scheme. The resulting scheme, called AUSM-IT (IT for Inertia Term), is designed as an extension of the AUSM+-up scheme allowing for full Mach number range calculations of unsteady flows including acoustic features. In line with the continuous asymptotic analysis, the AUSM-IT scheme satisfies the conservation of the discrete linear acoustic energy at first order in the low Mach number limit. Its capability to properly handle low Mach number unsteady flows, that may include acoustic waves or discontinuities, is numerically illustrated. The approach for building the AUSM-IT scheme from the AUSM+-up scheme is applicable to any other Godunov-type scheme

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Section: Introductionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 89%

Godunov-type schemes with an inertia term for unsteady full Mach number range flow calculations

Moguen

Delmas

Perrier

et al. 2015

Journal of Computational Physics

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“…Originally, Venkateswaran and Merkle [8] proposed an unsteady preconditioning mechanism for implicit and dual-time stepping methods in which an unsteady Mach number is added to the low-speed preconditioner (LSP). Potsdam et al [33] have presented an improvement for unsteady scaling of the preconditioning matrix while more recently, Sachdev et al [34] have extended the work of Potsdam et al [33] to utilize the mixed unsteady and steady preconditioning parameter. The basic idea is that an unsteady Mach number scaling is added to the controlling parameter of the LSP such that…”

Section: Preconditioning Control Parametermentioning

confidence: 99%

A fully coupled turbulent low-speed preconditioner for harmonic balance applications

Djeddi

Howison

Ekici

2016

Aerospace Science and Technology

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Aeromechanical design of wind turbines requires a high-fidelity analysis toolbox that can cover a wide spectrum of flow speeds from incompressible to compressible flow regimes. As it is known, the convergence of the compressible densitybased flow solvers is deteriorated when the flow lies in an essentially incompressible regime due to the disparity between the eigenvalues of the flux Jacobian matrices. This problem is usually resolved using a low-speed preconditioner that can balance the eigenvalues, thus alleviating the convergence issues in the densitybased flow solver. In this paper, a low-speed preconditioner that fully couples the Reynolds-averaged Navier-Stokes equations with the one equation Spalart-Allmaras turbulence model is developed for steady as well as unsteady flows. The preconditioner incorporates the working variable of the turbulence model into the formulation, thus resulting in balanced artificial dissipation terms and modified local time-steps to ensure convergence acceleration for the compressible flow solver. The preconditioner is first applied to a set of two-dimensional steady flow cases to assess the convergence acceleration. This new preconditioner is further enhanced with an unsteady limiter that improves the convergence of the harmonic balance solver used for the simulation of unsteady periodic flows such as those that arise in wind turbine applications. Although the CPU time per iteration is increased by about 9%-11%, the present preconditioner is capable of reducing the number of required iterations by about 50%-60% in order to achieve the same level of accuracy as with the non-preconditioned solver.

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“…On the other hand, schemes like the convective upwind and split pressure (CUSP) [20,21] and the advection upwind split method (AUSM) [22] decompose the flux into convective (or advective) and pressure fluxes. CUSP and AUSM schemes have also been extended to low Mach number flows using preconditioning [1,17,[24][25][26][27]. The CUSP scheme behavior depends on the local Mach number.…”

Section: Introductionmentioning

confidence: 99%

“…The AUSM scheme is based on the same principles but differs in the implementation of the dissipation term [23]. CUSP and AUSM schemes have also been extended to low Mach number flows using preconditioning [1,17,[24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Development of the generalized MacCormack scheme and its extension to low Mach number flows

Gallagher

Akiki

Menon

et al. 2017

Numerical Methods in Fluids

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Summary The low Mach number performance of the MacCormack scheme is examined. The inherent dissipation in the scheme is found to suffer from the degradation in accuracy observed with traditional, density‐based methods for compressible flows. Two specific modifications are proposed, leading to the formation of the generalized MacCormack scheme within a dual‐time framework (called GMC‐PC). The first modification involves reformulating the flux by splitting it into particle convection and acoustic parts, with the former terms treated using the traditional MacCormack discretization and the latter terms augmented by the addition of a pressure‐based artificial dissipation. The second modification involves a reformulation of the traditional nonlinear fix introduced by MacCormack in 1971, which is found to be necessary to suppress pressure oscillations at low Mach numbers. The new scheme is demonstrated to have superior performance, independent of Mach number, compared with standard MacCormack implementations using several canonical test problems. Copyright © 2017 John Wiley & Sons, Ltd.

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Improved Flux Formulations for Unsteady Low Mach Number Flows

Cited by 15 publications

References 13 publications

Godunov-type schemes with an inertia term for unsteady full Mach number range flow calculations

Godunov-type schemes with an inertia term for unsteady full Mach number range flow calculations

A fully coupled turbulent low-speed preconditioner for harmonic balance applications

Development of the generalized MacCormack scheme and its extension to low Mach number flows

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