Numerical dissipation of upwind schemes in low Mach flow

Thornber, Ben; Drikakis, Dimitris

doi:10.1002/fld.1628

Cited by 58 publications

(45 citation statements)

References 9 publications

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“…In other words, under sufficient condition (28) and when the initial conditions are wellprepared, PDE (26) does not create any spurious wave. At the opposite, the first point of Theorem 2.2 is not really important since estimate (27) does not mean that qðt P 0Þ is almost in the well-prepared subspace E. This first point is only mentioned to underline the importance of the invariance of E. Moreover, we underline the fact that we do not impose that the energy EðtÞ is a constant or a decreasing function (nevertheless, Eðt P 0Þ is bounded since (26) is supposed to be well-posed).…”

Section: Theoretical Derivation In the Linear Casementioning

confidence: 94%

“…In that case, estimate (50) induced by any 1D well-prepared initial condition should be replaced by the estimate p i ðs ac Þ ¼ p Ã þOðMDxÞ (see below the 2D case for the details). In fact, the formal analysis in [4,8] cannot be satisfactory because, as in [6,10], they use 1D arguments (an 1D argument is also used in [26]: see estimate (11) in [26]). As a consequence, any divergence-free field is trivial and it is impossible to clearly understand the origin of the inaccuracy of Godunov type schemes at low Mach number.…”

Section: A More Precise Formal Approach: Importance Of the Space Dimementioning

confidence: 98%

“…Proof of Theorem 2.2: Estimate (27) is a direct consequence of the well-posedness of PDE (26). Let us now define qðt; xÞ solution of (26) with the initial condition qðt ¼ 0; xÞ :¼ q 0 À Pq 0 .…”

Section: Theoretical Derivation In the Linear Casementioning

confidence: 99%

“…Moreover, the previous formal analysis (partly inspired from [6,10]) does not take into account the space dimension since it is an 1D analysis (1D arguments are also used in [4,8,26]): we will see in the sequel that the space dimension is essential to analyse Godunov type schemes at low Mach number from a formal or theoretical point of view.…”

Section: A First Formal Approachmentioning

confidence: 99%

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Analysis of Godunov type schemes applied to the compressible Euler system at low Mach number

Dellacherie¹

2010

Journal of Computational Physics

178

332

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Section: Theoretical Derivation In the Linear Casementioning

confidence: 94%

Section: A More Precise Formal Approach: Importance Of the Space Dimementioning

confidence: 98%

Section: Theoretical Derivation In the Linear Casementioning

confidence: 99%

Section: A First Formal Approachmentioning

confidence: 99%

See 2 more Smart Citations

Analysis of Godunov type schemes applied to the compressible Euler system at low Mach number

Dellacherie¹

2010

Journal of Computational Physics

178

332

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“…This low Mach number behaviour in TURMOIL is better than many Godunov methods. However, work on improving the low Mach number behaviour of Godunov methods [8] may make them well suited for calculating compressible turbulent flow.…”

Section: Low Mach Number Behaviourmentioning

confidence: 99%

Turbulent mixing in spherical implosions

Youngs

Williams

2007

Numerical Methods in Fluids

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SUMMARYWe discuss the application of the numerical code TURMOIL to turbulent mixing in a simple spherical implosion, a much simplified version of an inertial confinement fusion implosion. Some form of Monotone integrated large eddy simulation is required to eliminate non-physical oscillations, as shocks and contact discontinuities are present. The dissipation in the TURMOIL scheme is analysed. It is argued that this is relatively low and that the 'sub-grid' dissipation can be precisely quantified. q British Crown

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Implementation of all‐Mach Roe‐type schemes in fully implicit CFD solvers – demonstration for wind turbine flows

Carrion

Woodgate

Steijl

et al. 2013

Numerical Methods in Fluids

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SUMMARYThis paper presents the implementation of all‐Mach Roe‐type schemes in a fully implicit CFD solver. Simple 2D cases, such as the flow around inviscid and viscous aerofoils, were used for an initial validation of these methods, along with more challenging computations consisting of the 3D flow around the Model Experiments in Controlled Conditions wind turbine, in parked and rotating conditions. This work is motivated by the increased interest of the wind turbine industry in larger diameter wind turbines where compressibility effects near the blade tips may be important. Instead of using an incompressible flow solver, this paper explores the option of modifying an existing, efficient, compressible flow solver for use at lower Mach numbers. The good performance of the Roe solver and its popularity influenced the selection of schemes for this work. The results suggest that effective all‐Mach solutions are possible with implicit solvers, and the paper defines the implementation of the new fluxes and Jacobian, including an investigation of some numerical parameters, using as platform the Helicopter Multi‐Block solver of Liverpool University. Copyright © 2013 John Wiley & Sons, Ltd.

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Numerical dissipation of upwind schemes in low Mach flow

Cited by 58 publications

References 9 publications

Analysis of Godunov type schemes applied to the compressible Euler system at low Mach number

Analysis of Godunov type schemes applied to the compressible Euler system at low Mach number

Turbulent mixing in spherical implosions

Implementation of all‐Mach Roe‐type schemes in fully implicit CFD solvers – demonstration for wind turbine flows

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