On the uncertainty of CFD in sail aerodynamics

Viola, Ignazio Maria; Bot, Patrick; Riotte, M.

doi:10.1002/fld.3780

Cited by 23 publications

(17 citation statements)

References 18 publications

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“…31 This method was initially developed for yacht sail aerodynamics, but it can be applied to any other application. The method is as follows: the 95% confidence interval of any computed value φ num (in this paper, φ num is either L or C D ) is given by φ num ±U num φ num , where the numerical uncertainty U num is the sum of the uncertainties due to the grid (U g ) and the iterative convergence (U c ),…”

Section: Verificationmentioning

confidence: 99%

The effect of permeability on the flow past permeable disks at low Reynolds numbers

et al. 2017

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The viscous flow over a thick permeable circular disk in the Reynolds number (Re) range of 10 to 130 and in the Darcy number (Da) range of 10−9 to 1 is examined. Direct numerical simulations are performed on a 2D grid with axisymmetric boundary conditions. Three flow regimes are observed: I, II, and III. In regime I (effectively impervious; Da<10−6), the wake is characterized by the presence of a toroidal vortex whose length is approximately equal to that of an impervious disk. In regime II (transition; 10−6<Da<10−3), the increase in Da causes the vortex to shorten and move downstream and eventually vanishes at a critical Darcy number Dac. Regime III (Da>10−3) is the highly permeable regime, in which there is no recirculation. In I, good agreement with existing experimental data for impervious disks is found. In III, an analytical expression for the drag force on the disk is derived, showing good agreement with the numerical results. A global upper limit of Dac=Damax above which the disk is unable to maintain a recirculating wake for any Re is identified. Finally, in regime II, it is demonstrated that increasing the permeability can lead to large variations in the length of the recirculating wake but with minimal effect on the drag coefficient even when Da>Damax. This has important implications in our understanding of the locomotive strategies adopted by organisms that use porous bodies for movement.

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Section: Verificationmentioning

confidence: 99%

The effect of permeability on the flow past permeable disks at low Reynolds numbers

et al. 2017

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“…The numerical uncertainty for the simulations performed in this research is quantified using the method proposed by Viola et al [52]. The baseline parameter set of aerodynamic and structural system parameters introduced in sec.…”

Section: Verificationmentioning

confidence: 99%

On the nonlinear dynamics of self-sustained limit-cycle oscillations in a flapping-foil energy harvester

Wang

Ramesh

Killen

et al. 2018

Journal of Fluids and Structures

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The nonlinear dynamics of an airfoil at Reynolds number Re = 10, 000 constrained by two springs and subject to a uniform oncoming flow is studied numerically. The studies are carried out using open source computational fluid dynamics toolbox OpenFOAM. Under certain conditions related to aerodynamic flutter, this two-degree-of-freedom system undergoes self-sustained limit-cycle oscillations (LCOs) with potential application as an energy harvester. When the system is given a small initial perturbation, it is seen that the response of the system decays to zero at flow velocities below the flutter velocity, or oscillates in a limit cycle at velocities greater than the flutter velocity. The flutter velocity at Re = 10, 000 is shown to deviate significantly from the theoretical prediction (which is derived with an assumption of infinite Reynolds number) owing to the effect of viscosity. The LCOs at freestream velocities higher than the flutter velocity result in unsteady flows that are heavily influenced by leading-edge vortex shedding as well as trailing-edge flow separation. The influence of different system parameters

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“…The modeling error results from the use of simplified model to consider the effect of real flow physics, such as turbulence model, wall function, and so on. Meanwhile, the numerical error is due to discrete nature of the numerical model, such as grid, time steps, convergence, digits, and so on (Viola et al, 2013).…”

Section: Grid Converge Studymentioning

confidence: 99%

Surrogate model based design optimization of multiple wing sails considering flow interaction effect

Lee

et al. 2016

Ocean Engineering

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On the uncertainty of CFD in sail aerodynamics

Cited by 23 publications

References 18 publications

The effect of permeability on the flow past permeable disks at low Reynolds numbers

The effect of permeability on the flow past permeable disks at low Reynolds numbers

On the nonlinear dynamics of self-sustained limit-cycle oscillations in a flapping-foil energy harvester

Surrogate model based design optimization of multiple wing sails considering flow interaction effect

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