Turbulence cascade model for viscous vortex ring-tube reconnection

Duong, Viet Dung; Nguyen, Van Duc; Nguyen, Van Luc

doi:10.1063/5.0040952

Cited by 12 publications

(4 citation statements)

References 50 publications

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“…The particle core size is defined as 1/275 at Re =1000, as referred to references. 31,[48][49][50] As shown in Figure 3, the vorticity contours of the present results qualitatively agree well with those of reference for three angles of attack. In particular, the sizes of the leading-and trailing-edge vortices of the present work coincide with those of reference.…”

Section: Computation Setupsupporting

confidence: 88%

Low order modeling of dynamic stall using vortex particle method and dynamic mode decomposition

Nguyen

Duong

Trinh

et al. 2023

International Journal of Micro Air Vehicles

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Low order modelings are performed in this paper, including iterative Brinkman penalized vortex method (IBVM) and data-driven dynamic mode decomposition (DMD) for dynamic stall study of symmetric airfoil. The data are extracted from IBVM as input for flow field reconstruction using combinations of DMD dominant modes, representing extracted flow features. The primary mode together with its harmonics, and the mean mode are termed to be dominant for the airfoil wake duplication at fixed angles of attack ([Formula: see text]) ranging from [Formula: see text] to [Formula: see text]. For the dynamic stall duplication, at small and large pitching amplitudes, the nearfield and farfield vorticty contours from the DMD generally agree well with those from the IBVM. In addition, the lift coefficient from the DMD collapses well with that from the IBVM and the experiment.

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Section: Computation Setupsupporting

confidence: 88%

Low order modeling of dynamic stall using vortex particle method and dynamic mode decomposition

Nguyen

Duong

Trinh

et al. 2023

International Journal of Micro Air Vehicles

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“…2021), mixing from the interaction of a shock wave with a material interface (Zabusky 1999; Zhou 2017 a , b ; Wadas & Johnsen 2020) and turbulent transition (Zhou et al. 1999; Duong, Nguyen & Nguyen 2021; Yao & Hussain 2022). Understanding the dynamics of isolated or a small number of vortices is essential for successful operation of engineering applications in propulsion and energy generation (Saffman 1995) and elucidates naturally occurring flows involving, for example, jellyfish mobility (Dabiri 2009; Nawroth et al.…”

Section: Introductionmentioning

confidence: 99%

On the stability of a pair of vortex rings

Wadas,

Balakrishna,

LeFevre

et al. 2024

J. Fluid Mech.

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The growth of perturbations subject to the Crow instability along two vortex rings of equal and opposite circulation undergoing a head-on collision is examined. Unlike the planar case for semi-infinite line vortices, the zero-order geometry of the flow (i.e. the ring radius, core thickness and separation distance) and by extension the growth rates of perturbations vary in time. The governing equations are therefore temporally integrated to characterize the perturbation spectrum. The analysis, which considers the effects of ring curvature and the distribution of vorticity within the vortex cores, explains several key flow features observed in experiments. First, the zero-order motion of the rings is accurately reproduced. Next, the predicted emergent wavenumber, which sets the number of secondary vortex structures emerging after the cores come into contact, agrees with experiments, including the observed increase in the number of secondary structures with increasing Reynolds number. Finally, the analysis predicts an abrupt transition at a critical Reynolds number to a regime dominated by a higher-frequency, faster-growing instability mode that may be consistent with the experimentally observed rapid generation of a turbulent puff following the collision of rings at high Reynolds numbers.

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“…There has been many vortex method researches leading to challenging applications in fluid dynamics, such as hydrodynamics, 5 flow mediated transport, 6 dynamics of rotorcrafts’ turbulent wake, 7 vertical axis wind turbines, 8 aeroacoustics, 9 free jet, 10 flow controls, 11 and vortex reconnection in viscous fluids. 12 In the Lagrangian vortex method, the velocity is computed using the unbounded Green’s function, namely Biot-Savart formulation. Since the formulation is direct summation of individual particles within the unbounded domain, the cost is polynomially increased to N2 operations, where N is the particle number.…”

Section: Introductionmentioning

confidence: 99%

Vortex particle method with iterative Brinkman penalization for simulation of flow past sharp-shape bodies

Duong

Zuhal

2022

International Journal of Micro Air Vehicles

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This paper presents a Lagrangian vortex method combined with iterative Brinkman penalization for the simulation of incompressible flow past a complex geometry. In the proposed algorithm, particle and penalization domains are separately introduced. The particle domain is for the computation of particle convection and diffusion, while the penalization domain is the enforcement of the wall boundary conditions. In iterative Brinkman penalization, the no-slip boundary condition is enforced by applying penalization force in multiple times within each time step. This enables large time step size reducing computational cost and maintains the capability in handling complex geometries. The method is validated for benchmark problems such as an impulsively started flow past a circular cylinder, normal to a flat plate, and a symmetric airfoil at Reynolds numbers ranging from 550 to 1000. The vorticity and streamline contours, drag, and lift coefficients show a good agreement with those reported in literature.

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Turbulence cascade model for viscous vortex ring-tube reconnection

Cited by 12 publications

References 50 publications

Low order modeling of dynamic stall using vortex particle method and dynamic mode decomposition

Low order modeling of dynamic stall using vortex particle method and dynamic mode decomposition

On the stability of a pair of vortex rings

Vortex particle method with iterative Brinkman penalization for simulation of flow past sharp-shape bodies

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