Comments on the research article by Gross<i>et al.</i>(2012)

Guntur, Srinivas; Sørensen, Niels N.

doi:10.1002/we.1674

Wind Energ.

2013

DOI: 10.1002/we.1674

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Comments on the research article by Grosset al.(2012)

Srinivas Guntur

Niels N. Sørensen

Abstract: The purpose of this Letter to the Editor is to present a discussion on the physics of rotational augmentation based on existing work. One of the latest works by Gross et al. (2012) is highlighted here, and its conclusions are discussed. Based on the existing understanding of rotational augmentation, some inconsistencies seem to be present in the analysis of Gross et al. These are identified and discussed here, along with a brief survey of relevant literature.

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2024

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Boundary layer stability on a rotating wind turbine blade section

Fava,

Henningson,

Hanifi

2024

Physics of Fluids

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Wall-resolved large eddy simulations of the flow on a rotating wind turbine blade section are conducted to study the rotation effects on laminar-turbulent transition on the suction surface. A chord Reynolds number of 1×105 and angles of attack (AoA) of 12.8°, 4.2°, and 1.2° are considered. Simulations with and without rotation are performed for each AoA. For AoA=12.8°, rotation increases the reverse flow from 7% of the free-stream velocity in the non-rotating case to 16% of it in the rotating case in the laminar separation bubble (LSB), triggering an oblique instability mechanism in the latter, leading to a faster breakdown to small-scale turbulence. However, rotation delays transition and reattachment in 3%–4% of the chord due to the acceleration of the boundary layer upstream of the LSB, which is subject to a strong adverse pressure gradient (APG), stabilizing Tollmien–Schlichting (TS) waves. Regarding AoA=4.2° and 1.2°, rotation slightly decelerates the attached boundary layer since the APG is very mild but accelerates the separated flow downstream, stabilizing Kelvin–Helmholtz (KH) modes. This mitigates the oblique instability mechanism and slows down the breakdown of KH vortices in the rotating case. In these cases, the transition location is little affected by rotation, possibly due to a rotation-independent absolute instability. Rotation also generates a spanwise tip-flow in the LSB for AoA=4.2° and 1.2°, which is highly unstable and triggers stationary and traveling crossflow modes. Nevertheless, the amplitudes of these modes remain too low to trigger transition.

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Boundary layer stability on a rotating wind turbine blade section

Fava,

Henningson,

Hanifi

2024

Physics of Fluids

View full text Add to dashboard Cite

show abstract

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Comments on the research article by Grosset al.(2012)

Cited by 1 publication

References 11 publications

Boundary layer stability on a rotating wind turbine blade section

Boundary layer stability on a rotating wind turbine blade section

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