M. Sherry scite author profile

International audienceAnalysis of the helical vortices measured behind a model wind turbine in a water channel are reported. Phase-locked measurements using planar particle image ve- locimetry are taken behind a Glauert rotor to investigate the evolution and breakdown of the helical vortex structures. Existing linear stability theory predicts helical vortex filaments to be susceptible to three unstable modes. The current work presents tip and root vortex evolution in the wake for varying tip speed ratio and shows a breaking of the helical symmetry and merging of the vortices due to mutual inductance between the vortical filaments. The merging of the vortices is shown to be steady with rotor phase, however, small-scale non-periodic meander of the vortex positions is also ob- served. The generation of the helical wake is demonstrated to be closely coupled with the blade aerodynamics, strongly influencing the vortex properties which are shown to agree with theoretical predictions of the circulation shed into the wake by the blades. The mutual inductance of the helices is shown to occur at the same non-dimensional wake distance

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An experimental investigation of the recirculation zone formed downstream of a forward facing step

Sherry

Jacono

Sheridan

2010

Journal of Wind Engineering and Industrial Aerodynamics

120

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Characterisation of a horizontal axis wind turbine’s tip and root vortices

2013

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Characterizing the lower log region of the atmospheric surface layer via large-scale particle tracking velocimetry

et al. 2014

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Air flow around the point of an arrow

Park

Hodge

Al-Mulla

et al. 2011

Proceedings of the Institution of Mechanical Engineers, Part P:

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The aerodynamic drag of an arrow is of importance in relation to the arrow’s drift in wind and to its down-range velocity. A significant contributor to that drag is the viscous drag from the arrow shaft, and consequently the nature of air flow over the arrow point and the location of the transition from laminar to turbulent flow are of interest. In this paper the flow was investigated using a scale model in a water channel for two arrow point profiles and for circumferential gaps at the rear of the arrow point. The normal ‘bullet point’ was found to have laminar flow along the front of the shaft and transition at a Reynolds number of approximately 450,000, and that circumferential gaps did not affect the flow. The frequently used ‘short bulge point’ was found to have flow separation at the rear taper of the point and turbulent flow for the full length of the shaft, which would be expected to result in greater drag than for the bullet point or for a bulge point with less aggressive rear taper.

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M. Sherry

The interaction of helical tip and root vortices in a wind turbine wake

An experimental investigation of the recirculation zone formed downstream of a forward facing step

Characterisation of a horizontal axis wind turbine’s tip and root vortices

Characterizing the lower log region of the atmospheric surface layer via large-scale particle tracking velocimetry

Air flow around the point of an arrow

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