Pressure field of a rotating square plate with application to windborne debris

P. Martinez-Vazquez; M. Sterling; C.J. Baker; A.D. Quinn; B. Kakimpa; J.S. Owen; P.J. Richards

Pressure field of a rotating square plate with application to windborne debris

P. Martinez-Vazquez, M. Sterling, C.J. Baker, A.D. Quinn, B. Kakimpa, J.S. Owen, P.J. Richards

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Traditionally, a quasi steady response concerning the aerodynamic force and moment coefficients acting on a flat plate while 'flying' through the air has been assumed. Such an assumption has enabled the flight paths of windborne debris to be predicted and an indication of its potential damage to be inferred. In order to investigate this assumption in detail, a series of physical and numerical simulations relating to flat plates subject to autorotation has been undertaken. The physical experiments have been carried out using a novel pressure acquisition technique which provides a description of the pressure distribution on a square plate which was allowed to auto-rotate at different speeds by modifying the velocity of the incoming flow. The current work has for the first time, enabled characteristic pressure signals on the surface of an auto-rotating flat plate to be attributed to vortex shedding.

Original language	English
Pages (from-to)	509-529
Number of pages	21
Journal	Wind and Structures
Volume	15
Issue number	6
Publication status	Published - 1 Nov 2012

Cite this

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AU - Martinez-Vazquez, P.

AU - Sterling, M.

AU - Baker, C.J.

AU - Quinn, A.D.

AU - Kakimpa, B.

AU - Owen, J.S.

AU - Richards, P.J.

PY - 2012/11/1

Y1 - 2012/11/1

N2 - Traditionally, a quasi steady response concerning the aerodynamic force and moment coefficients acting on a flat plate while 'flying' through the air has been assumed. Such an assumption has enabled the flight paths of windborne debris to be predicted and an indication of its potential damage to be inferred. In order to investigate this assumption in detail, a series of physical and numerical simulations relating to flat plates subject to autorotation has been undertaken. The physical experiments have been carried out using a novel pressure acquisition technique which provides a description of the pressure distribution on a square plate which was allowed to auto-rotate at different speeds by modifying the velocity of the incoming flow. The current work has for the first time, enabled characteristic pressure signals on the surface of an auto-rotating flat plate to be attributed to vortex shedding.

AB - Traditionally, a quasi steady response concerning the aerodynamic force and moment coefficients acting on a flat plate while 'flying' through the air has been assumed. Such an assumption has enabled the flight paths of windborne debris to be predicted and an indication of its potential damage to be inferred. In order to investigate this assumption in detail, a series of physical and numerical simulations relating to flat plates subject to autorotation has been undertaken. The physical experiments have been carried out using a novel pressure acquisition technique which provides a description of the pressure distribution on a square plate which was allowed to auto-rotate at different speeds by modifying the velocity of the incoming flow. The current work has for the first time, enabled characteristic pressure signals on the surface of an auto-rotating flat plate to be attributed to vortex shedding.

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Pressure field of a rotating square plate with application to windborne debris

Abstract

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