1993
DOI: 10.2514/3.46393
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Unsteady wing surface pressures in the wake of a propeller

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Cited by 27 publications
(13 citation statements)
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“…On the retreating side (Y∕R > 0), on the other hand, the slipstream was subjected to a displacement toward the propeller axis. These spanwise displacements of the propeller slipstream on the pylon surface have been discussed previously in literature [11,16,[37][38][39] and are caused by the variations in lift along the pylon span. The swirl and the increased dynamic pressure in the slipstream cause a local increase in lift on the part of the pylon inside the slipstream compared to the part of the pylon outside of the slipstream.…”
Section: Propeller-slipstream Deformation Caused By the Pylonmentioning
confidence: 79%
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“…On the retreating side (Y∕R > 0), on the other hand, the slipstream was subjected to a displacement toward the propeller axis. These spanwise displacements of the propeller slipstream on the pylon surface have been discussed previously in literature [11,16,[37][38][39] and are caused by the variations in lift along the pylon span. The swirl and the increased dynamic pressure in the slipstream cause a local increase in lift on the part of the pylon inside the slipstream compared to the part of the pylon outside of the slipstream.…”
Section: Propeller-slipstream Deformation Caused By the Pylonmentioning
confidence: 79%
“…Apart from the modification of the time-averaged wing loading, the periodic impingement of the wakes and tip vortices of the propeller blades on the wing also results in a time-varying loading component. This loading is periodic at the blade-passage frequency and its harmonics, as shown by the experimental studies by Ljunggren et al [15] and Johnston and Sullivan [16]. The locally increased turbulence levels in the slipstream [18] will also lead to periodic laminar-to-turbulent transition on the downstream element [19,20], introducing additional load fluctuations.…”
Section: Introductionmentioning
confidence: 92%
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“…The shedding of vorticity associated with the spanwise lift gradient also introduces velocities in the spanwise direction ( Figs. 15b and c), which distort the propeller slipstream during and after its interaction with the wing [8,13,21]. The resulting spanwise shearing of the slipstream is visualized in Fig.…”
Section: Wing Performancementioning
confidence: 99%
“…The spanwise shearing of the slipstream modifies the local wing performance near the slipstream edge. Although this especially affects the unsteady lift and drag response [13,21], also the time-averaged wing loading is altered. This can be seen in Fig.…”
Section: Wing Performancementioning
confidence: 99%