Oil and Smoke Flow Visualization Past Two-Dimensional Airfoils for an Unmanned Aerial Vehicle

Velazquez-Araque, Luis; Nožička, Jiří

doi:10.1615/vismechproc.v1.i3.60

Cited by 1 publication

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“…Figure (9) shows the calculated and experimental pressure distributions on the standard and modified double wedge airfoils with and without blowing, at moderate and high angles of attack. The calculated and experimental results are in well agreement, with the theoretical method developing slightly less suction over the front of the airfoil.…”

Section: Resultsmentioning

confidence: 99%

Improving the Lift Characteristics of Supersonic Double 257 Wedge Airfoil at Low Speed Using Passive-Active Flow Controlling Methods

Abu-Tabikh¹,

Al-musawi²,

Khashan³

2015

ETJ

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The supersonic double wedge airfoil performs quite excellent in the supersonic speed regime but would lead to poor performance at subsonic speed regime due to sharp edges stall. For this purpose a theoretical and experimental study was undertaken to improve performance characteristics of the supersonic double wedge airfoil at low speed by using passive-active flow controlling methods. The proposed passive method was a shape modification through changing the sharp leading edge and mid-section upperand lower surface apex to smooth curved control segment actived during subsonic flight regime; and the blowing technique was used as an active method. ANSYS FLUENT CFD package was used to simulate the flow around the standard and modified airfoils. Low speed wind tunnel tests were also conducted in order to measure pressures and velocities chordal-wise the model airfoils fabricated to accomplish these wind tunnel tests.The results had proven that theproposed flow controlling methods had improved the performance of the double wedge airfoil at low speed. The maximum lift coefficient 𝐶 𝑙,𝑚𝑎𝑥 was increased by about (38%) and the stall angle for 𝐶 𝑙,𝑚𝑎𝑥 was jumped from ( 12°) for the standard airfoil to ( 18°) for the modified airfoil with blowing. The experimental results coincide well with the theoretical results.

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Section: Resultsmentioning

confidence: 99%