Effects of Unsteady Trailing-Edge Blowing on Delta Wing Aerodynamics

Jiang, Ping; Wang, Zhijin; Gursul, Ismet

doi:10.2514/1.45890

Cited by 12 publications

(3 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Vortex breakdown types are categorized into seven different kinds [26], three of which are more common over delta wings, spiral, double helix, and bubble type. Sarpkaya [27], [28] [11], [35] and unsteady blowing [36].…”

Section: Vortex Breakdownmentioning

confidence: 99%

Effect of thickness-to-chord ratio on aerodynamics of non-slender delta wing

Ghazijahani

Yavuz

2019

Aerospace Science and Technology

View full text Add to dashboard Cite

, 84 pages Flow characterization over delta wings have gained attention in recent decades due to their prevailing usage in designs of unmanned air vehicles (UAVs). In literature, only a few studies have reported wing thickness effect on both the aerodynamic performance and detailed flow structure over delta wings. In the present investigation, the effect of thickness-to-chord (/) ratio on aerodynamics of a non-slender delta wing with 45 degree sweep angle is characterized in a low-speed wind tunnel using laser illuminated smoke visualization, surface pressure measurements, particle image velocimetry, and force measurements. The delta wings with / ratios varying from 2 % to 15 % are tested at broad ranges of angle of attack and Reynolds number. The results indicate that the effect of / ratio on flow structure is quite substantial. Considering the low angles of attack where the wings experience leading edge vortex structure, the strength of the vortex structure increases as the / ratio increases. However, low / ratio wings have pronounced surface separations at higher angle of attack compared to the high / ratio wings. These results are well supported by the force measurements such that high / ratio wings induce higher lift coefficients, CL, at vi low angles of attack, whereas maximum CL values are higher and appear at higher angle of attack for low / ratio wings. This indicates that low / ratio wings are more resistive to the stall condition. Considering the lift-to-drag ratio, CL/CD, increase in / ratio induces remarkable drop in CL/CD values.

show abstract

Section: Vortex Breakdownmentioning

confidence: 99%

Effect of thickness-to-chord ratio on aerodynamics of non-slender delta wing

Ghazijahani

Yavuz

2019

Aerospace Science and Technology

View full text Add to dashboard Cite

show abstract

“…Ahmad 8 and Bur et al 9 have evaluated the impact of spacing between each pair of VGs in the interim. Several additional studies have investigated sub-VG, micro-VG, and blowing VG to examine their impact on flow management [10][11][12][13] . The flow behaviour above the airfoil with and without VGs has been better understood using computational fluid dynamics (CFD).…”

Section: Introductionmentioning

confidence: 99%

Numerical Analysis of Various Types of Flows Over NACA 4415 Airfoil

Sarkar,

Bangalee

2024

Dhaka Univ. J. Sci.

View full text Add to dashboard Cite

Because of the high-speed aircrafts, the distance to the other side of the world seems to be closer, as if it were situated just next door. Aerospace engineering has undergone a revolution thanks to research into airfoils. This research work has been focused on analyzing the aerodynamic performances of the NACA 4415 airfoil in turbulent flows while Mach numbers, and Reynolds numbers, have been taken into account. The chord length of and have been considered for this study. Computational fluid dynamics were employed to determine the lift, drag, and pitching moment forces, as well as their respective non-dimensional coefficients. As a result, maximum lift, moment forces have been found after the angle of attacks, and stagnation areas are increasing dramatically behind the airfoil, proportion to the increments with the angle of attack. Additionally, the effects of pressure and velocity on every point of the airfoil's surface were studied through the analysis of pressure and velocity contours. Dhaka Univ. J. Sci. 72(1): 85-91, 2024 (January)

show abstract

“…Cui et al [23] executed the forebody slot blowing over a delta wing with a 60-degree sweep angle. Jiang et al [24] carried out an experimental investigation on the effects of irregular blowing towards the trailing edge. over a delta wing with a sweep angle of 60 o .…”

Section: Introductionmentioning

confidence: 99%

Effect of Variation of Location of the Blowing on the Aerodynamic Characteristics over the Delta Wing

Gupta,

Kumar,

Kumar

2023

Preprint

View full text Add to dashboard Cite

The flow field around a delta wing is substantially altered by the impact of the active flow control technique. The present study involves the sharp-edged delta wing of 65 deg sweep angle with different active flow control configurations. The blowing was employed as an active flow control method on the airfoil surface. The various configurations considered are the baseline delta wing, delta wing with blowing holes located at 1.62%, 3.24% and 4.86% of root chord from the leading edge to the centre of the blowing holes. The computation is performed using the commercial software ANSYS Fluent. Unsteady, incompressible Reynolds-averaged Navier-Stokes equation and the shear-stress transport k-ω turbulence model are employed. The angles of attack varied in the range of 0 deg. < α < 35 deg. and Reynolds number is 2.64 x10^6 and the jet momentum coefficient is fixed at 0.05. The blowing of air from the injection region enhances the strength of the leading-edge vortices resulting in the delay of the vortex breakdown. The performance of the delta wing is greatly improved while using the blowing method specifically for the blowing holes located at 3.24% of root chord from the leading edge as compared to without the blowing method.

show abstract

Effects of Unsteady Trailing-Edge Blowing on Delta Wing Aerodynamics

Cited by 12 publications

References 27 publications

Effect of thickness-to-chord ratio on aerodynamics of non-slender delta wing

Effect of thickness-to-chord ratio on aerodynamics of non-slender delta wing

Numerical Analysis of Various Types of Flows Over NACA 4415 Airfoil

Effect of Variation of Location of the Blowing on the Aerodynamic Characteristics over the Delta Wing

Contact Info

Product

Resources

About