Proceedings ArticleDOI
A closer look at the induced drag of crescent-shaped wings
Stephen C. Smith,Ilan Kroo +1 more
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TLDR
In this paper, a high-order panel method was used to study the induced drag of crescent and elliptical wings using both techniques, and the results showed that the effect of panel density and angle of attack on induced drag was significant.Abstract:
Recent interest in the induced drag characteristics of crescent-shaped wings has led to a closer look at the methods used for determination of induced drag from computational aerodynamic methods. Induced drag may be computed by integration of surface pressure, or by evaluation of a contour integral in the Trefftz plane. A high-order panel method was used to study the induced drag of crescent and elliptical wings using both techniques. Induced drag computations using surface-pressure integration were strongly affected by panel density and angle of attack. Accurate drag computations for the crescent wing were obtained only when the spanwise as well as chordwise panel density was extremely high. Trefftz-plane results for the two wing planforms do not show this sensitivity to panel density or angle of attack. Span efficiencies of 0.994 for the crescent wing and 0.987 for the elliptical wing were computed by the Trefftz-plane technique. Substitution of a force-free, rolled-up wake geometry on the crescent wing did not change the pressure-integrated drag significantly. The slightly higher span efficiency of the crescent wing is attributed to a more nearly elliptical spanwise lift distribution. The chord distribution of the elliptical wing was modified to produce an elliptical span-loading on a wing with an unswept quarter-chord line. This wing demonstrated a span efficiency equal to that of the crescent wing.read more
Citations
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A Computational and Experimental Study of Nonlinear Aspects of Induced Drag
TL;DR: In this article, a hybrid wake-relaxation scheme couples the well-behaved nature of the discrete vortex wake with viscous-core modeling and the high-accuracy velocity prediction of the high order panel method.
Aerodynamic Comparison of Hyper-Elliptic Cambered Span (HECS) Wings with Conventional Configurations
Barry S. Lazos,Kenneth D. Visser +1 more
TL;DR: In this article, the aerodynamic and flow field characteristics of hyper-elliptic cambered span (HECS) wings were examined and compared with more conventional configurations used for induced drag reduction.
Proceedings ArticleDOI
The Computation of Induced Drag with Nonplanar and Deformed Wakes
Ilan Kroo,Stephen C. Smith +1 more
TL;DR: In this article, a detailed look at nonlinear, inviscid flow theory is presented, and it is concluded that many of the classical, linear results are more general than might have been expected.
Journal Article
Sailplane winglet design
Mark D. Maughmer,Peter Kunz +1 more
TL;DR: In this article, an improved methodology for winglet design has been developed, incorporating a detailed component drag buildup that includes the ability to interpolate input airfoil drag and moment data across operational lift coefficient, Reynolds number, and flap-setting ranges.
References
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Journal ArticleDOI
Prediction of Subsonic Aerodynamic Characteristics: A Case for Low-Order Panel Methods
TL;DR: In this paper, a low-order panel method is presented for the calculation of subsonic aerodynamic characteristics of general configurations, based on piecewise constant doublet and source singularities.
Journal ArticleDOI
On Calculation of Induced Drag and Conditions Downstream of a Lifting Wing
TL;DR: In this paper, the velocity at the outer edge of the bottom plate is estimated by a Bound-Ary layer type approximation with a velocity distribution given by the velocity distribution on the bottom surface.
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