Predicting Maximum Lift Coefficient for Twisted Wings Using Lifting-Line Theory

Solutions obtained from lifting-line, vortex-lattice, and the Euler equations are presented for a series of rigid, thin wing and sail geometries. Initial calculations were performed for an untwisted, rectangular wing. For this case, lifting line theory, vortex lattice, and Euler solutions were all in reasonable agreement. However, the lifting-line theory was the only method to predict a constant ratio of induced drag coefficient to lift coefficient squared. Similar results were found for a forward-swept, tapered wing. Additional results are presented in terms of lift and drag coefficients for an isolated mainsail, and mainsail/jib combinations with sails representative of both a standard and tall rig Catalina 27. Although experimental data is lacking, overall conclusions are that the accuracy realized from lifting-line solutions is as good as or better than that obtained from vortex-lattice solutions and inviscid CFD solutions, but at a fraction of the computational cost. The linear lifting-line results compared quite well with the nonlinear lifting-line results, with the exception of the downstream mainsail when considering jib/mainsail combinations.

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Predicting Maximum Lift Coefficient for Twisted Wings Using Lifting-Line Theory

Journal of Aircraft ◽

10.2514/1.25640 ◽

2007 ◽

Vol 44 (3) ◽

pp. 898-910 ◽

Cited By ~ 27

Author(s):

W. F. Phillips ◽

N. R. Alley

Keyword(s):

Lift Coefficient ◽

Line Theory ◽

Lifting Line ◽

Lifting Line Theory

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Prediction of Lift Coefficient for Tandem Wing Configuration or Multiple-Lifting-Surface System Using Prandtl’s Lifting-Line Theory

International Journal of Aerospace Engineering ◽

10.1155/2018/3104902 ◽

2018 ◽

Vol 2018 ◽

pp. 1-15 ◽

Cited By ~ 1

Author(s):

Hao Cheng ◽

Hua Wang

Keyword(s):

Numerical Solutions ◽

Hind Wing ◽

Incidence Angle ◽

Lift Coefficient ◽

Design Parameters ◽

Lifting Surface ◽

Surface System ◽

Line Theory ◽

Lifting Line ◽

Lifting Line Theory

In tandem airfoil configuration or multiple-lifting-surface layouts, due to the flow interaction among their lifting surfaces, the aerodynamic characteristics can be affected by each other. In accordance with Prandtl’s classical lifting-line theory, a method to calculate the section lift coefficient for the tandem wing configuration or multiple-lifting-surface system is presented. In that method, the form of Fourier sine series is used to express the variation of the section circulation which changes continuously along the wingspan. The accuracy of the numerical solutions obtained by the method has been validated by the data obtained from computational fluid dynamics and tunnel experiment. By varying the design parameters, such as the gap, the stagger, the incidence angle, the wingspan, the taper ratio as well as the aspect ratio, a series of tandem wing configurations are tested to analyze the lift coefficient and the induced drag of each lifting surface. From the results, it can be seen that the bigger negative gap and stagger can produce better lift characteristic for tandem wing configuration. Besides, it will also be beneficial for the lift characteristic when the incidence angle and the wingspan of fore wing are appropriately declined or if the incidence angle and the wingspan of hind wing are appropriately increased.

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Finite Wing Lift-Curve Slope Calculations Using Lifting-Line Theory

23rd AIAA Applied Aerodynamics Conference ◽

10.2514/6.2005-4839 ◽

2005 ◽

Cited By ~ 1

Author(s):

David Bridges

Keyword(s):

Line Theory ◽

Lift Curve ◽

Finite Wing ◽

Lifting Line ◽

Lifting Line Theory

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An improved nonlinear lifting-line theory.

AIAA Journal ◽

10.2514/3.6819 ◽

1973 ◽

Vol 11 (5) ◽

pp. 739-742 ◽

Cited By ~ 10

Author(s):

CHUAN-TAU LAN

Keyword(s):

Line Theory ◽

Lifting Line ◽

Lifting Line Theory

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A comprehensive comparative investigation of the Lifting Line Theory and Blade Element Momentum Theory applied to small wind turbines

Journal of Energy Resources Technology ◽

10.1115/1.4053066 ◽

2021 ◽

pp. 1-25

Author(s):

K.A.R. Ismail ◽

Willian Okita

Keyword(s):

Wind Turbines ◽

Power Coefficient ◽

Computational Time ◽

Local Flow ◽

Small Wind Turbines ◽

Wake Effects ◽

Line Theory ◽

Lifting Line ◽

Lifting Line Theory ◽

Blade Element

Abstract Small wind turbines are adequate for electricity generation in isolated areas to promote local expansion of commercial activities and social inclusion. Blade element momentum (BEM) method is usually used for performance prediction, but generally produces overestimated predictions since the wake effects are not precisely accounted for. Lifting line theory (LLT) can represent the blade and wake effects more precisely. In the present investigation the two methods are analyzed and their predictions of the aerodynamic performance of small wind turbines are compared. Conducted simulations showed a computational time of about 149.32 s for the Gottingen GO 398 based rotor simulated by the BEM and 1007.7 s for simulation by the LLT. The analysis of the power coefficient showed a maximum difference between the predictions of the two methods of about 4.4% in the case of Gottingen GO 398 airfoil based rotor and 6.3% for simulations of the Joukowski J 0021 airfoil. In the case of the annual energy production a difference of 2.35% is found between the predictions of the two methods. The effects of the blade geometrical variants such as twist angle and chord distributions increase the numerical deviations between the two methods due to the big number of iterations in the case of LLT. The cases analyzed showed deviations between 3.4% and 4.1%. As a whole, the results showed good performance of both methods; however the lifting line theory provides more precise results and more information on the local flow over the rotor blades.

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