Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-06T07:17:15.646Z Has data issue: false hasContentIssue false
  • English
  • Français

Generation Mechanism and Reduction Method of Induced Drag Produced by Interacting Wingtip Vortex System

Published online by Cambridge University Press:  14 September 2017

M. Zhang ,
Y. K. Wang  and
S. Fu
M. Zhang
Affiliation:
School of Aerospace EngineeringTsinghua UniversityBeijing, China Shanghai Aircraft Design and Research InstituteShanghai, China
Y. K. Wang
Affiliation:
School of Aeronautics and AstronauticsShanghai Jiao Tong UniversityShanghai, China
S. Fu*
Affiliation:
School of Aerospace EngineeringTsinghua UniversityBeijing, China
*
*Corresponding author ([email protected])
Get access

Abstract

The formation and evolution of wingtip vortex system generated from three wing configurations are simulated with the improved delayed detached eddy simulation (IDDES) method. Numerical results show that each layout produces an interacting wingtip vortex system. These three corresponding vortical interactions are, respectively, the interaction between wingtip vortex and its counter-rotating vortex, winglet-tip vortex, and winglet four-vortex system. The fluid entrainment of ambient fluid and vortical impulse transport resulted from inductive effect have been founded generally existing in its formation and evolution. These two dominated mechanisms account for induced drag generation. On one hand, the winglet with toed-out angle is considered capable of changing the flow field around the winglet, and decomposing the winglet-tip vortex into four small vortices. Due to quite few fluid entrainment effects, this typical four-vortex system that cannot merge and only dissipate in the near wake scarcely contributes to the induced drag. On the other hand, a potential drag reduction method is also indicated that a lower induced drag can be obtained when the merger of wingtip and winglet-tip vortex is controlled and eliminated. This investigation will offer a novel perspective to guide the design of wingtip device and method of crusing resistance reduction for aircrafts.

Keywords

Wingtip vortexInduced drag reductionGeneration mechanismVortex dynamics
Type
Research Article
Information
Journal of Mechanics , Volume 34 , Issue 2 , April 2018 , pp. 231 - 241
Copyright
Copyright © The Society of Theoretical and Applied Mechanics 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Spalart, P. R., “Airplane Trailing Vortices,” Annual Review of Fluid Mechanics, 30, pp. 107138 (1998).Google Scholar
2. Gerz, T., Holzäpfel, F. and Darracq, D., “Commercial Aircraft Wake Vortices,” Progress in Aerospace Sciences, 38, pp. 181208 (2002).Google Scholar
3. Kroo, I., “Drag Due to Lift: Concepts for Prediction and Reduction,” Annual Review of Fluid Mechanics, 33, pp. 587617 (2001).Google Scholar
4. Birch, D., Lee, T., Mokhtarian, F. and Kafyeke, F., “Structure and Induced Drag of a Tip Vortex,” Journal of Aircraft, 41, pp. 11381145 (2004).Google Scholar
5. Narayan, G. and John, B., “Effect of Winglets Induced Tip Vortex Structure on the Performance of Subsonic Wings,” Aerospace Science & Technology, 58, pp. 328340 (2016).Google Scholar
6. Michea, G. and Green, R. B., “Vortex Formation on Squared and Rounded Tip,” Aerospace Science & Technology, 29, pp. 191199 (2013).Google Scholar
7. Giuni, M., “Formation and Early Development of Wingtip Vortices,” Ph.D. Dissertation, University of Glasgow, Glasgow, U.K. (2013).Google Scholar
8. Chen, A. L., Jacob, J. D. and Savas, Ö., “Dynamics of Co-Rotating Vortex Pairs in the Wakes of Flapped Airfoils,” Journal of Fluid Mechanics, 382, pp. 155193 (1999).Google Scholar
9. Lamb, H., “Hydrodynamics,” Hydrodynamics New York Dover, 6, pp. 181185 (1932).Google Scholar
10. Allen, A. and Breitsamter, C., “Experimental Investigation of Counter-rotating Four Vortex Aircraft Wake,” Aerospace Science & Technology, 13, pp. 114129 (2009).Google Scholar
11. Devenport, J. W., “Flow Structure Produced by the Interaction and Merger of a Pair of Co-Rotating Wing-Tip Vortices,” Journal of Fluid Mechanics, 394, pp. 357377 (1999).CrossRefGoogle Scholar
12. Wang, Y. K., Qin, S. Y., Xiang, Y. and Liu, H., “Interaction Mechanism of Vortex System Generated by Large Civil Aircraft Afterbody,” Journal of Aeronautics, Astronautics and Aviation, 49, pp. 6776 (2017).Google Scholar
13. Anderson, D., J., , Fundamentals of Aerodynamics, 4th Edition, McGraw-Hill Education (Asia) and Aviation Industry Press, New York, pp. 2026 (2010).Google Scholar
14. Spalart, P. R., “On the Far Wake and Induced Drag of Aircraft,” Journal of Fluid Mechanics, 603, pp. 413430 (2008).Google Scholar
15. Chen, Z. L. and Zhang, B. Q., “Drag Prediction Method Investigation Basing on the Wake Integral,” Acta Aerodynamica Sinica, 27, pp. 330334 (2009).Google Scholar
16. ANSYS Fluent 14.0 Theory Guide, ANSYS, Inc. (2011).Google Scholar
17. Schmitt, V. and Charpin, F., “Pressure Distributions on the ONERA-M6-Wing at Transonic Mach Numbers,” Experimental Data Base for Computer Program Assessment. Report of the Fluid Dynamics Panel Working Group 04, AGARD AR 138 (1979).Google Scholar
18. Mani, M., Ladd, J. A., Cain, A. B. and Bush, R. H., “An Assessment of One- and Two-Equation Turbulence Models for Internal and External Flows,” 28th Fluid Dynamics Conference, Fluid Dynamics and Co-located Conferences, doi.org/10.2514/6.1997-2010 (1997).Google Scholar
19. Jeong, J. and Hussain, F., “On the Identification of a Vortex,” Journal of Fluid Mechanics, 285, pp. 6994 (1995).Google Scholar
20. Fu, Z. D., Liu, H., “Transient Force Augmentation Due to Counter-Rotating Vortex Ring Pairs,” Journal of Fluid Mechanics, 785, pp. 324348 (2015).Google Scholar
21. Giles, M. B. and Cummingst, R. M., “Wake Integration for Three-Dimensional Flow Field Computations: Theoretical Development,” Journal of Aircraft, 36, pp. 357365 (1999).Google Scholar
22. Kusunose, K., “Development of a Universal Wake Survey Data Analysis Code,” 15th Applied Aerodynamics Conference, Fluid Dynamics and Co-located Conferences, doi.org/10.2514/6.1997-2294 (1997).Google Scholar
23. Dabiri, J. O. and Gharib, M., “Fluid Entrainment by Isolated Vortex Rings,” Journal of Fluid Mechanics, 511, pp. 311331 (2004).Google Scholar
24. Fu, Z. D., Qin, S. Y. and Liu, H., “Mechanism of Transient Force Augmentation Varying with Two Distinct Timescales for Interacting Vortex Rings,” Physics of Fluids, 26, pp. 502543 (2014).Google Scholar
25. Maxworthy, T., “The Structure and Stability of Vortex Rings,” Journal of Fluid Mechanics, 51, pp. 1532 (1972).Google Scholar