Research on aerodynamic characteristics of transport aircraft with stall strips

Liu Yi; Zhao Xiaoxia; Ouyang Shaoxiu; Yuan Zhimin

doi:10.11729/syltlx20160012

Volume 30 Issue 5

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Liu Yi, Zhao Xiaoxia, Ouyang Shaoxiu, et al. Research on aerodynamic characteristics of transport aircraft with stall strips[J]. Journal of Experiments in Fluid Mechanics, 2016, 30(5): 36-41. doi: 10.11729/syltlx20160012

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Research on aerodynamic characteristics of transport aircraft with stall strips

doi: 10.11729/syltlx20160012

Research and Development Center, Avcation Industry Corporation of China Aircraft Co. Ltd., Xi'an 710089, China

Received Date: 2016-01-12
Rev Recd Date: 2016-04-20
Publish Date: 2016-10-25

Abstract

Abstract

In order to alleviate the violent roll motion during stall of a transport aircraft with landing flap configuration, the geometric parameters of stall strips are optimized and selected by numerical simulations and wind tunnel tests, and the aerodynamic force and flow field characteristics are studied. The height H and the install distance S from the leading edge are selected as design parameters for stall strips, and are evaluated by solving Reynolds Averaged Navior-Stokes (RANS) equations for the airfoil section of the landing flap configuration. The calculation indicates that smaller S value (installed closer to the upper surface) promotes earlier stall, while the larger H has similar but weaker effect. Separation bubble emerges after the stall strips when the angle of attack (AOA) of the airfoil becomes large, which grows larger and longer with increasing AOA. The bubble bursts eventually and causes the airfoil to stall earlier, leading to the rounded shape of the lift curve. The effect of the stall strips installed on the wing is studied by scaled model in wind tunnel tests, which shows that its spanwise length and arrangement have significant impact on the performance besides the cross section geometry. Four planform arrangements of stall strips are advanced and evaluated. Keeping the S parameter equal to 0, the stall trips installed at 40% half span with spanwise length of 2m change the abrupt stall of the lift curve to a flat roof type one, and eliminate the asymmetric roll moment after stall. The spanwise length of the stall strips is halved to form 2 new arrangements, which also ameliorate the stall of the lift curve and roll moment to some extent. The stall trips installed at 15% half span have no obvious effects on the stall characteristics. The suggested explanation is that the flow separation starts at about 40% half span of the wing at landing configuration, where the stall strips have the best performance.
- stall strips,
- stall characteristics,
- violent roll motion,
- separation bubble,
- CFD,
- wind tunnel test

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References(17)

References

[1]	中国民用航空局. CCAR-25-R4运输类飞机适航标准[S]. 2011.
[2]	Torenbeek E. Synthesis of subsonic aircraft design[M]. Delft University Press, 1982:227-262.
[3]	Hoerner S F, Borst H V. Fluid-dynamic lift[M]. 2nd ed. Published by the auther, 1985.
[4]	McVeigb M A, Kisielowski E. A design summary of stall characteristics of straight wing aircraft[R]. NASA CR-1646, 1971:1-20.
[5]	Obert E. Aerodynamic design of transport aircraft[M]. IOS Press, 2009.
[6]	Feistel T W, Anderson S B, Kroeger R A. Alleviation of spin-entry tendencies through localization of wing-flow separation[J]. Journal of Aircraft, 1981, 18(2):69-75. doi: 10.2514/3.57467
[7]	Newsom W A, Satran D R, Johnson J L. Effects of wing-leading-edge modifications on a full-scale, low-wing general aviation airplane[R]. NASA-TP-2011, 1982.
[8]	Chambers J R, Dicarlo D J, Johnson J L, et al. Exploratory study of the effects of wing-leading-edge modifications on the stall/spin behavior of a light general aviation airplane[R]. NASA-TP-1589, 1979.
[9]	Jacobs E N. Characteristics of two sharp-nosed airfoils having reduced spinning tendencies[R]. NACA-TN-416, 1932.
[10]	Weick F E, Scudder N F. The effect on lift, drag, and spinning characteristics of sharp leading edges on airplane wings[R]. NACA-TN-447, 1933.
[11]	Owens D B, Capone F J, Hall R M, et al. Free-to-Roll analysis of abrupt wing stall on military aircraft at transonic speeds[R]. AIAA-2003-0750, 2003.
[12]	Capone F J, Hall R M, Owens D B, et al. Recommended experimental procedures for evaluation of abrupt wing stall characteristics[R]. AIAA-2003-0922, 2003.
[13]	Parikh P, Chung J. A computational study of the Abrupt Wing Stall (AWS) characteristics for various fighter jets:part I, F/A-18E and F-16C[R]. AIAA-2003-0746, 2003.
[14]	Hall R M. Accomplishments of the Abrupt Wing Stall (AWS) program and future research requirements[R]. AIAA-2003-0927, 2003.
[15]	Woodson S H, Green B E, Chung J J, et al. Understanding abrupt wing stall with CFD[R]. AIAA-2003-0592, 2003.
[16]	Liu Y, Zhao X X, Ouyang S X, et al. A method to predict the magnitude of roll during stall for transport aircraft and its application[C]. The 55th Israel Annual Conference on Aerospace Sciences, 2015.
[17]	ANSYS. ANSYS FLUENT theory guide[M]. ANSYS Inc, Canonsburg, PA, 2011.