高效层流翼型设计及试验验证

耿延升; 艾梦琪; 王伟; 耿建中; 赵彦

doi:10.7527/S1000-6893.2022.26798

航空学报 >

2022 , Vol. 43 >Issue 11: 526798 - 526798

DOI: https://doi.org/10.7527/S1000-6893.2022.26798

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高效层流翼型设计及试验验证

耿延升 ,
艾梦琪 ,
王伟 ,
耿建中 ,
赵彦

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1. 航空工业第一飞机设计研究院, 西安 710089;
2. 西北工业大学, 西安 710072

收稿日期: 2021-12-09

修回日期: 2022-02-26

网络出版日期: 2022-08-29

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Efficient design and experimental verification of laminar airfoil

GENG Yansheng ,
AI Mengqi ,
WANG Wei ,
GENG Jianzhong ,
ZHAO Yan

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1. AVIC The First Aircraft Institute, Xi'an 710089, China;
2. Northwestern Polytechnical University, Xi'an 710072, China

Received date: 2021-12-09

Revised date: 2022-02-26

Online published: 2022-08-29

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摘要

层流机翼设计技术是民用飞机减阻设计重要的发展方向之一。采用CST参数化方法及现代优化算法开展了面向工程应用的层流翼型设计方法研究，基于某层流技术验证机需求设计了一款层流翼型，采用数值计算和高速风洞试验对其层流特性进行了验证研究。研究结果表明，发展的设计方法可以实现层流翼型优化设计及反设计，优化翼型表面的层流区域显著扩大，升阻比有所提升；为验证机设计的层流翼段在设计点具有超过50%的层流区域，较传统翼段减阻量超过10%。研究结果对军民用高亚声速运输类飞机的层流减阻设计具有一定的参考价值。

关键词： 层流机翼; 翼型优化; 风洞试验; 升阻比; 转捩

本文引用格式

耿延升 , 艾梦琪 , 王伟 , 耿建中 , 赵彦 . 高效层流翼型设计及试验验证[J]. 航空学报, 2022 , 43(11) : 526798 -526798 . DOI: 10.7527/S1000-6893.2022.26798

Abstract

Laminar flow wing design technology is one of the important development directions of civil aircraft drag reduction design. A laminar airfoil design method for engineering applications is studied by using CST parameterization method and modern optimization algorithm. A laminar airfoil is designed based on the requirements of a laminar flow validator, and its laminar flow characteristics are verified by numerical calculation and high-speed wind tunnel test. The results show that the developed design method can realize the optimization design and reverse design of laminar airfoil, the laminar flow area on the optimized airfoil surface is significantly expanded and the lift-drag ratio is improved. The laminar flow section designed for the validator has more than 50% laminar flow area at the design point, and the drag reduction is more than 10% compared with the traditional wing section. The research results have certain reference value for laminar drag reduction design of civil and military high subsonic transport aircraft.

Key words： laminar flow wing; airfoil optimization; wind tunnel test; lift-drag ratio; transition

参考文献

[1] ROSKAM J. Airplane design[M]. Ottawa:DAR Corporation, 1985.
[2] 朱自强, 吴宗成. 现代飞机设计空气动力学[M]. 北京:北京航空航天大学出版社, 2005. ZHU Z Q, WU Z C. Aerodynamics of modern aircraft design[M]. Beijing:Beihang University Press, 2005(in Chinese).
[3] LIEBECK R H. Design of the blended wing body subsonic transport[J]. Journal of Aircraft, 2004, 41(1):10-25.
[4] MA H D, CUI E, Drag prediction and reduction for civil transportation aircraft[J]. Mechanics in Engineering, 2007, 29(2):1-7.
[5] ARCARA P C, BARTLETT D W, MCCULLERS L A. Analysis for the application of hybrid laminar flow control to a long-range subsonic transport aircraft[R]. Warrendale:SAE International, 1991.
[6] 朱自强, 鞠胜军, 吴宗成. 层流流动主/被动控制技术[J]. 航空学报, 2016, 37(7):2065-2090. ZHU Z Q, JU S J, WU Z C. Laminar flow active/passive control technology[J]. Acta Aeronautica et Astronautica Sinica, 2016, 37(7):2065-2090(in Chinese).
[7] JOSLIN R D. Overview of laminar control:NASA TP-208705[R].Washington,D.C.:NASA, 1998.
[8] 乔志德. 自然层流超临界翼型的设计研究[J]. 流体力学实验与测量, 1998(4):23-30. QIAO Z D. Design of supercritical airfoils with natural laminar flow[J]. Experiments and Measurements in Fluid Mechanics, 1998(4):23-30(in Chinese).
[9] 李权, 段卓毅, 张彦军, 等. 民用飞机自然层流机翼研究进展[J]. 航空工程进展, 2013, 4(4):399-406. LI Q, DUAN Z Y, ZHANG Y J, et al. Progress in research on natural laminar wing for civil aircraft[J]. Advances in Aeronautical Science and Engineering, 2013, 4(4):399-406(in Chinese).
[10] Boeing Commerical Airplane Group. High Reynold number hybrid laminar flow control (HLFC) flight experiment(aerodynamic design):NASA/CR1999-209324[R]. Washington,D.C.:NASA,1999.
[11] HORSTMANN K H. TELFONA, Contribution to laminar wing development for future transport aircraft[C]//Aeronautical Days, 2006.
[12] KRISHNAN K S G, BERTRAM O, SEIBEL O. Review of hybrid laminar flow control systems[J]. Progress in Aerospace Sciences, 2017, 93:24-52.
[13] BLAZEK J. Computational fluid dynamics:Principles and applications (Second Edition)[M]. Amsterdam:Elsevier, 2005.
[14] MENTER F R. Two-equation eddy-viscosity turbulence models for engineering applications[J]. AIAA Journal, 1994, 32(8):1598-1605.
[15] LANGTRY R, MENTER F. Transition modeling for general CFD applications in aeronautics[C]//43rd AIAA Aerospace Sciences Meeting and Exhibit. Reston:AIAA, 2005.
[16] SEWALL W G, MCGHEE R J, HAHNE D E, et al. Wind tunnel results of the high-speed NLF (1)-0213airfoil:N 90-12539[R]. Washington,D.C.:NASA,1987.
[17] KULFAN B, BUSSOLETTI J. "Fundamental" parameteric geometry representations for aircraft component shapes[C]//11th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference. Reston:AIAA, 2006.
[18] HOLLAND J H. Adaptation in natural artificial systems:An introductory analysis with applications to biology, control, and artificial intelligence[M]. 2nd ed.Cambridge:MIT Press, 1992:1-51.
[19] TAMAKI O, TOMOYUKI H, MITSUNORI M,et al. DCMOGA:Distributed cooperation model of multi-objective genetic algorithm[J]. Science& Engineering Review of Doshisha University,2001,42:129-140.
[20] 艾梦琪, 段卓毅, 张健, 等. 高亚声速层流翼型转捩数值模拟及试验研究[J]. 飞行力学, 2020, 38(6):77-81, 94. AI M Q, DUAN Z Y, ZHANG J, et al. Numerical simulation and test on transition of a high subsonic laminar airfoil[J]. Flight Dynamics, 2020, 38(6):77-81, 94(in Chinese).

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