与常规机翼不同,变弯度机翼抗鸟撞装置在设计时需要考虑变弯度机翼的机构运动路线,在保证不影响机翼机构正常功能的前提下进行设计,因此也大大增加了抗鸟撞装置设计的难点。本文通过实验与仿真相结合的方法,对不同构型楔形结构的抗鸟撞性能进行了研究,得到了最合理、有效的抗鸟撞结构。根据鸟撞仿真分析结果,结合机翼机构运动路线,确定了抗鸟撞装置的设计思路,同时设计并制造了三角加弧形结构抗鸟撞装置,并对其进行了试验验证与仿真分析。结果表明,三角加弧形结构能有效预防变弯度机翼在受到鸟撞后发生破坏,为变弯度机翼抗鸟撞结构的设计提供了参考。
Abstract
Different from conventional wings, the bird strike device of the variable camber wing needs to consider the movement route of the variable camber wing during the design, so as to ensure that the normal function of the wing mechanism is not affected. Therefore, it also greatly increases the difficulty of the design of the bird strike device. In this paper, the bird-strike resistance performance of wedge-shaped structures of different configurations is studied through the method of combining experiment and simulation, and the most reasonable and effective anti-bird strike structure is obtained. According to the results of bird strike simulation, combined with the movement route of the wing mechanism, the design idea of the bird strike device is determined. The triangle and arc anti bird strike device is designed and manufactured, and the experimental verification and simulation analysis are carried out. The results show that the triangle and arc structure can effectively prevent the variable camber wing from being damaged after being hit by bird, which provides a reference for the design of the anti-bird strike structure of the wing.
关键词
机翼前缘 /
鸟撞 /
数值分析 /
试验验证
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Key words
leading edge of wing /
bird impact /
numerical simulation /
experimental verification
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参考文献
[1] 刘小川,王计真,白春玉.人工鸟研究进展及在飞机结构抗鸟撞中的应用[J].振动与冲击,2021,40(12):80-89.
Liu Xiao-chuan, Wang Ji-zhen, Bai Chun-yu. Overview on aircraft bird and application on the structural bird-strike [J]. Journal of Vibration and Shock,2021,40(12):80-89.
[2] Liu J, Li Y, Gao X. Bird strike on a flat plate: experiments and numerical simulations [J]. International Journal of Impact Engineering, 2014(70):21-37.
[3] 高俊, 耿立超, 吴志斌. 民用飞机方向舵抗鸟撞分析研究[J].民用飞机设计与研究,2021(01):117-122.
Gao Jun, Geng Li-chao, Wu Zhi-bin. Bird strike resistance analysis and research on civil aircraft rudder [J]. Civil Aircraft Design & Research, 2021(01):117-122.
[4] DOBEEER R A,BEGIER M J. Wildlife strikes to civil aircraft in the united states,1990-2017[R], The FAA National Wildlife Strike Database, Serial Report, 2019
[5] Jun Yan, Zhang Chen-guang, HuoSi-xu, et al. Experimental and numerical simulation ofbird-strikeperformance of lattice-material-infi-lled curved plate[J]. Chinese Journal of Aer-onautics,2021,34(08):245-257.
[6] Shahimi S S, Nur A A, Meftah H, et al. Numerical Investigation on the Damage of Whirling Engine Blades Subjected to Bird Strike Impact [J]. Journal of Aeronautics, Astronautics and Aviation, 2021, 53(2):193-199.
[7] Frederik A, Geert L, Wim V P, et al. Numerical and experimental investigation of the shock and steady state pressures in the bird material during bird strike [J]. International Journal of Impact Engineering, 2017, 107:12-22.
[8] 中国民用航空局.运输类飞机适航标准CCAR-25-R4[S]. 北京:中国标准出版社,2016.
[9] Feng S, Qin S, Lei N, et al. Numerical analysis of anti-bird strike performance in structural connection design for a vertical tail leading edge [J]. Thin-Walled Structures, 2019,144.
[10] Sebastian H. Computational methods for bird strike simulations: A review [J]. Computers and Structures, 2011, 89(23):2093-2112.
[11] klak J. Numerical Simulations of Bird Strikes with the Use of Various Equations of State [J]. Journal of KONBiN,2020,50(3):333-357
[12] 任冀宾,王斌,王振.某型飞机机翼前缘抗鸟撞结构设计与试验验证[J].爆炸与冲击,2019,39(02):133-141.
Ren Ji-bin, Wang Bin, Wang Zhen, et al.Design and Experimental Verification of Anti-bird Strike Structure for the Leading Edge of a Certain Aircraft Wing[J]. Explosion and Shock Waves, 2019, 39(02):133-141.
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