高频振动变体壁面对跨声速抖振影响的数值研究

doi:10.7527/S1000-6893.2026.33555

本期目录 | 过刊浏览 | 高级检索

前一篇 | 后一篇

高频振动变体壁面对跨声速抖振影响的数值研究

胡仕林,康伟,梁康

西北工业大学

收稿日期:2026-03-09 修回日期:2026-05-21 出版日期:2026-05-25 发布日期:2026-05-25
通讯作者: 康伟

Numerical Investigation of High-Frequency Oscillating Morphing Surface Effects on Transonic Buffet

Shi-lin HU,Wei KANG,

Received:2026-03-09 Revised:2026-05-21 Online:2026-05-25 Published:2026-05-25
Contact: Wei KANG

摘要/Abstract

摘要： 跨声速抖振是一种由激波/边界层干扰诱发的激波振荡现象，会严重影响飞行器气动性能与结构安全。本文采用数值方法研究了高频振动变体壁面对跨声速抖振的控制效果与影响机理，系统计算并分析了三种变体壁面激励形式在1至20倍自然抖振频率范围内对翼型抖振响应特性的影响。结果表明三种激励形式均能有效减小抖振载荷，其中单边凸振动激励在全频段范围内抑制效果最佳，抖振载荷最大能够降低88.49%。每种振动形式均存在一个起始激励频率，当激励频率超过该值时，流场中发生锁频现象，翼表面的激波抖振从低频大振幅运动（非锁频状态）转变为高频小振幅运动（锁频状态），抖振载荷得到大幅度降低（>80%）。流场模态结果进一步表明，锁频与非锁频状态之间的抖振载荷抑制差异源于原始抖振模态与激励模态之间的竞争关系。非锁频状态下原始抖振模态主导流场，抑制效果有限；锁频状态下激励模态占主导，迫使激波运动高频化并实现有效控制。研究表明了高频振动变体壁面在跨声速抖振控制中的应用潜力，为基于振动变体壁面的抖振主动控制提供了理论依据。

关键词: 跨声速抖振, 变体壁面, 高频振动, 抖振抑制, 流场模态

Abstract: Transonic buffet is a shock oscillation phenomenon induced by shock wave/boundary layer interaction, which severely compromises aircraft structural safety and aerodynamic performance. This study employs numerical methods to investigate the control efficacy and underlying mechanisms of high-frequency oscillating morphing surfaces on transonic buffet. Systematic computations and analyses are conducted for three morphing surface excitation types across a frequency range of 1–20 times the natural buffet frequency to examine their effects on airfoil buffet response characteristics. The results demonstrate that all three excitation types can effectively suppress buffet loads, with the convex excitation type achieving optimal suppression effect across the entire frequency band, reducing buffet loads by up to 88.49%. Each excitation type exhibits a critical excitation frequency threshold. Beyond this value, frequency lock-in occurs in the flow field, and the shock buffet on the airfoil surface transitions from low-frequency large-amplitude motion (unlock-in state) to high-frequency small-amplitude motion (lock-in state), yielding substantial buffet load reduction (>80%). Modal analysis results further reveal that the transition between lock-in and unlock-in states stems from the competition between the intrinsic buffet mode and the excitation-induced mode. In the unlock-in state, the intrinsic buffet mode dominates the flow field with limited suppression efficacy. In the lock-in state, the excitation-induced mode becomes dominant, compelling the shock motion to shift to higher frequencies and achieving effective control. This study demonstrates the application potential of high-frequency oscillating morphing surfaces for transonic buffet control and provides theoretical foundations for buffet active control strategies based on oscillating morphing surfaces.

Key words: Transonic buffet, Morphing surface, High-frequency oscillating, Buffet suppression, Flow mode

中图分类号:

V211. 3

胡仕林康伟梁康. 高频振动变体壁面对跨声速抖振影响的数值研究[J]. 航空学报, doi: 10.7527/S1000-6893.2026.33555.

Shi-lin HU Wei KANG. Numerical Investigation of High-Frequency Oscillating Morphing Surface Effects on Transonic Buffet[J]. Acta Aeronautica et Astronautica Sinica, doi: 10.7527/S1000-6893.2026.33555.

参考文献

[1]GIANNELIS N F, VIO G A, LEVINSKI O.A review of recent developments in the understanding of transonic shock buffet [J]. Progress in Aerospace Sciences, 2017, 92: 39-84.[J].Progress in Aerospace Sciences, 2017, 92(1):39-84
[2]张伟伟, 高传强, 叶正寅.机翼跨声速抖振研究进展[J].航空学报, 2015, 36(04):1056-75
[3]DOLLING D S.Fifty Years of Shock-WaveBoundary-Layer Interaction Research: What Next?[J].AIAA Journal, 2001, 39(8):1517-31
[4]GAO C, ZHANG W.Transonic aeroelasticity: A new perspective from the fluid mode [J]. Progress in Aerospace Sciences, 2020, 113: 100596.[J].Progress in Aerospace Sciences, 2020, 113(1):100596-100596
[5]LEE B H K.Self-sustained shock oscillations on airfoils at transonic speeds[J].Progress in Aerospace Sciences, 2001, 37(2):147-96
[6]CROUCH J D, GARBARUK A, MAGIDOV D, et al.Origin of transonic buffet on aerofoils [J]. Journal of Fluid Mechanics, 2009, 628: 357-69.[J].Journal of Fluid Mechanics, 2009, 628(1):357-369
[7]GAO C, ZHANG W, YE Z.Numerical study on closed-loop control of transonic buffet suppression by trailing edge flap [J]. Computers & Fluids, 2016, 132: 32-45.[J].Computers & Fluids, 2016, 132(1):32-45
[8]TSUKAMOTO Y, KITAMURA K.Numerical Study of Transonic Buffet on SC(2)-0518 and OAT15A with Vortex Generators[J].AIAA Journal, 2024, 62(8):3052-65
[9]田珊珊, 金亮, 杜兆波, 等.基于鼓包的激波边界层干扰控制研究进展[J].航空学报, 2023, 44(18):37-60
[10]BRUCE P J K, COLLISS S P.Review of research into shock control bumps[J].Shock Waves, 2015, 25(5):451-71
[11]GEOGHEGAN J A, GIANNELIS N F, VIO G A.Parametric Study of Active Shock Control Bumps for Transonic Shock Buffet Alleviation; proceedings of the AIAA Scitech 2020 Forum, F, 2020 [C]. American Institute of Aeronautics and Astronautics.
[12]康伟, 胡仕林, 王彦清.介电弹性薄膜翼型的增升效应机理[J].航空学报, 2023, 44(18):112-23
[13]KANG W, HU S, WANG Y.Lift enhancement mechanism study of the airfoil with a dielectric elastic membrane skin [J]. Journal of Fluids and Structures, 2024, 125: 104083.[J].Journal of Fluids and Structures, 2024, 125(1):1-13
[14]胡仕林, 陈柄宙, 康伟.基于动力学模态分解的柔性膜翼增升机制[J].航空学报, 2025, 46(02):137-49
[15]VISBAL M.Viscous and inviscid interactions of an oblique shock with a flexible panel [J]. Journal of Fluids and Structures, 2014, 48: 27-45.[J].Journal of Fluids and Structures, 2014, 48(1):27-45
[16]BROUWER K R, GOGULAPATI A, MCNAMARA J J.Interplay of Surface Deformation and Shock-Induced Separation in ShockBoundary-Layer Interactions[J].AIAA Journal, 2017, 55(12):4258-73
[17]SHINDE V, MCNAMARA J, GAITONDE D, et al.Transitional shock wave boundary layer interaction over a flexible panel [J]. Journal of Fluids and Structures, 2019, 90: 263-85.[J].Journal of Fluids and Structures, 2019, 90(1):263-285
[18]SHINDE V, MCNAMARA J, GAITONDE D.Control of transitional shock wave boundary layer interaction using structurally constrained surface morphing [J]. Aerospace Science and Technology, 2020, 96: 105545.[J].Aerospace Science and Technology, 2020, 96(1):1-13
[19]SHINDE V J, GAITONDE D V, MCNAMARA J J.Supersonic Turbulent Boundary-Layer Separation Control Using a Morphing Surface[J].AIAA Journal, 2021, 59(3):912-26
[20]REN K, GAO C, ZHOU F, et al.Transonic Buffet Active Control with Local Smart Skin[J].Actuators, 2022, 11(6):155-167
[21]HAMADA A A, MARGHA L, ABDELRAHMAN M M, et al.Dynamic shock wave investigations for an unsteady supersonic flow with a morphing bump over a flat plate[J].Shock Waves, 2025, 35(3):215-33
[22]孟祥一, 戴玉婷, 张育鸣，等.流固耦合翼型跨声速抖振载荷控制与机理分析[J].航空学报, 2026, 1(1):1-13
[23]GEOGHEGAN J A, GIANNELIS N F, VIO G A.A Numerical Study on Transonic Shock Buffet Alleviation Through Oscillating Shock Control Bumps; proceedings of the 2018 AIAA Aerospace Sciences Meeting, F, 2018 [C]. American Institute of Aeronautics and Astronautics.
[24]韦莲旖, 郑冠男, 黄程德, 等.跨声速抖振与翼型蒙皮的耦合作用. 第七届全国流固耦合与非常流体力学学术会议, 中国江苏盐城, 2024 [C].
[25]GREENBLATT D, WILLIAMS D R.Flow Control for Unmanned Air Vehicles[J].Annual Review of Fluid Mechanics, 2022, 54(Volume 54,2022):383-412
[26]WYGNANSKI I.On the need to reassess the design tools for active flow control[J].Progress in Aerospace Sciences, 2024, 146(1):1-13
[27]SIMIRIOTIS N, JODIN G, MAROUF A, et al.Morphing of a supercritical wing by means of trailing edge deformation and vibration at high Reynolds numbers: Experimental and numerical investigation [J]. , .[J].Journal of Fluids and Structures, 2019, 91(1):1-12
[28]ROUAIX C, JIMéNEZ-NAVARRO C, CARVALHO M, et al.Electroactive morphing effects on the aerodynamic performance through wobulation around an A320 wing with vibrating trailing edge at high Reynolds number [J].[J].Journal of Fluids and Structures, 2023, 123(1):1-13
[29]JIMENEZ-NAVARRO C, T? J B, ROUAIX C, et al.Morphing Effects on the Aerodynamic Performances of a Supercritical Wing’s Prototype in Transonic Flow Conditions [M]//TUOVINEN T, PERIAUX J, KNOERZER D, et al. Advanced Computational Methods and Design for Greener Aviation. Cham; Springer International Publishing. 2024: 159-74.
[30]JACQUIN L, MOLTON P, DECK S, et al.Experimental Study of Shock Oscillation over a Transonic Supercritical Profile[J].AIAA Journal, 2009, 47(9):1985-94
[31]ZHAO Y, DAI Z, TIAN Y, et al.Flow characteristics around airfoils near transonic buffet onset conditions[J].Chinese Journal of Aeronautics, 2020, 33(5):1405-20
[32]TIAN Y, GAO S, LIU P, et al.Transonic buffet control research with two types of shock control bump based on RAE2822 airfoil[J].Chinese Journal of Aeronautics, 2017, 30(5):1681-96

E-mail：hkxb@buaa.edu.cn

关于我们

期刊社服务

专业学科

封面文章

友情链接

主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

高频振动变体壁面对跨声速抖振影响的数值研究

Numerical Investigation of High-Frequency Oscillating Morphing Surface Effects on Transonic Buffet

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

[1]	刘知辉, 牛军川, 贾睿昊. 热梯度环境下梁高频振动的能量流模型[J]. 航空学报, 2022, 43(5): 425336-425336.
[2]	章胜华, 邓枫, 覃宁, 刘学强. 激波控制鼓包对跨声速抖振影响的数值研究[J]. 航空学报, 2022, 43(11): 526806-526806.
[3]	滕晓艳, 丰国宝, 江旭东, 赵贺桃. 自由阻尼梁高频能量流响应的解析模型[J]. 航空学报, 2019, 40(4): 222616-222616.
[4]	宁方立, 史红兵, 丘廉芳, 卫金刚. 前缘高频振动对亚声速开式空腔内强噪声影响的数值研究[J]. 航空学报, 2015, 36(12): 3843-3852.
[5]	牛康民;涂柏林;颜鸣皋. 耐热钢GH36高低周复合疲劳裂纹扩展的研究[J]. 航空学报, 1986, 7(3): 273-280.