Stall Flutter Analysis of High-Aspect-Ratio Composite Wing 被引量：4

大展弦比复合材料机翼失速颤振分析(英文)

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摘要 The stall flutter characters of high-aspect-ratio composite wing are investigated, and the effects of structure geometric nonlinearity and stiffness couple created by composite anisotropy on them also are discussed. Firstly, the high-aspect-ratio wing is modeled as a composite thin-walled closed section Euler beam whose displacement and rotation both could be of finite value, and the nonlinear dynamic equations is build up on it with all the effects of geometric nonlinearity, aerodynamic nonlinearity and anisotropy of material being considered. Then vibration equations are deduced through perturbing the dynamic equations at wing＇s equilibrium position, and coupled with unsteady stall aerodynamic model and ONERA model, to obtain the nonlinear stall flutter analysis equations of wing. Finally, the flutter stabilities with various wind speeds are determined by the harmonic balance method. With several exampies, the validity of the stall flutter model is proved, and the significant effects of geometric nonlinearity on the stall flutter various characters as wall as the effects of ply angle on the stall flutter speed and frequency also are discussed. The stall flutter characters of high-aspect-ratio composite wing are investigated, and the effects of structure geometric nonlinearity and stiffness couple created by composite anisotropy on them also are discussed. Firstly, the high-aspect-ratio wing is modeled as a composite thin-walled closed section Euler beam whose displacement and rotation both could be of finite value, and the nonlinear dynamic equations is build up on it with all the effects of geometric nonlinearity, aerodynamic nonlinearity and anisotropy of material being considered. Then vibration equations are deduced through perturbing the dynamic equations at wing＇s equilibrium position, and coupled with unsteady stall aerodynamic model and ONERA model, to obtain the nonlinear stall flutter analysis equations of wing. Finally, the flutter stabilities with various wind speeds are determined by the harmonic balance method. With several exampies, the validity of the stall flutter model is proved, and the significant effects of geometric nonlinearity on the stall flutter various characters as wall as the effects of ply angle on the stall flutter speed and frequency also are discussed.

作者刘湘宁向锦武

机构地区 School of Aeronautics Science and Engineering

出处《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2006年第1期36-43,共8页 中国航空学报（英文版）

基金 NationalNaturalScienceFoundationofChinaandProgramforNewCenturyExcellentTalentsinUniversity(NCET0401Q)

关键词 stall flutter high-aspect-ratio wing geometric nonlinearity COMPOSITES thln-walled closed section beam stall flutter high-aspect-ratio wing geometric nonlinearity composites thln-walled closed section beam

分类号 V215.34 [航空宇航科学与技术—航空宇航推进理论与工程]

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共引文献2

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