Nonlinear thermal flutter characteristics of thermoplastic composite panels in supersonic flow

被引：0

作者：

Gao Y. ^{[1
,2
]}

Duan J. ^{[3
]}

Lei Y. ^{[1
]}

机构：

[1] College of Aerospace Science and Engineering, National University of Defense Technology, Changsha

[2] Beijing Institute of Astronautical Systems Engineering, China Academy of Launch Vehicle Technology, Beijing

[3] Department of Engineering Mechanics, Shijiazhuang Tiedao University, Shijiazhuang

来源：

Guofang Keji Daxue Xuebao/Journal of National University of Defense Technology | 2022年 / 44卷 / 02期

关键词：

Limit cycle oscillation characteristics; Mode coupling; Nonlinear thermal flutter; Supersonic flow; Thermoplastic composite panels;

D O I：

10.11887/j.cn.202202003

中图分类号：

学科分类号：

摘要：

The flutter behavior of thermoplastic composite structures in high-speed flow is a key problem in the design of reusable spacecraft. Based on the classical Mindlin thick theory, the Von-Karman larger deformation theory and the piston theory, the thermoplastic composite structure panel and its aerodynamics were described, along with the consideration of both the thermal stress and the variation of mechanical properties caused by the temperature. The aeroelastic model of the thermoplastic composite panel was established based on the principle of virtual work and the finite element method, and the V-g method and the Newmark method were used to solve the thermal flutter characteristics of the thermoplastic panel from frequency domain and time domain, respectively. After the validity and convergence of the presented method were verified, the effects of temperature on mode coupling in frequency domain, limit cycle oscillation in time-domain and stress response were investigated.The results show that the flutter dynamic pressure obtained by considering the temperature variation of thermoplastic materials will further reduce the flutter dynamic pressure of the panel, and the equivalent stress of thermoplastic panels under the limit cycle oscillation is lower than the material yield limit. © 2022, NUDT Press. All right reserved.

引用

页码：16 / 23

页数：7

共 19 条

[1] HOUBOLT J C., A study of several aerothermoelastic problems of aircraft in high speed flight, (1958)
[2] DOWELL E H., Nonlinear oscillations of a fluttering plate. II, AIAA Journal, 5, 10, pp. 1856-1862, (1967)
[3] KOUCHAKZADEH M A, RASEKH M, HADDADPOUR H., Panel flutter analysis of general laminated composite plates, Composite Structures, 92, 12, pp. 2906-2915, (2010)
[4] ZHOU R C, XUE D Y, MEI C., Finite element time domain-modal formulation for nonlinear flutter of composite panels, AIAA Journal, 32, 10, pp. 2044-2052, (1994)
[5] YANG Z C, TAN G H, XIA W., Effects of stacking sequence on thermal flutter speed of composite panel, Journal of Astronautics, 29, 3, pp. 1047-1052, (2008)
[6] LI K L, ZHANG J Z., Numerical analysis method and aerothermoelastic behaviors of temperature-dependent functional graded panels, Journal of Astronautics, 34, 9, pp. 1177-1186, (2013)
[7] ZHUANG W Z, YANG C, WU Z G., Aeroelastic analysis of foam-filled composite corrugated sandwich plates using a higher-order layerwise model, Composite Structures, 257, (2021)
[8] ZHUANG W Z, YANG C, WU Z G., Modal and aeroelastic analysis of trapezoidal corrugated-core sandwich panels in supersonic flow, International Journal of Mechanical Sciences, 157, 158, pp. 267-281, (2019)
[9] SONG Z G, LI F M., Flutter and buckling characteristics and active control of sandwich panels with triangular lattice core in supersonic airflow, Composites Part B, 108, pp. 334-344, (2017)
[10] OZEN I, CAVA K, GEDIKLI H, Et al., Low-energy impact response of composite sandwich panels with thermoplastic honeycomb and reentrant cores, Thin-Walled Structures, 156, (2020)

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