收稿日期: 2016-11-14
网络出版日期: 2018-10-26
基金资助
国家自然科学基金重点资助项目(11232009);国家自然科学基金面上资助项目(11372171);国家自然科学基金优青资助项目(11422214)
Bifurcation and chaos of axially moving viscoelastic beam constituted by standard linear solid model
Received date: 2016-11-14
Online published: 2018-10-26
研究了轴向运动黏弹性梁在参数激励下的非线性动力学行为. 采用牛顿第二定律推导了轴向运动梁的积分-偏微分控制方程, 采用三参数模型本构关系描述了运动梁的黏性特征. 运用四阶Galerkin截断方法将控制方程离散为常微分方程组, 并采用四阶Runge-Kutta法对常微分方程组求解, 得到了运动梁上各点的时间响应历程, 进而分析了运动梁的分岔与混沌特征. 通过时间历程图以及频谱分析图、相图、庞加莱映射图, 呈现了系统的混沌现象. 着重考察了三参数黏弹性对系统非线性动力学行为的影响. 结果发现, 轴向运动梁的非线性振动对黏弹性各个参数都很敏感.
关键词: 轴向运动梁; 三参数模型; Galerkin截断; 分岔; 混沌
李怡, 严巧赟, 丁虎, 陈立群 . 轴向运动三参数黏弹性梁的分岔与混沌[J]. 上海大学学报(自然科学版), 2018 , 24(5) : 713 -720 . DOI: 10.12066/j.issn.1007-2861.1870
The nonlinear dynamic behavior of an axially moving viscoelastic beam under parametric excitation is investigated. A standard linear solid model is used in the constitutive relation. Newton's second law is applied to derive a nonlinear integral-partial-differential governing equation of the beam. The fourth-order Galerkin truncation method is applied to truncate the governing equation into a set of ordinary differential equations solved with the fourth-order Runge-Kutta method. Based on the diagrams of time history, phase, Poincaré map and frequency analysis, the dynamical behavior is identified. The investigation is focused on the effects of the standard linear solid model's viscoelasticity on the nonlinear dynamic behavior. Numerical simulations show that vibration of an axially accelerating viscoelastic beam is sensitive to all parameters of the standard linear solid model.
| [1] | 陈树辉, 黄建亮, 佘锦炎. 轴向运动梁横向非线性振动研究[J]. 动力学与控制学报, 2004,2(1):40-50. |
| [2] | 陈立群, 刘延柱, 薛纭. Kirchhoff弹性杆动力学建模的分析力学方法[J]. 物理学报, 2006,55(8):3845-3851. |
| [3] | 丁虎, 陈立群, 张国策. 轴向运动梁横向非线性振动模型研究进展[J]. 动力学与控制学报, 2013,11(1):20-30. |
| [4] | 沈惠杰, 温激鸿, 郁殿龙, 等. 基于Timoshenko梁模型的周期充液管路弯曲振动带隙特性和传输特性[J]. 物理学报, 2009,58(2):8357-8363. |
| [5] | 李群宏, 闫玉龙, 韦丽梅, 等. 非线性传送带系统的复杂分岔[J]. 物理学报, 2013,62(12):65-74. |
| [6] | 丁虎, 陈立群. 轴向运动梁参数激励振动稳定性研究进展[J]. 上海大学学报(自然科学版), 2011,11(1):1672-6553. |
| [7] | Ravindra B, Zhu W D. Low-dimensional chaotic response of axially accelerating continuum in the supercritical regime[J]. Archive of Applied Mechanics, 1998,68(3):195-205. |
| [8] | Chakraborty G, Mallik A K. Stability of an accelerating beam[J]. Journal of Sound and Vibration, 1999,227(2):309-320. |
| [9] | Yang X D, Chen L Q. Bifurcation and chaos of an axially accelerating viscoelastic beam[J]. Chaos, Solitons and Fractals, 2005,23(1):249-258. |
| [10] | Chen L Q, Tang Y Q. Combination and principal parametric resonances of axially accelerating viscoelastic beams: recognition of longitudinally varying tensions[J]. Journal of Sound and Vibration, 2011,330(23):5598-5614. |
| [11] | 严巧赟, 丁虎, 陈立群. 黏弹性轴向运动变张力梁非线性动力学[J]. 噪声与振动控制, 2013,33(3):1006-1355. |
| [12] | 丁虎, 严巧赟, 陈立群. 轴向加速运动黏弹性梁受迫振动中的混沌动力学[J]. 物理学报, 2013,62(20):1-7. |
| [13] | Yan Q Y, Ding H, Chen L Q. Nonlinear dynamics of axially moving viscoelastic Timoshenko beam under parametric and external excitations[J]. Applied Mathematics and Mechanics (English Edition), 2015,36(8):971-984. |
| [14] | Tang Y Q, Zhang D B, Gao J M. Parametric and internal resonance of axially accelerating viscoelastic beams with the recognition of longitudinally varying tensions[J]. Nonlinear Dynamics, 2016,83(1/2):401-418. |
| [15] | 杨挺青, 罗文波, 徐平, 等. 黏弹性理论与应用 [M]. 北京: 科学出版社, 2004: 13-24. |
| [16] | Wang B. Asymptotic analysis on weakly forced vibration of axially moving viscoelastic beam constituted by standard linear solid model[J]. Applied Mathematics and Mechanics (English Edition), 2012,33(6):817-828. |
| [17] | Wang B, Chen L Q. Asymptotic stability analysis with numerical confirmation of an axially accelerating beam constituted by the standard linear solid model[J]. Journal of Sound and Vibration, 2009,328(4/5):456-466. |
/
| 〈 |
|
〉 |
