脉动流下两端简支细长圆柱动力学行为分析

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摘要在考虑由附加轴向力引起非线性项基础上，建立了轴向脉动流下两端简支圆柱的非线性动力学模型。为了研究该描述系统的动力学特性，进一步讨论关键参数脉动频率对系统动力学行为的影响。从分岔图可以看出系统在一定的频率范围内可能存在混沌，并且通过三个特定脉动频率下的相图、庞加莱映射、功率谱、以及最大Lyapunov指数等统计特征来分析该系统的动力学特性。该研究结果对反应堆中脉动流引起燃料棒流致振动的安全评估具有指导意义。

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	舒亚锋1
	2
	武建军1
	杨永伟2
	李佳骏1

关键词 ：非线性项, 脉动流, 分岔图, 动力学特性

Abstract：The nonlinear dynamic model of a two-end simply-supported cylinder subjected to axial pulsating flow was established considering a nonlinear term caused by additional axial force. In order to study dynamic characteristics of the system, effects of key parameter’s pulsating frequency on dynamic behaviors of the system were further discussed. From bifurcation diagram, it was observed that chaos may exist in the system within a certain frequency range. Phase diagrams, Poincare mapping and statistical features, such as, power spectrum and the maximum Lyapunov exponent under 3 special pulsating frequencies were used to analyze dynamic characteristics of the system. It was shown that the results provide a guide for safety assessment of flow induced vibration of a fuel rod caused by pulsating flow in a reactor system.

Key words： nonlinear term pulsating flow bifurcation diagram dynamic characteristics

收稿日期: 2018-11-09

引用本文:

舒亚锋1,2，武建军1，杨永伟2，李佳骏1. 脉动流下两端简支细长圆柱动力学行为分析[J]. 振动与冲击, 2020, 39(13): 49-56.
SHU Yafeng1,2, WU Jianjun1, YANG Yongwei2, LI Jiajun1. Dynamic behavior analysis for a two-end simply-supported slender cylinder subjected to pulsating flow. JOURNAL OF VIBRATION AND SHOCK, 2020, 39(13): 49-56.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2020/V39/I13/49

[1] E.Ter Hofstede, S. Kottapalli, A. Shams, Numerical prediction of flow induced vibrations in nuclear reactor applications[J]. Nuclear Engineering and Design, 2017, 319: 81-90.

[2] W. R. Marcum, B. G. Woods. Predicting the onset of dynamic instability of a cylindrical plate under axial flow conditions[J]. Nuclear Engineering and Design, 2012, 250: 81-100.

[3] M. P. Paϊdoussis. Dynamics of flexible slender cylinders in axial flow Part 1. Theory[J]. Journal of Fluid Mechanics, 1966, 26(4): 717-736.

[4] M. P. Paϊdoussis. Dynamics of flexible slender cylinders in axial flow Part 2. Experiments[J]. Journal of Fluid Mechanics, 1966, 26(4), 737-751.

[5] M. P. Paϊdoussis. The dynamical behaviour of cylindrical structures in axial flow[J]. Annals of Nuclear Science and Engineering 1974,1:83-106.

[6] 王琳，输流管道的稳定性、分岔与混沌行为研究[D].武汉：华中科技大学博士论文，2006.

WANG Lin, Stability, bifurcations, and chaos in pipes conveying fluid[D]. Wuhan: Huazhong University of Science & Technology PH.D. thesis, 2006

[7] J. D. Jin, Stability and chaotic motions of a restrained pipe conveying fluid. Journal of Sound and Vibration, 1997, 208: 427~439

[8] Y. Modarres-Sadeghi. Nonlinear dynamics of a slender flexible cylinder subjected to axial flow[D]. PhD thesis, McGill University, 2006.

[9] Y. Modarres-Sadeghi, M. P. Païdoussis, Semler, C., et al., Nonlinear dynamics of slender cylinders supported at both ends and subjected to axial flow. In IUTAM Symposium on Integrated Modeling of Fully Coupled Fluid Structure Interactions Using Analysis, Computations and Experiments (pp. 233-246). Springer, Dordrecht, 2003

[10] V. I. Solonin, V. V. Perevezentsev, Studying the vibration and random hydrodynamic loads on the fuel rods bundles in the fuel assemblies of the reactor installations used at nuclear power stations equipped with VVER reactors[J]. Thermal Engineering, 2012, 59(5): 384-389.

[11] J. De Ridder, Doaré O., J. Degroote, et al. Simulating the fluid forces and fluid-elastic instabilities of a clamped–clamped cylinder in turbulent axial flow[J]. Journal of Fluids and Structures, 2015, 55: 139-154.

[12] M. J. Lighthill, Note on the swimming of slender fish[J]. Journal of fluid Mechanics, 1960, 9(02): 305-317.

[13] G.Taylor,，Analysis of the swimming of long and narrow animals[J]. Proceedings The Royal Society, 1952, 214(1117): 158-183.

[14] M. P. Paϊdoussis, Fluid-Structure interactions, slender structures and axial flow ,V. 2[M]. Academic Press, London, U.K., 2004.

[15] A. Labuschagne, van Rensburg N.F.J., Van der Merwe A. J., Comparison of linear beam theories[J]. Mathematical and Computer Modelling, 2009, 49(1-2): 20-30.

[16] 刘延柱，陈立群.非线性振动[M]. 北京：高等教育出版社,2001.

LIU Yanzhu, CHEN Liqun. Nonlinear vibrations[M]. Beijing: High education press, 2001.

[17] 武建军，郑晓静，周又和，何丽红.两级EMS型悬浮磁悬浮控制系统的动力学稳定性分析[J]. 固体力学学报,2003, 24(1):67-74.

WU Jianjun, ZHENG Xiaojing, ZHOU Youhe, et al. The nonliear dynamical characteristics of magalev control system with two suspensions[J]. Acta mechanical solida sinica, 2003,24(1):67:74

[18] 周又和，郑晓静，武建军，何丽红.磁浮列车的动力稳定性与Liapunov指数[J].力学学报，2000,32(1):42-51.

ZHOU Youhe, ZHENG Xiaojing, WU Jianjun, et al. Analysis of dynamical stability for magnetic levitation vehicles by Liapunov characteristic nunber[J]. Acta mechanical sinica, 2000, 32(1):42-51