Bifurcation and chaos study on transverse-torsional coupled 2K-H planetary gear train with multiple clearances

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• 作者：Dong-ping Sheng 盛冬巿/a> ; Ru-peng Zhu 朱如鷿/a>…
• 刊名：Journal of Central South University
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：23
• 期：1
• 页码：86-101
• 全文大小：2,321 KB
• 参考文献：[1]KAHRAMAN A, SINGH R. Nonlinear dynamics of a geared rotor bearing system with multiple clearance [J]. Journal of Sound and Vibrations, 1991, 144: 469–506.CrossRef
  [2]KAHRAMAN A, SINGH R. Interactions between time-varying mesh stiffness and clearance nonlinearities [J]. Journal of Sound and Vibrations, 1991, 146: 135–156.CrossRef
  [3]HIDAKA T. Analysis of dynamic load on planetary gear [J]. Bulletin of the JSME, 1980, 23(176): 315–322.CrossRef
  [4]AUGUST R, VELEX P. Torsional vibration and dynamic loads in a basic planetary gear system [J]. Journal of Vibration, Acoustics, Stress, and Reliability in Design, 1986, 108(7): 348–353.CrossRef
  [5]KAHRAMAN A. Planetary gear train dynamics [J]. ASME, Journal of Mechanical Design, 1994, 116(3): 713–720.CrossRef
  [6]SAADA A, VELEX P. An extended model for the analysis of the dynamic behavior of planetary trains [J]. ASME, Journal of Mechanical Design, 1995, 117(6): 241–247.CrossRef
  [7]LIN J, PARKER R G. Analytical characterization of the unique properties of planetary gear free vibration [J]. ASME, Journal of Vibration and Acoustics, 1999, 121(7): 316–321.CrossRef
  [8]PARKER R G, AGASHE V, VIJAYAKAR S M. Dynamic response of a planetary gear system using a finite element/contact mechanics model [J]. ASME, Journal of Mechanical Design, 2000, 122(9): 304–310.CrossRef
  [9]SUN Tao, SHEN Yun-wen, SUN Zhi-ming. Study on nonlinear dynamic behavior of planetary gear train dynamic model and governing equations [J]. Journal of Mechanical Engineering, 2002, 38(3): 6–10. (in Chinese)MathSciNet CrossRef
  [10]SUN Tao, HU Hai-yan. Nonlinear dynamics of a planetary gear system with multiple clearances [J]. Mechanism and Machine Theory, 2003, 38(5): 1371–1390.CrossRef MATH
  [11]SUN Zhi-min, JI Lin-hong, SHEN Yun-wen. Nonliear dynamics of 2K-H planetary gear train [J]. Journal of Tsinghua University: Sci & Tech, 2003, 43(5): 636–639. (in Chinese)
  [12]CHANGJIAN C W, CHEN C K. Bifurcation and chaos of a flexible rotor supported by turbulent journal bearings with non-linear suspension [C]// Proc Mech Eng, Part J, J Eng Tribol, 2006, 220: 549–561.CrossRef
  [13]CHANGJIAN C W, CHEN C K. Nonlinear dynamic analysis of a flexible rotor supported by micropolar fluid film journal bearings [J]. Int J Eng Sci, 2006, 44: 1050–1070.CrossRef
  [14]CHANGJIAN C W, CHEN C K. Bifurcation and chaos of a flexible rotor supported by turbulent journal bearings with non-linear suspension [J]. Mech Mach Theory, 2007, 42(3): 312–333.CrossRef
  [15]CHANGJIAN C W, CHEN C K. Bifurcation and chaos analysis of a flexible rotor supported by turbulent long journal bearings [J]. Chaos Solitons Fractals, 2007, 34(4): 1160–1179.CrossRef
  [16]AMBARISHA V K, PARKER R G. Nonlinear dynamics of planetary gears using analytical and finite element models [J]. Journal of Sound and Vibration, 2007, 302(1): 577–595.CrossRef
  [17]AL-SHYYAB A, KAHRAMAN A. A non-linear dynamic model for planetary gear sets [M]. Proc Inst Mech Eng, Part K, J Multi-Body Dyn, 2007, 221: 567–576.
  [18]AL-SHYYAB A, ALWIDYAN K. Non-linear dynamic behavior of compound planetary gear trains: model formulation and semi-analytical solution [C]// Proc Inst Mech Eng, Part K, J Multi-Body Dyn, 2009, 223: 199–210
  [19]LI Tong-jie, ZHU Ru-peng, BAO He-yun. Nonlinear torsional vibration modeling and bifurcation characteristic study of a planetary gear train [J]. Journal of Mechanical Engineering, 2011, 47(21): 76–83. (in Chinese)CrossRef
  [20]WU Shi-jing, LIU Zhen-hao, WANG Xiao-sun. Nonliear dynamic characteristics of compound planetary gear train sets based on harmonic balance method [J]. Journal of Mechanical Engineering, 2011, 47(1): 55–61. (in Chinese)MathSciNet CrossRef
  [21]LI Sheng, WU Qing-ming, ZHANG Zhi-qiang. Bifurcation and chaos analysis of multistage planetary gear train [J]. Nonliear Dyn, 2014, 75: 217–233.MathSciNet CrossRef
  [22]KAHRAMAN A, SINGH R. Non-linear dynamics of a spur gear [J]. Journal of Sound and Vibration, 1990, 142(1): 49–75.CrossRef
  [23]LIN J, PARKER R G. Planetary gear paramtetric instability caused by mesh variation [J]. Sound Vib, 2002, 249(1): 129–145.CrossRef
  [24]WELBOURN D B. Fundamental knowledge of gear noise— A survey [C]// Proceedings of the Conference on Noise and Vibrations of Engines and Transmissions. Cranfield: Institution of Mechanical Engineers, 1979: 9–14.
  [25]HOUSER D R. Gear noise state of the art [C]// Proceedings of Inter-noise. 1988, 88: 601–606.
  [26]KASUBA R, EVANS J W. An extended model for determing dynamic loads in spur gearing [J]. ASME Mech Des, 1981, 103(2): 398–409.CrossRef
  [27]WANG K L, CHENG H S. A numerical solution to the dynamic load [J]. ASME Mech Des, 1981, 103(1): 177–187.CrossRef
  
• 作者单位：Dong-ping Sheng 盛冬平 (1)
  Ru-peng Zhu 朱如鹏 (1)
  Guang-hu Jin 靳广虎 (1)
  Feng-xia Lu 陆凤霞 (1)
  He-yun Bao 鲍和云 (1)
  
  1. College of Mechanical and Electrical Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing, 210016, China
  
• 刊物类别：Engineering
• 刊物主题：Engineering, general
  Metallic Materials
  Chinese Library of Science
  
• 出版者：Central South University, co-published with Springer
• ISSN：2227-5223

文摘

A new non-linear transverse-torsional coupled model was proposed for 2K-H planetary gear train, and gear’s geometric eccentricity error, comprehensive transmission error, time-varying meshing stiffness, sun-planet and planet-ring gear pair’s backlashes and sun gear’s bearing clearance were taken into consideration. The solution of differential governing equation of motion was solved by applying variable step-size Runge-Kutta numerical integration method. The system motion state was investigated systematically and qualitatively, and exhibited diverse characteristics of bifurcation and chaos as well as non-linear behavior under different bifurcation parameters including meshing frequency, sun-planet backlash, planet-ring backlash and sun gear’s bearing clearance. Analysis results show that the increasing damping could suppress the region of chaotic motion and improve the system’s stability significantly. The route of crisis to chaotic motion was observed under the bifurcation parameter of meshing frequency. However, the routes of period doubling and crisis to chaos were identified under the bifurcation parameter of sun-planet backlash; besides, several different types of routes to chaos were observed and coexisted under the bifurcation parameter of planet-ring backlash including period doubling, Hopf bifurcation, 3T-periodic channel and crisis. Additionally, planet-ring backlash generated a strong coupling effect to system’s non-linear behavior while the sun gear’s bearing clearance produced weak coupling effect. Finally, quasi-periodic motion could be found under all above–mentioned bifurcation parameters and closely associated with the 3T-periodic motion.