面内轨道转移过程中的绳系系统摆振特性研究

Abstract

Abstract: The center of mass of a tethered system is in a non-Keplerian orbit during orbital transfer, which leads to a complicated dynamic behavior of the system and affects the normal operation of the mission satellite. Thus, it is of great theoretical and practical significance to study the librational and viberational characteristics of a tethered system. According to its complex nonlinear and strong coupling, an attitude dynamic equation of the tethered system is established on the basis of the momentum theorem; and against the background of deorbiting in the tangential direction, the trajectory of the center of mass is obtained. Based on the analysis of the bifurcation of the in-plane angle, the first-order analytical solutions of librational angles are derived. Then, a typical lumped mass model is introduced to study the longitudinal and transverse vibration of the tether. Furthermore, the coupling effects between the tether librational and vibration characteristics are analyzed. Numerical simulation results indicate that during orbital transfer, librational angles maintain a uniform-amplitude pendular motion around the equilibrium position at a specific angular frequency determined by factors such as the length of the tether, the thrust acceleration and the geocentric distance. It may result in resonance of the librational angle when the pendular motion frequency of the in-plane angle approaches the angular frequency of the orbit, and a great transverse motion also occurs during orbital transfer.

Key words: tethered system, orbital transfer, dynamics, librational and vibrational characteristics, constant thrust

CLC Number:

V412.4

SUN Liang, ZHAO Guowei, HUANG Hai, ZHU Ouning. Analysis of Librational and Vibrational Characteristics for Tethered Systems During Orbital Transfer in Plane[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2012, 33(7): 1245-1254.

References

[1] Tyc G, Han R P S. Attitude dynamics investigation of the OEDIPUS-A tethered rocket payload. Journal of Spacecraft and Rockets, 1995, 32(1): 133-141.
[2] Tyc G, Vigneron F R, Jablonski A M, et al. Flight dynamics results from the OEDIPUS-C tether mission. AIAA-1996-3573, 1996.
[3] Krupa M, Poth W, Schagerl M. Modelling dynamics and control of tethered satellite systems. Nonlinear Dynamics, 2006, 43(1-2): 73-96.
[4] Burov A A, Troger H. The relative equilibria of an orbital pendulum suspended on a tether. Journal of Applied Mathematics and Mechanics, 2000, 64(5): 723-728.
[5] Kuma K D. Review of dynamics and control of nonelectrodynamic tethered satellite systems. Journal of spacecraft and Rockets, 2006, 43(4): 705-720.
[6] Cartmell M P, McKenzie D J. A review of space tether research. Progress in Aerospace Sciences, 2008, 44(1): 1-21.
[7] Misra A K, Modi V J. Dynamic and control of tethered satellite system. Acta Astronautica, 2008, 63(11-12): 1169-1177.
[8] Wen H, Jin D P, Hu H Y. Advances in dynamics and control of tethered satellite systems. Acta Mechanica Sinica, 2008, 24(3): 229-241.
[9] Mankala K K, Agrawal S K. Equilibrium-to-equilibrium maneuvers of flexible electrodynamic tethers in equatorial orbits. Journal of Spacecraft and Rockets, 2006, 43(3): 651-658.
[10] Corsi J, Iess L. Stability and control of electrodynamic tethers for deorbiting applications. Acta Astronautic, 2001, 48(5-18): 491-501.
[11] Fujii H A, Watanabe T, Taira W. An analysis of vibration and wave absorbing control of tether system. AIAA -2001-4003, 2001.
[12] Yamaigiwa Y, Hiragi E, Kishimoto T. Dynamic behavior of electrodynamic tether deorbit system on elliptical orbit and its control by Lorentz force. Aerospace Science and Technology, 2005(9): 366-373.
[13] Sun L, Zhao G W, Huang H, et al. Tether-dragging maneuver strategy and tether control method. Asia-Pacific International Symposium on Aerospace Technology, 2010.
[14] Pel醗z J, Andr閟 Y N. Dynamic stability of electrodynamic tethers in inclined elliptical orbits. Journal of Guidance, Control and Dynamics, 2005, 28(4): 611-622.
[15] Zhu R Z, Wang X G. Continuous constant thrust maneuver in polar coordinate system. Spacecraft Engineering, 2008, 17(2): 31-37.

Analysis of Librational and Vibrational Characteristics for Tethered Systems During Orbital Transfer in Plane

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