谭述君

个人信息Personal Information

教授

博士生导师

硕士生导师

性别:男

毕业院校:大连理工大学

学位:博士

所在单位:力学与航空航天学院

学科:动力学与控制. 航空航天力学与工程. 飞行器设计

联系方式:壹叁肆柒捌玖柒壹零玖肆

电子邮箱:tansj@dlut.edu.cn

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Coupling dynamics of super large space structures in the presence of environmental disturbances

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论文类型:期刊论文

发表时间:2018-07-01

发表刊物:ACTA ASTRONAUTICA

收录刊物:SCIE

卷号:148

页面范围:385-395

ISSN号:0094-5765

关键字:Super large space structure; Flexible beam; Coupling dynamics; Gravity gradient; Solar radiation pressure; Thermal radiation

摘要:Considering the effects of the gravity gradient, the solar radiation pressure (SRP) and the thermal radiation, the coupling dynamical model is established for a super large flexible beam structure, which moves in the orbital plane around the earth. The effects of environmental disturbances on the orbital motion, the attitude motion and the structural vibration are analyzed simultaneously. Influences of the initial attitude angle, the structure size and other system parameters have been investigated for the coupling dynamics. The results show that the envelop shapes of the vibration responses are dependent on the attitude motion, and the perturbation of orbital motion increases with the growth of the initial attitude angle. When the structural fundamental frequency is close to the attitude frequency with the increase of the structure size, the average orbit altitude would decrease slightly. The main frequency component of the attitude motion decreases and the frequency component related to the structural vibration encounters and grows up. The resonance then leads to system instability. Moreover, the magnitude of the attitude motion can also be influenced by the slightly intense structural vibration, which might be excited by the momentum exchange devices of the attitude control system. In addition, in the presence of the SRP, the orbital radius is perturbed obviously and the eccentricity of orbital motion is generally changed. The effects of the thermal radiation and the gravity gradient are in the same order of magnitude on the structural vibration in the low orbit while the former one turns to be dominant in geostationary orbit.