Nonlinear Dynamics of Multi-satellite Stack with Pre-tightening in Connection Mechanism

doi:10.3901/JME.260007

Abstract

Abstract: Multi-satellite stack represents a launch configuration well-suited for large-scale constellation deployment. Flat-panel satellites are interconnected through load-bearing columns distributed across the upper and lower layers, with axial preload applied to the top layer to compress the assembly. The connection surfaces between satellites introduce typical nonlinear structural dynamic behaviors. Consequently, establishing a reasonable equivalent model and accurately identifying the parameters of the connection surfaces are critical challenges in advancing this technology. To address these issues, this paper employs the constrained substructure super-element method to condense the flat-panel satellite model and the thin-layer element method to develop an equivalent model of the connection surfaces. The substructures are then assembled using constraint conditions to form a simplified finite element model of the entire assembly. A scaled physical model of the multi-satellite stack is designed to validate the finite element model and identify the parameters of the connection surfaces. Modal experiments are conducted to obtain the frequency response function under varying preload torques. The stiffness parameters of the connection surfaces are identified by optimizing the three modulus parameters of the thin-layer element material using the first three modal frequencies of the assembly as objectives. The damping parameters are identified by optimizing the damping coefficient of the thin-layer material using the first-order resonance peak amplitude of the frequency response function as the objective. Finally, the influence of preload torque on the nonlinear dynamic characteristics of the multi-satellite stack is analyzed through changes in the frequency response function.

Key words: multi-satellite stack, thin-layer element, nonlinear dynamics, satellite-rocket connection mechanism, parameter identification

CLC Number:

O321

LI Yuanheng, FAN Ruixiang, YANG Fan, ZHANG Hongjian, WU Huiqiang, CHEN Huawei. Nonlinear Dynamics of Multi-satellite Stack with Pre-tightening in Connection Mechanism[J]. Journal of Mechanical Engineering, 2026, 62(1): 125-136.

References

[1] HE Yuan,LI Zhuoyang,CHEN Yiqi.Tractable modelling and performance analysis of low earth orbit satellite constellations[J].IEEE Internet of Things Journal,2024,11(17):28297-28306.
[2] MCDOWELL J C.The low earth orbit satellite population and impacts of the SpaceX Starlink constellation[J].The Astrophysical Journal Letters,2020,892(2):L36.
[3] 李元恒,范瑞祥,杨帆,等.基于线性等效模型的堆叠式多星组合体模态分析[J].力学学报,2024,56(8):2364-2380.LI Yuanheng,FAN Ruixiang,YANG Fan,et al.Modal analysis of multi-satellite stack based on linear equivalent model[J].Chinese Journal of Theoretical and Applied Mechanics,2024,56(8):2364-2380.
[4] ZHAO Yong,ZHAO Qingguang,YANG Fei,et al.Design and analysis of a compression and separation device for multi-satellite deployment[J].Aerospace,2022,9(8):446.
[5] ZHANG Xiaoliang,SUN Jialiang,JIN Dongping,et al.Dynamics of reconfiguration and assembly of a stacked satellite system[J].Acta Astronautica,2024,218:367-382.
[6] 李艳辉,单悌磊,刘质加,等.侧挂式卫星-分配器一体化力学环境分析与试验验证[J].宇航学报,2024,45(8):1216-1224.LI Yanhui,SHAN Tilei,LIU Zhijia,et al.Mechanical environment analysis and test validation of the side-mounted satellite and dispenser integration[J].Journal of Astronautics,2024,45(8):1216-1224.
[7] YU Baoshi,ZHANG Dapeng,WU Xinfeng,et al.Optimal design of a clamp band system based on genetic algorithm and experimental verification[J].Aerospace Science and Technology,2024,145:108870.
[8] YU Baoshi,LEI Yongjun,WANG Zhixiang,et al.Lightweight design of a clamp band joint via a constrained sequential approximate optimization method in the irregular design domain[J].Engineering Optimization,2024,56(2):155-178.
[9] 王国辉,张宏剑,吴会强.运载火箭非火工分离机构技术发展与展望[J].宇航学报,2023,44(3):334-347.WANG Guohui,ZHANG Hongjian,WU Huiqiang.Development and prospect of non pyrotechnic separation mechanism technology for launch vehicles[J].Journal of Astronautics,2023,44(3):334-347.
[10] 张宏剑,于兵,吴会强,等.运载火箭机构技术发展研究[J].导弹与航天运载技术,2023(6):1-9.ZHANG Hongjian,YU Bing,WU Huiqiang,et al.Research on technology development of launch vehicle mechanism.Missiles and Space Vehicles,2023(6):1-9.
[11] 李元恒,范瑞祥,杨帆,等.堆叠式多星组合体结构设计与连接技术发展及展望[J].导弹与航天运载技术,2024(4):14-24.LI Yuanheng,FAN Ruixiang,YANG Fan,et al.Development and outlook of structural design and connection technology for multi-satellite stack[J].Missiles and Space Vehicles,2024(4):14-24.
[12] GHESMI M,BRINDLEY S.A nonlinear finite element method to assess loads on container stacks[J].Ocean Engineering,2021,235:109430.
[13] KIRKAYAK L,DE SOUZA V A,SUZUKI K,et al.On the vibrational characteristics of a two-tier scaled container stack[J].Journal of marine science and technology,2011,16:354-365.
[14] DE SOUZA V A,KIRKAYAK L,WATANABE I,et al.Experimental and numerical analysis of container multiple stacks dynamics using a scaled model[J].Ocean Engineering,2013,74:218-232.
[15] DE SOUZA V A,KIRKAYAK L,SUZUKI K,et al.Experimental and numerical analysis of container stack dynamics using a scaled model test[J].Ocean Engineering,2012,39:24-42.
[16] LI Chuntong,WANG Deyu,CAI Zhonghua.Experimental and numerical investigation of lashing bridge and container stack dynamics using a scaled model test[J].Marine Structures,2021,75:102846.
[17] LI Chuntong,WANG Deyu,LIU Jiaqi,et al.Experimental and numerical investigation on dynamic response of a four-tier container stack and lashing system subject to rolling and pitching excitation[J].Applied Ocean Research,2021,109:102553.
[18] LI Chuntong,WANG Deyu.Multi-objective optimisation of a container ship lashing bridge using knowledge-based engineering[J].Ships and Offshore Structures,2019,14(1):35-52.
[19] LI Chuntong,WANG Deyu,LIU Jiaqi.Numerical analysis and experimental study on the scaled model of a container ship lashing bridge[J].Ocean Engineering,2020,201:107095.
[20] LI Chuntong,WANG Deyu,LIU Jiaqi.Numerical simulation of container stacks dynamics under typical motion excitation[C]//International Conference on Offshore Mechanics and Arctic Engineering.American Society of Mechanical Engineers,2019,58783:V003T02A089.
[21] JAMIA N,JALALI H,TAGHIPOUR J,et al.An equivalent model of a nonlinear bolted flange joint[J].Mechanical Systems and Signal Processing,2021,153:107507.
[22] 李朝峰,乔瑞环,苗雪阳,等.螺栓连接界面非线性建模及其参数辨识方法研究[J].机械工程学报,2021,57(7):78-86.LI Chaofeng,QIAO Ruihuan,MIAO Xueyang,et al.Investigation on nonlinear modeling and model parameters identification of the interface of bolted joints[J].Journal of Mechanical Engineering,2021,57(7):78-86.
[23] 潘嘉诚,关振群,曾岩,等.柱壳结构螺栓法兰连接非线性刚度分析[J].机械工程学报,2021,57(1):28-39.PAN Jiacheng,GUAN Zhenqun,ZENG Yan,et al.Nonlinear stiffness analysis of bolted flange connection in cylindrical shell structure[J].Journal of Mechanical Engineering,2021,57(1):28-39.
[24] LI Dongwu,BOTTO D,LI Ruozhang,et al.Experimental and theoretical studies on friction contact of bolted joint interfaces[J].International Journal of Mechanical Sciences,2022,236:107773.
[27] SUN Jiaying,YANG Huiyi,LI Dongwu,et al.Analysis of friction-related acoustic emission in bolted joint structures[J].International Journal of Mechanical System Dynamics,2023,3(4):383-396.
[26] LI Dongwu,XU Chao,KANG Jiahao,et al.Modeling tangential friction based on contact pressure distribution for predicting dynamic responses of bolted joint structures[J].Nonlinear Dynamics,2020,101:255-269.
[27] SUN Delin,ZHAO Lingling,LIANG Guihang,et al.Prediction of bolted joint dynamics based on the thin-layer element of nonlinear material[J].Annales de Chimie Science des Matériaux,2019,43(5):311-315.
[28] MAHDIABADI M K,BARTL A,XU D,et al.An augmented free-interface-based modal substructuring for nonlinear structural dynamics including interface reduction[J].Journal of Sound and Vibration,2019,462:114915.
[29] LATINI F,BRUNETTI J,D'AMBROGIO W,et al.Nonlinear substructuring in the modal domain:numerical validation and experimental verification in presence of localized nonlinearities[J].Nonlinear Dynamics,2021,104:1043-1067.
[30] STAVRINIDIS C,FRANSEN S.An efficient method for preliminary launcher/satellite coupled loads analysis by satellite developers using launcher user's manual data[J].CEAS Space Journal,2016,8:13-21.
[31] WANG Zhi,FEI Chengwei,WANG Jianjun.Equivalent simulation of mechanical characteristics for parametric modeling of bolted joint structures[J].Advances in Mechanical Engineering,2017,9(6):1687814017704360.
[32] CHU Yongpeng,WEN Hao,CHEN Ti.Nonlinear modeling and identification of an aluminum honeycomb panel with multiple bolts[J].Shock and Vibration,2016,2016(1):1276753.
[33] EHRLICH C,SCHMIDT A,GAUL L.Reduced thin-layer elements for modeling the nonlinear transfer behavior of bolted joints of automotive engine structures[J].Archive of Applied Mechanics,2016,86:59-64.
[34] BOGRAD S,REUSS P,SCHMIDT A,et al.Modeling the dynamics of mechanical joints[J].Mechanical Systems and Signal Processing,2011,25(8):2801-2826.