Surrogate Model Based Fast Solution Method for Dynamics of Mechanisms with Friction

doi:10.3901/JME.2025.04.323

Abstract

Abstract: Joint friction has a significant impact on the dynamical behavior of the mechanism. In scenarios where heavy loads or mechanisms have ball hinges, components are commonly connected by sliding joints, whose joint friction are related to the reaction force, and therefore the reaction force cannot be eliminated in the dynamical equations in generalized coordinate form. This leads to a forward dynamics described by differential-algebraic equations with too many unknown variables, and the real-time solution of the dynamical equations cannot be easily achieved. To address this problem, a surrogate model based fast solution method for dynamics of mechanisms with friction is proposed. Firstly, the smooth dynamical equations with continuous Stribeck friction model related to the reaction force are formulated. Secondly, the surrogate model is constructed by using a single hidden layer neural network to simplify the forward dynamics equations into ordinary differential equations, which greatly reduces the unknown variables that need to be solved. Finally, the effectiveness and superiority of the proposed method are verified by the hydraulic lifting system of the segment assembly robot. The numerical solutions prove that the proposed method significantly improves the calculation efficiency with guaranteed accuracy, with a maximum error of 0.023 4 mm and an average saving of 99.89% of the solution time.

Key words: mechanism dynamics, friction model, surrogate model, fast solution

CLC Number:

TH113

WEI Qi, TAO Jianfeng, SUN Hao, Xu Shuang, LIU Chengliang. Surrogate Model Based Fast Solution Method for Dynamics of Mechanisms with Friction[J]. Journal of Mechanical Engineering, 2025, 61(4): 323-332.

References

[1] 王庚祥，刘宏昭，龚春园，等. 考虑关节摩擦效应的并联机构动力学分析[J]. 农业机械学报，2013，44(11):308-315. WANG Gengxiang，LIU Hongzhao，GONG Chunyuan，et al. Dynamics analysis of parallel mechanism with joint friction[J]. Transactions of the Chinese Society for Agricultural Machinery，2013，44(11):308-315.
[2] 段书用，李昌洛，韩旭，等. 机械臂动力学分析及关节非线性摩擦模型建立[J]. 机械工程学报，2020，56(9):18-28. DUAN Shuyong，LI Changluo，HAN Xu，et al. Forward-inverse dynamics analysis of robot arm trajectories and development of a nonlinear friction model for robot joints[J]. Journal of Mechanical Engineering，2020，56(9):18-28.
[3] LIU Dongyu，LIU Hong，HE Yu，et al. Research on flexible joint friction identification of space lab manipulator[C]//Proceedings of the 2018 IEEE International Conference on Mechatronics and Automation (ICMA)，2018:614-619.
[4] LIU Guanghui，LI Qiang，FANG Lijin，et al. A new joint friction model for parameter identification and sensor-less hand guiding in industrial robots[J]. Industrial Robot，2020，47(6):847-857.
[5] HE Y，WANG C，BAO S，et al. A joint friction model of robotic manipulator for low-speed motion[C]//Proceedings of the 2021 IEEE International Conference on Robotics and Biomimetics (ROBIO)，Sanya，China，2021:545-550.
[6] 张彦斐，金鹏，宫金良，等. 3-RPS并联机器人粘性摩擦工况动力学建模[J]. 农业机械学报，2018，49(9):374-381. ZHANG Yanfei，JIN Peng，GONG Jinliang，et al. Dynamic modeling of 3-RPS parallel robot considering joint friction[J]. Transactions of the Chinese Society for Agricultural Machinery，2018，49(9):374-381.
[7] GUO Feng，CHENG Gang，PANG Yusong. Explicit dynamic modeling with joint friction and coupling analysis of a 5-DOF hybrid polishing robot[J]. Mech Mach Theory，2022，167:104509.
[8] JAVANFAR A，BAMDAD M. Effect of novel continuous friction model on nonlinear dynamics of the mechanisms with clearance joint[J]. Proceedings of the Institution of Mechanical Engineers，Part C: Journal of Mechanical Engineering Science，2022，236(11):6040-6052.
[9] FRACZEK J，WOJTYRA M. On the unique solvability of a direct dynamics problem for mechanisms with redundant constraints and Coulomb friction in joints[J]. Mech Mach Theory，2011，46(3):312-334.
[10] SAHA S. Dynamics of serial multibody systems using the decoupled natural orthogonal complement matrices[J]. Journal of Applied Mechanics，1999，66(4):986-996.
[11] SCHIEHLEN W. Computational dynamics:Theory and applications of multibody systems[J]. European Journal of Mechanics A-Solids，2006，25(4):566-594.
[12] 陈根良，王皓，来新民，等. 基于广义坐标形式牛顿-欧拉方法的空间并联机构动力学正问题分析[J]. 机械工程学报，2009，45(7):41-48. CHEN Genliang，WANG Hao，LAI Xinmin，et al. Forward dynamics analysis of spatial parallel mechanisms based on the newton-euler method with generalized coordinates[J]. Journal of Mechanical Engineering，2009，45(7):41-48.
[13] SUSUKI Y. On koopman operator framework for semi-explicit differential-algebraic equations[J]. IFAC-PapersOnLine，2021，54(14):341-345.
[14] FABIANI G，GALARIS E，RUSSO L，et al. Parsimonious physics-informed random projection neural networks for initial-value problems of ODEs and index-1 DAEs[J]. Chaos，2023，33(4):043128.
[15] MOYA C，LIN G. DAE-PINN:A physics-informed neural network model for simulating differential algebraic equations with application to power networks[J]. Neural Computing and Applications，2022，35(5):3789-3804.
[16] STIASNY J，MISYRIS G S，CHATZIVASILEIADIS S. Physics-informed neural networks for non-linear system identification for power system dynamics[C]//Proceedings of the 2021 IEEE Madrid PowerTech，2021:1-6.
[17] 丁千，翟红梅. 机械系统摩擦动力学研究进展[J]. 力学进展，2013，43(1):112-131. DING Qian，QU Hongmei. The advance in researches of friction dynamics in mechanics system[J]. Advances in Mechanics，2013，43(1):112-131.
[18] SPECKER T，BUCHHOLZ M，DIETMAYER K. A new approach of dynamic friction modelling for simulation and observation[J]. IFAC Proceedings Volumes，2014，47(3):4523-4528.
[19] SCHWEIZER B，LI P. Solving differential-algebraic equation systems:Alternative index-2 and index-1 approaches for constrained mechanical systems[J]. Journal of Computational and Nonlinear Dynamics，2016，11(4):044501.
[20] MCKAY M D，BECKMAN R J，CONOVER W J. Comparison of three methods for selecting values of input variables in the analysis of output from a computer code[J]. Technometrics，1979，21(2):239-245.