https://doi.org/10.22190/FUME211028008Y

341

361

In this paper, the excavator’s dynamic performance is considered together with the study of its trajectory, stress distribution and vibration. Many researchers have focused their study on the kinematics principle while a few others focused their work on dynamic performance, especially the vibration analysis. Previous studies of dynamic performance analysis have ignored the vibration effects. To address these challenges, the rigid-flexible coupling model of the excavator attachment is established and carried out based on virtual prototyping in this study. The dipper handle, the boom and the hoist rope are modeled as a flexible multi-body system for structural strength. The other components are modeled as a rigid multi-body system to catch the dynamic characteristics. The results show that the number of flexible bodies has little effect on the excavation trajectory. The maximum stress determined for the dipper handle and the boom are 96.45 MPa and 212.24 MPa, respectively. The dynamic performance of the excavator is greatly influenced by the clearance and is characterized by two phases: as the clearance decreases, the dynamic response decreases at first and then increases.

Excavator, Dynamics, Virtual Prototype, Rigid-flexible Coupling

Li, Y., Liu, W., 2013, Dynamic dragline modeling for operation performance simulation and fatigue life prediction， Engineering Failure Analysis, 34, pp. 93-101.

Li, Y., Frimpong, S., 2008, Hybrid virtual prototype for analyzing cable shovel component stress, The International Journal of Advanced Manufacturing Technology, 37(5), pp. 423-430 .

Jovanović, V., Janošević, D., Pavlović, J., 2021, Analysis of the influence of the digging position on the loading of the axial bearing of slewing platform drive mechanisms in hydraulic excavators, Facta Universitatis-Series Mechanical Engineering, 19(4), pp. 705-718.

Mitrev, R., Marinković, D., 2019, Numerical study of the hydraulic excavator overturning stability during performing lifting operations, Advances in Mechanical Engineering, 11(5), doi: 10.1177/1687814019841779.

Li, Y., Chang, S.S., 2013, Liu, W., Spatial kinematics and virtual prototype modeling of Bucyrus shovel, International Journal of Advanced Manufacturing Technology, 69(5-8), pp. 1917-1925.

Awuah-Offei, K., Frimpong, S., 2007, Cable shovel digging optimization for energy efficiency, Mechanism and machine theory, 42(8), pp. 995-1006.

Šalinić, S., Bošković, G., Nikolić, M., 2014, Dynamic modelling of hydraulic excavator motion using Kane's equations, Automation in Construction, 44, pp. 56-62.

Awuah-Offei, K., Frimpong, S., 2006, Numerical simulation of cable shovel resistive forces in oil sands excavation, International Journal of Surface Mining, Reclamation and Environment, 20(3), pp. 223-238.

Mitrev, R., Janošević, D., Marinković, D., 2017, Dynamical modelling of hydraulic excavator considered as a multibody system, Tehnicki Vjesnik, 24, pp. 327-338.

Ding, H, Han, L, Yang, W, et al., 2017, Kinematics and dynamics analyses of a new type face-shovel hydraulic excavator, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 231(5): 909-924.

Ma, M.H, 2009, Research on dynamic characteristics of working equipment of mining excavator, Master Thesis, Jilin University.

He, B., Zhou, G.F., Hou, S. C., Zeng, L., 2017, Virtual prototyping-based fatigue analysis and simulation of crankshaft, The International Journal of Advanced Manufacturing Technology, 88(9-12), pp. 2631-2650.

He, B., Tang, W., Cao, J.T., 2014, Virtual prototyping-based multibody systems dynamics analysis of offshore crane, The International Journal of Advanced Manufacturing Technology, 75(1-4), pp. 161-180

Jiang, M., Liao, S., Guo, Y., Wu, J., 2019, The improvement on vibration isolation performance of hydraulic excavators based on the optimization of powertrain mounting system, Advances in Mechanical Engineering, 11(5), doi: 10.1177/1687814019849988.

Strzalka, C., Marinkovic, D., Zehn, M.W., 2021, Stress mode superposition for a priori detection of highly stressed areas: mode normalisation and loading influence, Journal of Applied and Computational Mechanics, 7(3), pp. 1698-1709.

Strzalka, C., Zehn, M., 2020, The influence of loading position in a priori high stress detection using mode superposition, Reports in Mechanical Engineering, 1(1), pp. 93-102.

Zhao, H , Wang, G.Q., Wang, H.T., Bi, Q.S., Li, X.F., 2017, Fatigue life analysis of crawler chain link of the excavator, Engineering Failure Analysis, 79, pp. 737-748.

Zhang, Y.Z., Wang, Y.T., 2008, Co-simulation of Flexible Body Based on ANSYS and ADAMS, Journal of system simulation, 20, pp. 4501-4504.

Khemili, I., Romdhane, L., 2008, Dynamic analysis of a flexible slider-crank mechanism with clearance, European Journal of Mechanics-A/Solids, 27(5), pp. 882-898.

Yuan, Y.L., Yang, Z., Wang, S.H., Li, X.F., 2014, The Application and Analysis of Gear Train in the Turnover Mechanism. Packaging Engineering, 17(9), pp. 86-90.

Chen, Y., Sun, Y., Chen, C., 2016, Dynamic analysis of a planar slider-crank mechanism with clearance for a high speed and heavy load press system, Mechanism and Machine Theory, 98, pp. 81-100.