Chinese Journal of Mechanical Engineering >

2021 , Vol. 34 >Issue 5: 106 - 106

DOI: https://doi.org/10.1186/s10033-021-00627-7

Original Article

Influence of Novel Redirector with Bypass Damping on the Performance of Load-Sensing Steering System

  • Yuqi Wang ,
  • Xinhui Liu ,
  • Jinshi Chen ,
  • Dongyang Huo
Expand
  • School of Mechanical and Aerospace Engineering, Jilin University, Jilin, 130022, China

Received date: 2020-06-11

  Revised date: 2021-08-23

  Online published: 2022-03-22

Supported by

Supported by National Key Research and Development Program of China (Grant No. 2018YFB2000900).

Fold

Abstract

Load-sensing steering systems for articulated loaders are prone to large pressure shocks and oscillations during steering operations, affecting the system stability. An optimized structure of the redirector with bypass damping is proposed to improve this phenomenon. In this structure, orifices and throttle grooves are added to the traditional redirector. To control the steering load and working conditions, the steering load of the loader is replaced by a pressure regulating valve. Simulation and experimental results reveal that the redirector with bypass damping has better load-sensing characteristics than the traditional redirector. The peak output pressure shock caused by the load unit step signal decreases from 6.50 to 5.64 MPa, which means the pressure oscillation of the hydraulic system is reduced by 13.4%. The pressure fluctuation time can be reduced from 2.09 to 1.6 s, with a decrease rate of 23.4%. The output pressure oscillation decays swiftly, and the smoothness of the steering operation is improved significantly.

Key words: Articulated vehicle; Redirector; Load-sensing steering system; Pressure oscillation

Cite this article

Yuqi Wang , Xinhui Liu , Jinshi Chen , Dongyang Huo . Influence of Novel Redirector with Bypass Damping on the Performance of Load-Sensing Steering System[J]. Chinese Journal of Mechanical Engineering, 2021 , 34(5) : 106 -106 . DOI: 10.1186/s10033-021-00627-7

References

[1] X Yan, J Yang, L Quan. Co-simulation and experiment of wheel loader during operation process. Transactions of the Chinese Society of Agricultural Engineering, 2015, 31(16):102-109.
[2] X Wang, J Yang, L Quan, et al. A novel high-efficiency wheel loader power steering system with fault-tolerant capability. IEEE Transactions on Vehicular Technology, 2018, 67(10):9273-9283.
[3] Z Meng, H Zang. Analysis of hydraulic steering system of tracked all-terrain vehicles' articulated mechanism. AIP Conference Proceedings, 2018, 1955(1):030003-1-030003-7.
[4] T Xu, Y Shen, Y Huang, et al. Study of hydraulic steering process for articulated heavy vehicles based on the principle of the least resistance. IEEE/ASME Transactions on Mechatronics, 2019, 24(4):1662-1673.
[5] Zardin B, Borghi M, Gherardini F, et al. Modelling and simulation of a hydrostatic steering system for agricultural tractors. Energies, 2018, 11(1):230.
[6] D Lei, K Deng, YP Gong. The optimum design for pivot points of steering mechanism on HT25J wheel loader. 2011 International Conference on Consumer Electronics, Communications and Networks (CECNet), Xianning, China, April 16-28, 2011:2760-2763.
[7] T J Wang, J S Chen, F Zhao, et al. Combined simulation and test of hydraulic steering system. Journal of Jilin University (Engineering Science Edition), 2013, 43(3):607-612. (in Chinese)
[8] C Wang, Y Zhang, W Zhao. Multi-objective optimization of a steering system considering steering modality. Advances in Engineering Software, 2018, 126:61-74.
[9] K Kitahara, K Kazama, H Mouri. Design of a new steering system to solve the problem of steering operation during low speed driving. Mechanical Engineering Journal, 2019, 6(3):18-00386.
[10] Y Yin, S Rakheja, J Yang, et al. Design optimization of an articulated frame steering system. Proceedings of the Institution of Mechanical Engineers, Part D:Journal of Automobile Engineering, 2018, 232(10):1339-1352.
[11] B W Cao, X H Liu, W Chen, et al. Depth optimization analysis of articulated steering hinge position based on genetic algorithm. Algorithms, 2019, 12(3):55.
[12] AMICO D A. Pressure control in hydraulic power steering systems:division of fluid and mechatronic systems. Sweden:Linköping University. 2013:14-22.
[13] S Haggag, D Alstrom, S Cetinkunt, et al. Modeling, control, and validation of an electro-hydraulic steer-by-wire system for articulated vehicle applications. IEEE/ASME Transactions on Mechatronics, 2005, 10(6):688-692.
[14] K Heybroek, J Larsson, J O Palmberg. Mode switching and energy recuperation in open-circuit pump control. Tampere, Finland:Tampere Univ. Technol., 2009:197-209.
[15] N A Daher, M Ivantysynova. Energy analysis of a traditional steering technology that saves fuel and boosts efficiency. Energy Conversion and Management, 2014, 86:1059-1068.
[16] N A Daher, M Ivantysynova. Pump controlled steer-by-wire system. SAE Technical Papers, 2013:7.
[17] N A Daher. New steering concept for wheel loaders. The 9th International Fluid Power Conference, Aachen, Germany, March 24-26, 2014:112-117.
[18] G P Massarotti. Hydrostatic steering system and energy saving evaluation in idle regime. 10th JFPS International Symposium on Fluid Power, Fukuoka, Octorber 24-27, 2017:2A11-1-2A11-7.
[19] Y Yang, G Zhang, J Zha, et al. Design of automatic steering system based on direct connection of DC motor and full hydraulic steering gear. Transactions of the Chinese Society for Agricultural Machinery, 2020, 51(8):44-54+61.
[20] J Wang, P Hou, H Cai, et al. Continuous angle steering of an optically-controlled phased array antenna based on differential true time delay constituted by micro-optical components. Optics Express, 2015, 23(7):9432.
[21] L He, B Ma and C Zong. Fault-tolerance control strategy for the steering wheel angle sensor of a steer-by-wire vehicle. Chinese Journal of Automotive Engineering, 2015, 37(3):327-330, 345.
[22] W Z Zhao, Y J Li, C Y Wang. Robust control of hand wheel torque for active front steering system. Science China Technological Sciences, 2015, 58(1):107-116.
[23] M Khristamto, A Praptijanto, S Kaleg. Measuring geometric and kinematic properties to design steering axis to angle turn of the electric golf car. Energy Procedia, 2015, 68(1):463-470.
[24] A Dellamico, P Krus. Modeling, simulation, and experimental investigation of an electrohydraulic closed-center power steering system. IEEE/ASME Transactions on Mechatronics, 2015, 20(5):1-11.
[25] X Y Tian, ZC Yu, H Zhou, et al. The design research of the indigenous steering gear. 2016 Chinese Control and Decision Conference (CCDC)IEEE, 2016:6947-6952.
[26] L H Liang, L Y Wang, J F Wang. Energy-saving nonlinear friction compensation method for direct drive volume control flange-type rotary vane steering gear. IEEE Access, 2019, 7:15851-62.
[27] L Liang, L Wang, J Wang. The compensation for nonlinear friction of DDVC flange-type rotary vane steering gear. PLoS ONE, 2018, 13(11):e0207018.
[28] A DellAmico, P Krus. Modeling, simulation, and experimental investigation of an electrohydraulic closed-center power steering system. IEEE/ASME Transactions on Mechatronics, 2015, 20(5), 2452-2462.
[29] Q Q Lu. Simulation analysis and test of full hydraulic steering system for flow amplification. Hangzhou:Zhejiang University, 2010. (in Chinese)
[30] X H Liu, Q W Li, J S Chen, et al. Mathematical modeling and simulation of load-sensing priority valve. Journal of Jilin University (Engineering & Engineering Edition), 2015, 45(6):1817-1824.
[31] B Hu, C J Zhou, H B Wang, et al. Prediction and validation of dynamic characteristics of a valve train system with flexible components and gyroscopic effect. Mechanism and Machine Theory, 2021, 157:104222.
Options
Outlines

/

  Copyright © Chinese Journal of Mechanical Engineering, All Rights Reserved.
Powered by Beijing Magtech Co. Ltd,.