Dynamic Performance of Radial Flow Magneto-Rheological Valve and Damping Performances of Valve-Controlled Cylinder System

被引：0

作者：

Hu G.-L. ^{[1
]}

Zhang J.-W. ^{[1
]}

Yu L.-F. ^{[1
]}

Zhong F. ^{[1
]}

机构：

[1] Key Laboratory of Conveyance and Equipment, Ministry of Education, East China Jiaotong University, Nanchang, 330013, Jiangxi

来源：

Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology | 2019年 / 39卷 / 11期

关键词：

Dynamic performance; MR valve-controlled cylinder system; Pressure drop ability; Radial flow MR valve;

D O I：

10.15918/j.tbit1001-0645.2018.182

中图分类号：

学科分类号：

摘要：

In order to improve the pressure drop ability of the magneto-rheological (MR) valve, a radial flow MR valve with higher pressure drop ability was proposed. Firstly, the working principle was analyzed in detail and a mathematical model of radial flow MR valve was established. And then, a dynamic test system was constructed to test the pressure drop and response time of the radial flow MR valve under different applied direct currents and flow rates. The experimental results show that the pressure drop is 3.2 MPa at the applied direct current of 1.2 A, and the response time is between 100 ms and 150 ms. Finally, the damping performances of the radial flow MR valve-controlled cylinder system were analyzed. The damping performance tests were carried out under different applied direct currents, frequencies, and amplitudes. The experimental results show that, the system can output a larger damping force, and the maximum damping force can reach 5 kN. Furthermore, the damping force can be continuously adjusted under the different applied direct current, and the adjustable range is wider too. The effects of piston velocity on the damping force are little, and the system can generate stable damping forces in a variety of operating conditions. © 2019, Editorial Department of Transaction of Beijing Institute of Technology. All right reserved.

引用

页码：1118 / 1125

页数：7

共 20 条

[1] Zhu X., Jing X., Cheng L., Optimal design of control valves in magnetorheological fluid dampers using a nondimensional analytical method, Journal of Intelligent Material Systems and Structures, 24, 1, pp. 108-129, (2013)
[2] Abd Fatah A.Y., Mazlan S.A., Koga T., Et al., A review of design and modeling of magnetorheological valve, International Journal of Modern Physics B, 29, 4, (2015)
[3] Imaduddin F., Mazlan S.A., Zamzuri H., Et al., Design and performance analysis of a compact magnetorheological valve with multiple annular and radial gaps, Journal of Intelligent Material Systems and Structures, 26, 9, pp. 1038-1049, (2015)
[4] Yoo J.H., Wereley N.M., Design of a high-efficiency magnetorheological valve, Journal of Intelligent Material Systems and Structures, 13, 10, pp. 679-685, (2002)
[5] Aydar G., Wang X., Gordaninejad F., A novel two-way-controllable magneto-rheological fluid damper, Smart Materials and Structures, 19, 6, (2010)
[6] Hu G., Long M., Huang M., Et al., Design, analysis, prototyping, and experimental evaluation of an efficient double coil magnetorheological valve, Advances in Mechanical Engineering, 6, 8, (2014)
[7] Artur G., Abdul-Ghani O., Design of magneto-rheological (MR) valve, Sensors and Actuators A: Physical, 148, 1, pp. 211-223, (2008)
[8] Wang D.H., Ai H.X., Liao W.H., Amagnetorheological valve with both annular and radial fluid flow resistance gaps, Smart Materials and Structures, 18, 11, (2009)
[9] Imaduddin F., Mazlan S.A., Rahman M.A.A., Et al., A high performance magnetorheological valve with a meandering flow path, Smart Materials and Structures, 23, 6, (2014)
[10] Hu G., Long M., Yu L., Et al., Design and performance evaluation of a novel magnetorheological valve with a tunable resistance gap, Smart Materials and Structures, 23, 12, (2014)

← 1 2 →