An Innovative Design of Magnetorheological Lateral Damper for Secondary Suspension of a Train

International Journal of Sustainable Transportation Technology Pub Date : 2019-10-31 DOI:10.31427/ijstt.2019.2.2.2

A. Masa’id, U. Ubaidillah, B. W. Lenggana, N. Muhayat, W. Wibowo, S. Mazlan

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引用次数: 1

Abstract

This article delivered an innovative idea of a magnetorheological (MR) damper for secondary suspension of train bogie. The valve inside MR damper adopted meandering of both fluid flow and magnetic flux for improving magnetization area. In this work, the design and working principle of the MR valve were presented including a mathematical model to predict the pressure drop. In the early stage, the finite element method magnetics software (FEMM) simulation could predict the magnetic flux density across the passages. Based on the amount of magnetic flux, the corresponding shear yield stress could be determined from its basic physical properties. The mathematical model covered pressure drop prediction for both off-state and on-state. The FEMM simulation results showed that the meandering flow and serpentine flux design could improve the effective area of magnetization. Consequently, the pressure drop of the valve could have wider ranges and achieve a high value of pressure differences. This result could be potentially improving the performance of the damping forces of the lateral damper in a bogie train.

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列车二次悬架磁流变侧向阻尼器的创新设计

提出了一种用于列车转向架二次悬挂的磁流变阻尼器的创新思想。磁流变阻尼器内阀采用了流体流动和磁通的弯曲，提高了磁化面积。本文介绍了磁流变阀的设计和工作原理，并建立了预测压降的数学模型。前期利用有限元法磁学软件(FEMM)仿真可以预测通道内的磁通密度。根据磁通的大小，可以根据材料的基本物理性质确定相应的剪切屈服应力。该数学模型涵盖了开关状态下的压降预测。FEMM仿真结果表明，弯曲流和蛇形磁通设计可以提高有效磁化面积。因此，阀的压降可以有更大的范围，实现高的压差值。这一结果可能会潜在地改善横向减振器在转向架列车上的阻尼力性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Sustainable Transportation Technology

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