Magnetic Field-Dependent Reversal Effect of the Electromagnet- Induced Normal Stress of Magnetorheological Materials

  • Taixiang Liu
  • Yangguang Xu
  • Ke Yang
  • Lianghong Yan
  • Beicong Huang
  • Zhuo Zhang
  • Xiaodong Jiang
  • Hongwei Yan
DOI: https://doi.org/10.18282/mpc.v1i4.844
Keywords: Magnetorheological Material, Magnetorheological Finishing, Electromagn

Abstract

Magnetorheological (MR) materials are a type of magnetoactive smart materials, whose physical or mechanical properties can be altered by applying a magnetic field. In usual, MR materials can be prepared by mixing magnetic particles into non-magnetic matrices. In this work, the electromagnet-induced (or non-uniform magnetic field-induced) normal stress of MR materials is studied. It shows that the stress does not vary monotonically along with the enhancement of the applied magnetic field. There exists a field-dependent reversal effect of the variation of the stress. The reversal effect is thought resulting from that the ratio of interparticle repellent of parallel magnetic particles to the particle-electromagnet attraction gets enlarged along with the enhancement of the field.

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Published
2021-06-02
How to Cite
Liu, T., Xu, Y., Yang, K., Yan, L., Huang, B., Zhang, Z., Jiang, X., & Yan, H. (2021). Magnetic Field-Dependent Reversal Effect of the Electromagnet- Induced Normal Stress of Magnetorheological Materials. Materials Physics and Chemistry, 3(1), 1-6. https://doi.org/10.18282/mpc.v1i4.844
Issue
Vol. 3 No. 1 (2021)
Section
Original Research Articles

Copyright (c) 2021 Taixiang Liu, Yangguang Xu, Ke Yang, Lianghong Yan, Beicong Huang, Zhuo Zhang, Xiaodong Jiang, Hongwei Yan

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