Magneto-hydrodynamic coupling modeling of a pinch-mode magnetorheological valve with multiple non-magnetic edges

Abstract

The magnetorheological effect of the pinch-mode magnetorheological valve (pinch-mode MR valve) depends on the complex coupling between nonlinear gradient magnetic fields and magnetorheological fluids, especially for the configuration with multiple non-magnetic edges, which is rarely investigated. In this study, a magneto-hydrodynamic coupling model of pinch-mode MR valve with multiple non-magnetic edges is established to capture the interactions between non-uniform magnetic fields and hydrodynamic behavior, firstly. Secondly, the experimental data of pressure drop between the inlet and outlet is utilized to verify the model accuracy. The comparison results show that the established model, considering the wall movement to describe the flow separation of MR flow dynamics caused by the pinch effect, can describe the variable properties of the viscous damping and pre-yield damping with different magnetic fields and fluid flow with relative agreement. Finally, through the parameter sensitivity analysis based on the established model, it is shown that the pinch-mode MR valve with about 6.5 mm channel diameter can provide a better performance in absolute pressure drop adjustment range and pinch effect. Besides, the width of the coil bracket can be utmost designed without the magnetic saturation in steel yoke, improving the damping properties of the pinch-mode MR valve.

Keywords

MR valve pinch-mode magneto-hydrodynamic coupling modeling parameter sensitivity analysis

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References

Allen

JRL

(1982) An outline of flow separation. In: Allen

JRL

(ed.) Developments in Sedimentology, vol. 30. Part B Elsevier. pp. 101–131.

Balak

Mazumdar

(2021) Bistable valves for MR fluid-based soft robotic actuation systems. IEEE Robotics and Automation Letters 6(4): 8285–8292.

Chang

(1970) Introduction to the problems of flow separation. In: Chang

(ed.) Separation of Flow. Pergamon. pp. 1–54.

Elsaady

Oyadiji

Nasser

(2020) A one-way coupled numerical magnetic field and CFD simulation of viscoplastic compressible fluids in MR dampers. International Journal of Mechanical Sciences 167: 105265.

Frigaard

Nouar

(2005) On the usage of viscosity regularisation methods for visco-plastic fluid flow computation. Journal of Non-Newtonian Fluid Mechanics 127(1): 1–26.

Guzmán

Salgado

Sayas

(2013) A note on the Ladyženskaja-Babuška-Brezzi condition. Journal of Scientific Computing 56(2): 219–229.

Hauke

Hughes

TJR

(1994) A unified approach to compressible and incompressible flows. Computer Methods in Applied Mechanics and Engineering 113(3-4): 389–395.

Hsiao

Lim

Huang

(2010) On the near-field flow structure and mode behaviors for the right-angle and sharp-edged orifice plane jet. Experimental Thermal and Fluid Science 34(8): 1282–1289.

Hughes

TJR

Mallet

(1986) A new finite element formulation for computational fluid dynamics: III. The generalized streamline operator for multidimensional advective-diffusive systems. Computer Methods in Applied Mechanics and Engineering 58(3): 305–328.

10.

Deng

, et al. (2021) Damping performance analysis of magnetorheological damper based on multiphysics coupling. Actuators 10(8): 176.

11.

Ying

, et al. (2023) Design, analysis and optimization of a hybrid fluid flow magnetorheological damper based on multiphysics coupling model. Mechanical Systems and Signal Processing 205: 110877.

12.

Zhou

Yang

, et al. (2024) Analysis of pressure drop and response characteristics of an enhanced radial magnetorheological valve based on magneto-fluidic coupling. Journal of Magnetism and Magnetic Materials 589: 171589.

13.

Jayaraman

Palanisamy

Thangaraj

(2023) Hydraulic control valve integrated novel semi active roll resistant interconnected suspension with vertical and roll coordinated control scheme. Proceedings of the Institution of Mechanical Engineers Part D Journal of Automobile Engineering 237(1): 98–111.

14.

Kubík

Gołdasz

Macháček

, et al. (2023) Magnetorheological fluids subjected to non-uniform magnetic fields: Experimental characterization. Smart Materials and Structures 32(3): 035007.

15.

Kubík

Macháček

Strecker

, et al. (2017) Design and testing of magnetorheological valve with fast force response time and great dynamic force range. Smart Materials and Structures 26(4): 047002.

16.

Kubík

Žáček

Gołdasz

, et al. (2024) Grasping the behavior of magnetorheological fluids in gradient pinch mode via microscopic imaging. Physics of Fluids 36(4): 042004.

17.

Lee

Kang

Choi

(2019) A quasi-static model for the pinch mode analysis of a magnetorheological fluid flow with an experimental validation. Mechanical Systems and Signal Processing 134: 106308.

18.

Lin

Yang

, et al. (2025) Design, experiment and modeling of a damper based on magnetic gradient pinch mode MR valve. Smart Materials and Structures 34(1): 015053.

19.

Liu

Yang

, et al. (2023) Study on the structural design and performance of magnetorheological (MR) valve with hybrid supply magnetic source and double annular channels. Journal of Magnetism and Magnetic Materials 570: 170506.

20.

Zhang

Guo

, et al. (2016) A novel squeeze mode based magnetorheological valve: Design, test and evaluation. Smart Materials and Structures 25(12): 127003.

21.

Ntella

Thabuis

Tiwari

, et al. (2023) Highly efficient miniaturized magnetorheological valves using electropermanent magnets. IEEE Robotics and Automation Letters 8(3): 1487–1494.

22.

Papanastasiou

(1987) Flows of materials with yield. Journal of Rheology 31(5): 385–404.

23.

Ruan

Xuan

Zhao

, et al. (2020) Mechanical performance of a novel magnetorheological fluid damper based on squeeze-valve bi-mode of MRF. Smart Materials and Structures 29(5): 055018.

24.

Sapiński

Macháček

Kubík

, et al. (2024) True pinch mode of magnetorheological fluids. Smart Materials and Structures 33(11): 115045.

25.

Žáček

Goldasz

Sapinski

, et al. (2023) Assessment of the dynamic range of magnetorheological gradient pinch-mode prototype valves. Actuators 12(12): 449.

26.

Zhu

, et al. (2024) Experimental and numerical analysis of magnetorheological valve based on Herschel–Bulkley–Papanastasiou model. Journal of Magnetism and Magnetic Materials 602: 172169.