Study of a magnetorheological brake under compression-shear mode

Wang, Hongyun; Bi, Chen

doi:10.1088/1361-665x/ab5162

Cited by 28 publications

(26 citation statements)

References 32 publications

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“…(C) High-torque squeezing MRF brake (Wang et al, 2019a). (D) MRF brake with squeeze-shear mode (Wang and Bi, 2020). (E) Snake like robot with MRF actuators (Zhang D. et al, 2020).…”

Section: Figure 4 | (A)mentioning

confidence: 99%

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A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Hua

Liu

Li³

et al. 2021

Front. Mater.

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Magnetorheological fluid (MRF) is a kind of smart materials with rheological behavior change by means of external magnetic field application, which has been widely adopted in many complex systems of different technical fields. In this work, the state-of-the-art MRF based devices are reviewed according to structural configurations reported from 2018 to 2020. Based on the rheological characteristic, the MRF has a variety of operational modes, such as flow mode, shear mode, squeeze mode and pinch mode, and has unique advantages in some special practical applications. With reference to these operational modes, improved engineering mechanical devices with MRF are summarized, including brakes, clutches, dampers, and mounts proposed over these 3 years. Furthermore, some new medical devices using the MRF are also investigated, such as surgical assistive devices and artificial limbs. In particular, some outstanding advances on the structural innovations and application superiority of these devices are introduced in detail. Finally, an overview of the significant issues that occur in the MRF based devices is reported, and the developing trends for the devices using the MRF are discussed.

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“…(C) High-torque squeezing MRF brake (Wang et al, 2019a). (D) MRF brake with squeeze-shear mode (Wang and Bi, 2020). (E) Snake like robot with MRF actuators (Zhang D. et al, 2020).…”

Section: Figure 4 | (A)mentioning

confidence: 99%

“…performance, and a magnetic vane was set to ensure that a magnetic flux crosses both sides of the rotor, shown in Figure 4D (Wang and Bi, 2020). Utilizing the combined mode, the MRF device generated higher torque compared to those without compression.…”

Section: Figure 4 | (A)mentioning

confidence: 99%

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Hua

Liu

Li³

et al. 2021

Front. Mater.

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“…Despite the fact that MR brakes have been investigated repeatedly under compression-shear, many of the studies dealt with the stable characteristics of MR brakes under constant currents 19 – 23 , as briefly noted here. Patil et al have experimentally studied the influencing parameters of braking torque of MR brake in shear and squeeze mode 19 .…”

Section: Introductionmentioning

confidence: 99%

Transient behavior of compressed magnetorheological brake excited by step currents

Wang

Yong-ju

et al. 2021

Sci Rep

Self Cite

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Transient behavior of a magnetorheological brake excited by step currents under compression-shear mode has been experimentally studied. The results show that the amplitude of the applied current had little effect on the rising time of transient torque, while the rising time was significantly affected by the rotational speed, the compressive speed and the compressive strain position. The falling time of transient torque was independent of the amplitude of the applied current, the compressive speed and the compressive strain position, and it was affected by the rotational speed. The falling time of the transient torque was much shorter than the rising time by a step current. The transient process of MR brake applied as a step current was different from a stable process pre-applied at constant current in different particle chain structure forming processes. In addition, the compressive processes applied in one step current and randomly on/off current were compared and experimentally verified: the particle chains in two processes both experienced the same evolutionary of transient torque. The results achieved in this study should be properly considered in the design and control of magnetorheological brake under compression-shear mode.

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“…Nguyen et al [24] designed a multi-pole MR brake, which adopts multiple excitation coils evenly arranged to form multiple magnetic poles, further enhance the braking torque of the drum brake. Wang and Bi [25] designed a MR brake with compression shear mode. Under the conditions of high pressure and small damping gap, the braking torque was significantly improved.…”

Section: Introductionmentioning

confidence: 99%

Performance Analysis of Rotary Magnetorheological Brake With Multiple Fluid Flow Channels

et al. 2020

IEEE Access

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In order to solve the problems of low magnetic field utilization rate and low volume-torque ratio of the traditional magnetorheological (MR) brake under a volume constraint, a rotary MR brake with multiple fluid flow channels was proposed. The magnetic flux was guided into the external axial fluid flow channel by inserting a non-magnetic ring in the middle of the magnetic conduction sleeves which could improve the magnetic circuit structure greatly, the working area where the MR brake producing rheological effect was increased, and the effective damping gaps were also increased from two sections to four sections. The working principle of rotary MR brake was expounded and torque mathematical model was also deduced. The electromagnetic field was modeled and the distribution of magnetic flux density in multiple fluid flow channels was analyzed using finite element method. The prototypes of initial and optimal design were fabricated by using the obtained optimal geometric parameters. An experimental test system was setup to investigate the dynamic performance of the proposed rotary MR brake. The experimental results show that the maximum braking torque and torque ratio of the optimal MR brake are increased by 13.5% and 2.3% compared with the initial MR brake at the applied current of 1.8 A, respectively. At the same time, the variation trend of experimental and simulation results is basically consistent, and the rotational speed has almost no effect on the torque performance, which is conducive to the application of MR brakes under different working conditions. INDEX TERMS rotary MR brake; multiple fluid flow channels; optimal design; braking torque

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Study of a magnetorheological brake under compression-shear mode

Cited by 28 publications

References 32 publications

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

A Review on Structural Configurations of Magnetorheological Fluid Based Devices Reported in 2018–2020

Transient behavior of compressed magnetorheological brake excited by step currents

Performance Analysis of Rotary Magnetorheological Brake With Multiple Fluid Flow Channels

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