An innovative multi-gap clutch based on magneto-rheological fluids and electrodynamic effects: magnetic design and experimental characterization

Rizzo, Rocco

doi:10.1088/0964-1726/26/1/015007

Cited by 33 publications

(18 citation statements)

References 11 publications

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“…Moreover, the assembly and maintenance of each components is not easy. In 2017, a new design method for the MRF clutch was reported (Rizzo, 2017). In this design method, the permanent FIGURE 1 | Design of multi-coil MRF brake (Shiao and Nguyen, 2013).…”

Section: Mrf Brake and Mrf Clutchmentioning

confidence: 99%

Magnetorheological Fluid Based Devices Reported in 2013–2018: Mini-Review and Comment on Structural Configurations

Phu

Choi

2019

Front. Mater.

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This paper presents a mini-review of magnetorheological (MRF) fluid-based devices (MRF devices in short) including the brake, clutch, damper, and the mount reported from 2013 to 2018. MRF devices are usually designed based on three operating modes of MRF: flow mode, shear mode and squeeze mode. Each mode has its own characteristics for the high performance of application systems. Therefore, numerous design configurations of MRF devices have been proposed by many researchers. In this article, among many different MRF devices such as MRF brake, clutch, damper and MRF mount proposed over the last 6 years are examined in the sense of their structural configuration and operating principles. Certain advantages and demerits of each MRF device are also discussed. In addition, some useful design guidelines of MRF devices, which are absolutely different from developed MRF devices so far, are provided to enhance design simplicity and control performance.

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Section: Mrf Brake and Mrf Clutchmentioning

confidence: 99%

Magnetorheological Fluid Based Devices Reported in 2013–2018: Mini-Review and Comment on Structural Configurations

Phu

Choi

2019

Front. Mater.

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“…Moghani and Kermani (2016) proposed a method to reduce the weight and power consumption of the MR clutch by dividing the magnetic field generation into two parts using a permanent magnet and a coil. Rizzo (2016) suggested a multi-spacing magnetorheological clutch that uses a permanent magnet to generate an additional electromagnetic torque to the torque transmitted by the magnetorheological fluid. Leong et al (2017) proposed the design of a magnetic coupler that can amplify shaft speed using magnetic pull.…”

Section: Introductionmentioning

confidence: 99%

Hybrid multi-plate magnetorheological clutch featuring two operating modes: Fluid coupling and mechanical friction

Park

Kim

et al. 2021

Journal of Intelligent Material Systems and Structures

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Recently, there has been a rising demand for high-performance clutches in mechanical systems owing to the development of industrial technologies. This paper, therefore, proposes a hybrid multi-plate Magnetorheological (MR) clutch that has both fluid coupling and mechanical friction modes. To reduce impact when the plates are in contact with each other, a fluid coupler’s operating mode was used at the beginning of the clutch operation. For this, torque modeling in each mode was induced based on the Bingham model of the MRF. Using the induced torque modeling and ANSYS Maxwell’s magnetic field analysis results, the design procedure for a multi-plate clutch was implemented. Based on the design results, a hybrid multi-plate MR clutch was manufactured. Finally, the performance of the manufactured MR clutch was evaluated using a torque tester. The assessment confirmed that the proposed torque modeling and simulation results mostly matched the test results.

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“…Also less commonly found are MRF clutches which only use permanent magnets. One of such devices was presented in [17], where a clutch was developed to serve as an auxiliary device in automotive applications. This MRF clutch uses mechanical means to place permanent magnets in one of two positions in order to engage or disengage the MRF clutch, achieving output torque values of up to 6.6 N•m.…”

Section: Introductionmentioning

confidence: 99%

Design of an Adjustable Fail-Safe MRF Clutch With a Novel Field Blocking Mechanism for Robotic Applications

Fernández

Chang

2021

IEEE Access

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A permanent magnet-based magnetorheological fluid clutch (MRF) with a novel field blocking mechanism for torque adjustment is presented in this article. Magnetostatic simulations were used to optimize the design of the MRF clutch so as to increase its performance. A magnetic flux density measurement setup was used to confirm the correctness of the magnetostatic simulations. The MRF clutch was then characterized by measuring the transmitted torque with different magnetization and input angular velocity conditions. In addition to this, a 3D printed gripper was used to test the use of the MRF clutch both in normal working conditions and as a torque-limiting fail-safe mechanism. A torque control system which used an unscented Kalman filter to produce a torque feedback signal was implemented to showcase the use of the gripper under normal conditions. A simulated failure case in which the driving actuator was driven at its maximum velocity was then used to test the MRF clutch as a fail-safe mechanism.

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An innovative multi-gap clutch based on magneto-rheological fluids and electrodynamic effects: magnetic design and experimental characterization

Cited by 33 publications

References 11 publications

Magnetorheological Fluid Based Devices Reported in 2013–2018: Mini-Review and Comment on Structural Configurations

Magnetorheological Fluid Based Devices Reported in 2013–2018: Mini-Review and Comment on Structural Configurations

Hybrid multi-plate magnetorheological clutch featuring two operating modes: Fluid coupling and mechanical friction

Design of an Adjustable Fail-Safe MRF Clutch With a Novel Field Blocking Mechanism for Robotic Applications

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