In this paper, a torque feedback device (TFD) based on a magneto-rheological brake (MRB) is developed for haptic systems. The MRB-based TFD incorporates an innovative rectangular tooth-shaped (TS) magneto-rheological fluid channel. Key structural elements, such as the number of teeth, exciting coils, and tooth geometry, are optimized to enhance torque performance while minimizing energy consumption. Initially, four configurations of rectangular TSMRB-based TFDs are proposed, and the modeling and structural optimization are subsequently implemented, followed by a decision support for a specific haptic application case study. The configuration of double side coils and two teeth is demonstrated to be the most suitable in terms of dynamic range, power consumption and manufacturing feasibility compared to previous studies. A prototype of the optimal TSMRB-based TFD is then fabricated, and a closed-loop controller is designed and experiments are conducted to evaluate its feedback performance. The experimental responses of the TFD prototype show good agreement with a steady-state torque error of approximately 3.7%. The tracking control results for various input signals demonstrate effective performance at low frequencies, while reduced controllability at higher frequencies reflects the inherent hysteresis behavior of the MRF.
AcharyaSSainiTRSKumarH (2019) Optimal design and analyses of T-shaped rotor magnetorheological brake. IOP Conference Series Materials Science and Engineering624: 012024.
2.
ANSYS Inc (2021) DesignXplorer User’s Guide. ANSYS Inc.
3.
AttiaEMElsodanyNMEl-GamalHA, et al. (2017) Theoretical and experimental study of magneto-rheological fluid disc brake. Alexandria Engineering Journal56(2): 189–200.
4.
DiepBTNguyenQHLeTD (2022) Design and control of 2-DoF joystick using MR-fluid rotary actuator. Journal of Intelligent Material Systems and Structures33(12): 1562–1573.
5.
DongXLiuQLiP, et al. (2024) Performance analysis of the damper with built-in magnetorheological valve. Smart Materials and Structures33(1): 015004.
6.
EPS Division (2021) Rotary Seal Design Guide. Parker Hannifin Corporation.
7.
HoangLVNguyenQHBuiQD (2025) Design and performance evaluation of a multi-coil tooth-shaped MR brake for force feedback applications. Mechanisms and Machine Science177: 351–360.
8.
HooshiarAPayamiADargahiJ, et al. (2021) Magnetostriction-based force feedback for robot-assisted cardiovascular surgery using smart magnetorheological elastomers. Mechanical Systems and Signal Processing161: 107918.
9.
HuGWuLLiL (2021) Torque characteristics analysis of a magnetorheological brake with double brake disc. Actuators10(2): 23.
10.
JiangXWuKZhangY, et al. (2022) Improved vibration suppression modeling for reinforcement clamping by eco-friendly magnetorheological fluid during milling of annular thin-walled workpiece. International Journal of Precision Engineering and Manufacturing-Green Technology9(6): 1511–1526.
KennedySVlajicNPerkinsE (2024) Hybrid dynamical modeling of shape memory alloy actuators with phase kinetic equations. Journal of Intelligent Material Systems and Structures35(15): 1245–1260.
13.
LiangYHuangDZhouX, et al. (2023) Efficient electrorheological technology for materials, energy, and mechanical engineering: from mechanisms to applications. Engineering24: 151–171.
14.
MousaviSHSayyaadiH (2018) Optimization and testing of a new prototype hybrid MR brake with arc form surface as a prosthetic knee. IEEE/ASME Transactions on Mechatronics23(3): 1204–1214.
15.
NguyenNDNguyenTTLeDH, et al. (2021a) Design and investigation of a novel magnetorheological brake with coils directly placed on side housings using a separating thin wall. Journal of Intelligent Material Systems and Structures32(14): 1565–1579.
16.
NguyenQHNguyenVBLeHD, et al. (2021b) Development of a novel magnetorheological brake with zigzag magnetic flux path. Smart Materials and Structures30(12): 125028.
17.
NguyenVBLeHDNguyenQH, et al. (2022) Design and experimental evaluation a novel magneto-rheological brake with tooth shaped rotor. Smart Materials and Structures31(1): 015015.
18.
SenkalDGurocakH (2010) Serpentine flux path for high torque MRF brakes in haptics applications. Mechatronics20(3): 377–383.
19.
ShiaoYHuynhT-L (2023) Design and optimization of a new flow-mode magnetorheological mount with compact structure and extended workable force. Journal of Intelligent Material Systems and Structures34(20): 2404–2413.
20.
ShiaoYKantipudiMB (2022) High torque density magnetorheological brake with multipole dual disc construction. Smart Materials and Structures31(4): 045022.
21.
ShiaoYNgocNALaiC-H (2016) Optimal design of a new multipole bilayer magnetorheological brake. Smart Materials and Structures25(11): 115015.
22.
SinghRKSarkarC (2023) Two-wheeler magnetorheological drum brake operating under hybrid mode for enhancing braking torque: Development and validation. Mechatronics92: 102971.
23.
SohnJWGangHGChoiS-B (2018) An experimental study on torque characteristics of magnetorheological brake with modified magnetic core shape. Advances in Mechanical Engineering10(1): 1–8.
24.
WangSGeYChenW, et al. (2024) A dynamic analytical model on electrical circuit response of magnetorheological clutch. Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science238(6): 1968–1977.
25.
WellbornPMitchellJPieperN, et al. (2022) Design and analysis of a small-scale magnetorheological brake. IEEE/ASME Transactions on Mechatronics27(5): 3099–3109.
26.
WuJLiHJiangX, et al. (2018) Design, simulation and testing of a novel radial multi-pole multi-layer magnetorheological brake. Smart Materials and Structures27(2): 025016.
27.
YangGYaoLDongT, et al. (2024a) Design and performance evaluation of a multi-disc magnetorheological fluid brake for A00-class minicars. Journal of Intelligent Material Systems and Structures35(1): 99–113.
28.
YangJMaoYQuB, et al. (2024b) Dynamic responses of normal and partially failed piezoelectric stack actuators under sinusoidal voltages with DC biasing. Smart Materials and Structures33(9): 095004.
29.
YangXCaoZLiuG, et al. (2023) Structural design and experimental study of multi-ring and multi-disc magnetorheological valve. Smart Materials and Structures32(4): 045011.
30.
YinXWuCWenS, et al. (2021) Smart design of Z-Width expanded thumb haptic interface using magnetorheological fluids. IEEE Transactions on Instrumentation and Measurement70: 1–11.
31.
YuJDongXSuX, et al. (2022) Development and characterization of a novel rotary magnetorheological fluid damper with variable damping and stiffness. Mechanical Systems and Signal Processing165: 108320.
