Design, Analysis, and Characterization of a Small-Scale High-Torque Magnetorheological Brake for Haptic Applications.

IF 2.8 3区计算机科学 Q2 COMPUTER SCIENCE, CYBERNETICS

IEEE Transactions on Haptics Pub Date : 2026-05-05 DOI:10.1109/TOH.2026.3690458

Yiting Mo, Aiguo Song, Huanhuan Qin, Fernando Bello

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引用次数: 0

Abstract

Achieving both high torque for convincing kinesthetic feedback and a compact form factor for user comfort in magnetorheological (MR) actuators remains challenging due to the rapid degradation of torque with reduced dimensions. To address this limitation, a small-scale, high-torque MR brake with a novel dual multi-drum configuration is proposed for haptic applications. In this configuration, two identical multi-gap MR shear regions are located on both sides of an electromagnetic coil. Once an excitation is applied, the MR shear regions are simultaneously activated, effectively maximizing active shear areas within the limited volume. This configuration facilitates a significant torque output without compromising the brake's compactness. The optimized brake prototype has compact dimensions of Ø29.2×44 mm and a mass of 171.5 g, with a peak torque of 1165.4 mN$\cdot$m. The torque-to-volume and torque-to-mass ratios are 39.6 kN/m$^{2}$ and 6.8 mN$\cdot$m/g, respectively, which are higher than those of other MR brakes of comparable size. In a practical scenario, a handheld haptic device based on the brake prototype was constructed. The experimental results demonstrated controllable torque rendering, with a just noticeable difference of 54.18 $\pm$ 17.73 mN$\cdot$m and a Weber fraction of 11.91 $\pm$ 3.90%, thereby highlighting its potential for small-scale, high-torque haptic actuation.

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用于触觉应用的小型大扭矩磁流变制动器的设计、分析和特性。

在磁流变（MR）致动器中实现高扭矩以获得令人信服的动觉反馈和紧凑的外形因素，由于扭矩随尺寸减小而迅速退化，因此仍然具有挑战性。为了解决这一限制，提出了一种小型，高扭矩MR制动器，具有新颖的双多鼓配置，用于触觉应用。在这种结构中，两个相同的多间隙MR剪切区位于电磁线圈的两侧。一旦施加激励，MR剪切区域同时被激活，有效地最大化有限体积内的活性剪切区域。这种配置有利于显著的扭矩输出，而不影响制动器的紧凑性。优化后的制动器原型尺寸为Ø29.2×44 mm，质量为171.5 g，峰值扭矩为1165.4 mN$\cdot$m。扭矩-体积比和扭矩-质量比分别为39.6 kN/m$^{2}$和6.8 mN$\cdot$m/g，高于同等尺寸的其他MR制动器。在实际场景中，基于该制动器原型构建了手持触觉装置。实验结果表明，该方法的扭矩呈现是可控的，差异仅为54.18 $\pm$ 17.73 mN$\cdot$m，韦伯分数为11.91 $\pm$ 3.90%，从而突出了其在小尺寸、高扭矩触觉驱动方面的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Haptics COMPUTER SCIENCE, CYBERNETICS-

CiteScore

5.90

自引率

13.80%

发文量

109

审稿时长

>12 weeks

期刊介绍： IEEE Transactions on Haptics (ToH) is a scholarly archival journal that addresses the science, technology, and applications associated with information acquisition and object manipulation through touch. Haptic interactions relevant to this journal include all aspects of manual exploration and manipulation of objects by humans, machines and interactions between the two, performed in real, virtual, teleoperated or networked environments. Research areas of relevance to this publication include, but are not limited to, the following topics: Human haptic and multi-sensory perception and action, Aspects of motor control that explicitly pertain to human haptics, Haptic interactions via passive or active tools and machines, Devices that sense, enable, or create haptic interactions locally or at a distance, Haptic rendering and its association with graphic and auditory rendering in virtual reality, Algorithms, controls, and dynamics of haptic devices, users, and interactions between the two, Human-machine performance and safety with haptic feedback, Haptics in the context of human-computer interactions, Systems and networks using haptic devices and interactions, including multi-modal feedback, Application of the above, for example in areas such as education, rehabilitation, medicine, computer-aided design, skills training, computer games, driver controls, simulation, and visualization.