Principle design and control of a brake-by-wire actuator featuring magnetorheological clutch

Duan, Shun-Chang; Sun, Jun; Bai, Xian–Xu; Nguyen, Quoc Hung; Si, Zhi-Yuan; Li, Wei-Han; Liu, Yang

doi:10.1177/09544070221079501

Proceedings of the Institution of Mechanical Engineers, Part D:

2022

DOI: 10.1177/09544070221079501

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Principle design and control of a brake-by-wire actuator featuring magnetorheological clutch

Shun-Chang Duan

Jun Sun

Xian–Xu Bai

et al.

Abstract: Electro-mechanical brake (EMB), driven by a motor to push the brake pads to clamp the brake disk for braking, is considered as the future of vehicle braking system, because of its simple structure and controllable braking force. However, EMB must face the problem of motor blocking when it works in a long-time continuous braking condition. When the motor is blocking, the current in the coil windings is large enough to burn the motor down, leading to the failure of EMB, which is a great threat to driving safety.… Show more

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2024

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Cited by 3 publications

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A review on the magnetorheological materials and applications

Yang,

Pan,

Wang

2024

International Journal of Applied Electromagnetics and Mechanics

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Magnetorheological materials refer to field-response smart materials whose properties are controllable with a magnetic field, including fluid, grease, elastomer, and gel. The unique magnetorheological effect exhibited by these smart materials is a physical phenomenon where physics and engineering intersect and has extensive application prospects in modern machinery. In electro-mechanical systems, magnetorheological materials offer a superior design method for mechanical devices used in the fields of transmission, damping, and braking. It is important to control the magnetorheological materials for advancing the design philosophy of modern electro-mechanical devices. Hence, this paper presents a recent progressive review on the fundamentals of magnetorheological materials and numerous applications. Firstly, an introduction to the magnetorheological effect and different types of magnetorheological materials are presented in this review. Then, the individual and coupled effects of sedimentation, temperature, and magnetic field on magnetorheological materials are discussed. Finally, magnetorheological materials-based devices have been extensively reviewed, including actuator, clutch, damper, brake, pump, valve, and robot, thus aiming to provide useful information for facilitating the design of complex electro-mechanical systems.

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A review on the magnetorheological materials and applications

Yang,

Pan,

Wang

2024

International Journal of Applied Electromagnetics and Mechanics

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Design, Modeling, and Control of Electronic Mechanical Brake System: A Review

Yan,

Peng,

Chen

et al. 2024

SAE Int. J. Veh. Dyn., Stab., and NVH

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<div>The electronic mechanical brake (EMB) system is a critical actuator for achieving brake-by-wire control. This review categorizes and summarizes the literature related to EMB into three sections: actuator, mathematical modeling, and control strategies. In the actuator aspect, this article compares and analyzes motors, motion conversion mechanisms, and self-reinforcing mechanisms. For mathematical modeling, this article reviews modeling methods for EMB systems concerning motors, transmission mechanisms, friction, contact collisions, nonlinear stiffness, and hysteresis characteristics. Regarding control strategies, this article consolidates methods for clamp force control, clamp force estimation, and gap management. Finally, the article discusses potential future research directions in EMB from both hardware structure and software algorithm perspectives.</div>

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Research on Direct-Drive Brake Actuator and Its Control Method for Electric Vehicles

He,

Gong,

Deng

et al. 2024

SAE Int. J. Veh. Dyn., Stab., and NVH

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<div>With the rapid development of electric vehicles, the need for improved reliability and safety performance of electric vehicle braking systems has become paramount. In response to this demand, a novel direct-drive brake-by-wire actuator based on linear motors was designed to address these challenges. This article presents the structure and principles of the proposed braking actuator. Leveraging the traditional electromechanical brake systems as a foundation, the prototype was modified and fabricated. Additionally, the control and drive system for the braking actuator was established using the TMS320F28335 digital signal processor. Moreover, the current-position dual closed-loop control algorithm was devised to regulate the braking force accurately. Experimental results demonstrate that the direct-drive brake-by-wire actuator exhibits rapid responsiveness and precise braking force modulation, showcasing promising prospects in the field of electric vehicle braking.</div>

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Principle design and control of a brake-by-wire actuator featuring magnetorheological clutch

Cited by 3 publications

References 22 publications

A review on the magnetorheological materials and applications

A review on the magnetorheological materials and applications

Design, Modeling, and Control of Electronic Mechanical Brake System: A Review

Research on Direct-Drive Brake Actuator and Its Control Method for Electric Vehicles

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