Title :
Compact MR-brake with serpentine flux path for haptics applications
Author :
Senkal, Doruk ; Gurocak, Hakan
Author_Institution :
Sch. of Eng. & Comput. Sci., Washington State Univ. Vancouver, Vancouver, WA
Abstract :
This research explores a new approach to shape the magnetic flux path in a MR brake. Magnetically conductive and non-conductive elements were stacked to weave the magnetic flux through the rotor and the outer shell of the brake. This approach enabled design of a more compact and powerful MR brake. In addition, a ferro-fluidic sealing technique was developed to prevent the fluid from leaking and to reduce off-state friction. Experimental results showed that, when compared to a commercial MR brake, our 33% smaller prototype MR-brake could generate 2.7 times more torque (10.9 Nm). A 1-DOF haptic interface employing the brake enabled crisp virtual wall collision simulations. Significant reduction in the off-state torque was obtained by applying a reverse current pulse to collapse a residual magnetic field in the brake.
Keywords :
brakes; haptic interfaces; rotors; compact MR-brake; ferrofluidic sealing technique; haptic interface; magnetic flux path; off-state friction; reverse current pulse; rotors; serpentine flux path; Erbium; Friction; Haptic interfaces; Magnetic flux; Magnetic liquids; Prototypes; Structural rings; Torque; Valves; Virtual reality; MR brake; MR fluid; VR; force feedback; haptics; magnetorheological; virtual reality;
Conference_Titel :
EuroHaptics conference, 2009 and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems. World Haptics 2009. Third Joint
Conference_Location :
Salt Lake City, UT
Print_ISBN :
978-1-4244-3858-7
DOI :
10.1109/WHC.2009.4810807
