Design and Characterization of a Small-Scale Magnetorheological Damper for Tremor Suppression

Author

Case, David ; Taheri, Behzad ; Richer, Edmond

Author_Institution

Biomed. Instrum. & Robot. Lab., Southern Methodist Univ., Dallas, TX, USA

Volume

18

Issue

1

fYear

2013

fDate

Feb. 2013

Firstpage

96

Lastpage

103

Abstract

This paper explores the design methodology and effectiveness of small-scale magnetorheological dampers (MRDs) in applications that require variable damping. Previously, applications of MRD have been chiefly limited to vehicle shock absorbers and seismic vibration attenuators. There has been recent biomedical interest in active-damping technology, however, particularly in the field of rehabilitation robotics. The topic at hand is the feasibility of developing MRDs that would be functionally and cosmetically adequate for actuation of an upper limb tremor suppression orthosis. A Bingham plastic model is used to determine MRD´s functional characteristics, and experimental data are presented to validate the mathematical model. The feasibility of applying the developed small-scale MRDs to attenuation of tremorous motion is explored.

Keywords

actuators; design engineering; medical robotics; orthotics; patient rehabilitation; plasticity; shock absorbers; vibration control; Bingham plastic model; MRD; actuation; damper characterization; damper design; design methodology; rehabilitation robotics; seismic vibration attenuator; small-scale magnetorheological damper; tremor suppression; upper limb tremor suppression orthosis; vehicle shock absorber; Damping; Equations; Force; Magnetomechanical effects; Mathematical model; Pistons; Shock absorbers; Magnetic liquids; medical robotics; orthotics;

fLanguage

English

Journal_Title

Mechatronics, IEEE/ASME Transactions on

Publisher

ieee

ISSN

1083-4435

Type

jour

DOI

10.1109/TMECH.2011.2151204

Filename

5997312