Title :
Development of a MEMS-based electro-rheological microfinger system with an alternating pressure source
Author :
Miyoshi, T. ; Yoshida, K. ; Kim, J.-W. ; Eom, S.I. ; Yokota, S.
Author_Institution :
Grad. Sch., Tokyo Inst. of Technol., Tokyo, Japan
Abstract :
This paper presents a novel MEMS-based electro-rheological (ER) microfinger system with an alternating pressure source for multiple microactuator systems. Based on rectifying alternating flow by the ER microvalves, the ER microfinger system enables half number and small size of supply and return pipes, which is suitable for multiple microactuator systems. The MEMS-based finger part was realized by newly developed PDMS micromolding process featuring high-aspect-ratio and three-dimensional structures. This is the first time demonstration of bi-directional, large-displacement of 1.1 mm and high-speed (rise time of 1.1 s) bending motion of the fabricated 1.6-mm long ER microfinger.
Keywords :
electrorheology; microactuators; microvalves; moulding; ER microfinger system; ER microvalves; MEMS-based electro-rheological microfinger system; MEMS-based finger part; PDMS micromolding process; alternating pressure source; bending motion; bi-directional large-displacement; multiple microactuator systems; rectifying alternating flow; size 1.1 mm; size 1.6 mm; three-dimensional structures; time 1.1 s; Erbium; Fingers; Microactuators; Microvalves; Transmitters; Viscosity; Alternating Pressure Source; Electro-Rheological Fluid (ERF); Hydraulic Actuators; MEMS;
Conference_Titel :
Solid-State Sensors, Actuators and Microsystems (TRANSDUCERS), 2015 Transducers - 2015 18th International Conference on
Conference_Location :
Anchorage, AK
DOI :
10.1109/TRANSDUCERS.2015.7181050
