Title :
Millimeter-scale actuator with fiber-optic roller bearings
Author :
Feinerman, Alan D. ; Thodati, Srinivas R.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Illinois Univ., Chicago, IL, USA
fDate :
3/1/1995 12:00:00 AM
Abstract :
A technique combining semiconductor processing and fiber-optic technology has been developed to micromachine a 1-cm2 silicon die that rolls on two wheels above a flat substrate. Each wheel consists of a glass capillary surrounding a fixed solid glass fiber axle. A 100-silicon die is anisotropically etched to create two variable width v-grooves. Each v-groove has a wide center section and two narrow ends, which is schematically illustrated as -==-. The capillary is free to rotate about the axle in the wide v-groove section while the axle is anodically bonded into the narrow v-groove ends. The gap between the die and the substrate is determined by the narrow v-groove width, fiber diameter, and capillary wall thickness. Several rolling die have been fabricated with 210-120 μm gaps. The coefficient of static friction (μS) has been investigated on several substrates as a function of the load on the die. Values for μS are compared to an unetched die with a silicon nitride coating. With loads ranging from 0-10 grams, the wheels reduce μS by more than 50% on borosilicate glass
Keywords :
etching; friction; microactuators; micromachining; optical fibres; semiconductor technology; silicon; 120 to 210 micron; Si; Si die; SiO2; anisotropical etching; borosilicate glass; fiber-optic roller bearings; fiber-optic technology; fixed solid glass fiber axle; glass capillary; micromachined cart; millimeter-scale actuator; semiconductor processing; static friction coefficient; variable width v-grooves; Actuators; Anisotropic magnetoresistance; Axles; Etching; Glass; Rolling bearings; Silicon; Solids; Substrates; Wheels;
Journal_Title :
Microelectromechanical Systems, Journal of
