Patent application number | Description | Published |
20080250785 | Micromechanical device with gold alloy contacts and method of manufacture - A MEMS switch device is made using a gold alloy as the switch contact material. The increased mechanical hardness of the alloy compared to the pure gold prevents the contacts of the switch from welding together. A scrubbing action which occurs when the switch closes may allow the contact surfaces to come to rest where their surfaces are complementary, thus resulting in higher contact area and low contact resistance, despite the higher sheet resistance of the gold alloy material relative to the pure gold material. | 10-16-2008 |
20090181488 | MEMS thermal actuator and method of manufacture - A separated MEMS thermal actuator is disclosed which is largely insensitive to creep in the cantilevered beams of the thermal actuator. In the separated MEMS thermal actuator, a inlaid cantilevered drive beam formed in the same plane, but separated from a passive beam by a small gap. Because the inlaid cantilevered drive beam and the passive beam are not directly coupled, any changes in the quiescent position of the inlaid cantilevered drive beam may not be transmitted to the passive beam, if the magnitude of the changes are less than the size of the gap. | 07-16-2009 |
20090201119 | Hysteretic mems thermal device and method of manufacture - A MEMS hysteretic thermal actuator may have a plurality of beams disposed over a heating element formed on the surface of the substrate. The plurality of beams may be coupled to a passive beam which is not disposed over the heating element. One of the plurality of beams may be formed in a first plane parallel to the substrate, whereas another of the plurality of beams may be formed in a second plane closer to the surface of the substrate. When the heating element is activated, it heats the plurality of beams such that they move the passive beam in a trajectory that is neither parallel to nor perpendicular to the surface of the substrate. When the beams are cooled, they may move in a different trajectory, approaching the substrate before moving laterally across it to their initial positions. By providing one electrical contact on the distal end of the passive beam and another stationary electrical contact on the substrate surface, the MEMS hysteretic actuator may form a reliable electrical switch that is relatively simple to manufacture and operate. | 08-13-2009 |
20100018021 | Hysteretic MEMS two-dimensional thermal device and method of manufacture - A MEMS hysteretic thermal device may be formed having two passive beam segments driven by a current-carrying loop coupled to the surface of a substrate. The first beam segment is configured to move in a direction having a component perpendicular to the substrate surface, whereas the second beam segment is configured to move in a direction having a component parallel to the substrate surface. By providing this two-dimensional motion, a single MEMS hysteretic thermal device may by used to close a switch having at least one stationary contact affixed to the substrate surface. | 01-28-2010 |
20110155548 | Dual substrate MEMS plate switch and method of manufacture - Systems and methods for forming an electrostatic MEMS plate switch include forming a deformable plate on a first substrate, forming the electrical contacts on a second substrate, and coupling the two substrates using a hermetic seal. The deformable plate may have at least one shunt bar located at a nodal line of a vibrational mode of the deformable plate, so that the shunt bar remains relatively stationary when the plate is vibrating in that vibrational mode. A hermetic seal may be made around the device with a larger, secondary enclosure. Electrical access to the deformable plate may be accomplished by an electrical path which is independent of the seal. The electrical path may include a via through the first substrate or the second substrate, or a flash deposited on an external region of the switch. | 06-30-2011 |
20110295229 | In-plane electromagnetic mems pump - A micromechanical pumping system is formed on a substrate surface. The pumping system uses a pumping element which pumps a fluid through valves which move in a plane substantially parallel to the substrate surface. An electromagnetic actuating mechanism may also be fabricated on the surface of the substrate. Magnetic flux produced by a coil around a permeable core may be coupled to a permeable member affixed to a pumping element. The permeable member and pumping element may be configured to move in a plane parallel to the substrate. The electromagnetic actuating mechanism gives the pumping system a large throw and substantial force, such that the fluid pumped by the pumping system may be pumped through a transdermal cannula to deliver a therapeutic substance to the tissue underlying the skin of a patient. | 12-01-2011 |
20120302946 | Microfabricated electromagnetic actuator with push-pull motion - A micromechanical electromagnetic actuator may have two separate components: a flux-generating portion and a separate movable structure. The flux-generating portion may have a plurality of conductive coils wound around a magnetically permeable material. Each coil generates a magnetic field along its axis, which is different for each of the coils. The adjacent movable structure may include magnetically permeable features, one inlaid in the movable structure and other stationary features which focus the flux produced by the flux-generating mechanism across a gap between the stationary features. By energizing each coil sequentially, a push-pull motion in the actuator may result from the force of the magnetically permeable features. This push-pull actuator may be particularly effective when used as a pumping element in a drug delivery system, or other fluidic pumping system. | 11-29-2012 |
20130184661 | EYE DRUG DELIVERY SYSTEM - A punctal plug or lacrimal insert comprising a microelectromechanical system pump and associated reservoir may be utilized to deliver precise dosages of an active agent into the eye though the tear film. The microelectromechanical system pump comprises four main components; namely, a reservoir, a pump, a series of valves and a vent. The microelectromechanical system pump is positioned within a cavity in the punctal plug. The microelectromechanical system pump is positioned with a cavity in the punctal plug. | 07-18-2013 |