An MEMS chip includes a substrate, a movable assembly, a fastening assembly, and a drive assembly. The fastening assembly is located between the substrate and the movable assembly. The movable assembly includes a fastening portion, a movable portion, and a first support beam. The first support beam is connected to the movable portion and the fastening portion. A first avoidance slot is disposed on a face that is of the movable portion and that faces the fastening assembly. The fastening assembly is grounded. A boss and a first position limiting pole are disposed on a face that is of the fastening assembly and that faces the movable assembly. The boss is connected to the fastening portion and configured to support the fastening portion. The first position limiting pole corresponds to the first avoidance slot. The drive assembly is connected to the movable portion to drive the movable portion to move.

A transducer unit for a MEMS sound transducer includes a support, a transducer element connected to the support and deflectable along a reciprocation axis, a coupling element for connecting the transducer element to a diaphragm in a manner spaced apart from the transducer element, and a spring region formed between the transducer element and the coupling element, the spring region including at least one spring element, which movably connects the transducer element to the coupling element, and which includes a damping layer, which at least partially covers the spring element.

The present disclosure relates to a microelectromechanical systems (MEMS) package featuring a flat plate having a raised edge around its perimeter serving as an anti-stiction device, and an associated method of formation. A CMOS IC is provided having a dielectric structure surrounding a plurality of conductive interconnect layers disposed over a CMOS substrate. A MEMS IC is bonded to the dielectric structure such that it forms a cavity with a lowered central portion the dielectric structure, and the MEMS IC includes a movable mass that is arranged within the cavity. The CMOS IC includes an anti-stiction plate disposed under the movable mass. The anti-stiction plate is made of a conductive material and has a raised edge surrounding at least a part of a perimeter of a substantially planar upper surface.

A micromechanical device having a substrate wafer, a functional layer situated above it which has a mobile micromechanical structure, and a cap situated on top thereof, having a first cavity, which is formed at least by the substrate wafer and the cap and which includes the micromechanical structure. The micromechanical device has a fixed part and a mobile part, which are movably connected to each other with at least one spring element, and the first cavity is situated in the mobile part. Also described is a method for producing the micromechanical device.

Embodiments of the present invention provide an MEMS actuator with a substrate, at least one post attached to the substrate and a deflectable actuator body that is connected to the at least one post via at least one spring, wherein, during electrostatic, electromagnetic or magnetic force application, the actuator body takes a second position starting from a first position by a tilt-free translational movement, wherein the first position and the second position are different, and wherein in a top view of the MEMS actuator the actuator body is arranged outside an area spanned by the at least one post.

An optical device formed of a mirror wafer, a cap wafer, and a glass wafer. The mirror wafer includes a first layer of electrically conductive material, a second layer of electrically conductive material, and a third layer of electrically insulating material between the first layer and the second layer. A mirror element is formed of the second layer of the mirror wafer, and has a reflective surface in the bottom of a cavity opened into at least the first layer. A good optical quality planar glass wafer can be used to enclose the mirror element when the mirror wafer, cap wafer, and glass wafer are bonded to each other.

A sensor device includes: a sensor portion having a movable thin film and a detection element configured to output a signal corresponding to displacement of the movable thin film; a frame portion disposed to surround an outside of the sensor portion; a spring portion provided between the frame portion and the sensor portion; and a circuit board including a circuit configured to process the signal output from the detection element, in which the frame portion is laminated on the circuit board, and the sensor portion is cantilevered from the frame portion by the spring portion such that a gap is formed between the sensor portion and the circuit board.

In some examples, a transducer apparatus includes a spring structure that enables a large, reliable amount of displacement of a transducer plate. For instance, an individual cell of the transducer apparatus may include a substrate having a first electrode portion, with at least one spring anchor extending from a first side of the substrate. At least one spring member may be supported by the at least one anchor, and may be connected to a plate that includes a second electrode portion. Accordingly, the spring member may support the plate, at least in part, for enabling the plate to move in a resilient manner toward and away from the substrate. In some cases, the spring member may be a bar-shaped spring that is cantilevered to an anchor or supported by two or more anchors. Additionally, a cavity between the plate and the substrate may be sealed by a sealing material.

A diaphragm structure of a micromechanical component includes: a diaphragm integrated via at least one spring element into a layered structure, the diaphragm spanning a cavern, so that at least one section of the diaphragm edge extends up to and beyond the edge area of the cavern; and an anchoring structure formed in the overlap area between the diaphragm and the cavern edge area. The anchoring structure includes at least one anchor element structured out of the layered structure above the cavern edge area, and one through opening for the anchor element formed in the edge area of the diaphragm, so that there is a clearance between the anchor element and the through opening which allows for a mechanical stress relaxation of the diaphragm.

A micro check valve includes a substrate body having a top side and an underside, at least the top side having a sealing bar between a first trough and a second trough. The substrate body also has a passage which leads from the underside of the substrate body to the top side of the substrate body and ends on the top side of the substrate body in the first trough. In addition arranged on the top side of the substrate body is a diaphragm which is mounted flexibly at least in the region of the sealing bar and the first and second troughs. The diaphragm also has at least one through opening arranged above the second trough.