Patent application number | Description | Published |
20110296913 | Yaw rate sensor - A yaw rate sensor includes: at least one Coriolis element; a drive device connected to the Coriolis element and configured to drive a vibration of the Coriolis element; a detection device having at least one rotor; and a coupling device connected to the detection device and to the Coriolis element. The coupling device is configured to couple a deflection in the plane of vibration of the Coriolis element to the detection device in a direction orthogonal to the vibration, so that when the Coriolis element is deflected a torque for driving the at least one rotor is transmitted from the Coriolis element to the at least one rotor. | 12-08-2011 |
20120011933 | YAW RATE SENSOR - A yaw rate sensor is described which includes a drive device, at least one Coriolis element, and a detection device having at least two detection elements which are coupled to one another with the aid of a coupling device, the drive device being connected to the Coriolis element for driving a vibration of the Coriolis element, and an additional coupling device which is connected to the detection device and to the Coriolis element for coupling a deflection in the plane of vibration of the Coriolis element to the detection device in a direction orthogonal to the vibration. | 01-19-2012 |
20120125099 | YAW-RATE SENSOR AND METHOD FOR OPERATING A YAW-RATE SENSOR - A yaw-rate sensor includes: a substrate having a main extension plane for detecting a yaw rate about a first axis extending parallel to the main extension plane; a first Coriolis element; a second Coriolis element; a third Coriolis element; and a fourth Coriolis element. The first Coriolis element and the fourth Coriolis element are drivable in the same direction parallel to a second axis extending parallel to the main extension plane and perpendicularly to the first axis. The first Coriolis element and the second Coriolis element are drivable in opposite directions parallel to the second axis. The first Coriolis element and the third Coriolis element are drivable in opposite directions parallel to the second axis. | 05-24-2012 |
20120152019 | Yaw-rate sensor and method for operating a yaw-rate sensor - A yaw-rate sensor is described as having a substrate which has a main plane of extension for detecting a yaw rate about a first axis extending parallel to the main plane of extension is provided, the yaw-rate sensor having a first rotation element and a second rotation element, the first rotation element being drivable about a first axis of rotation, the second rotation element being drivable about a second axis of rotation, the first axis of rotation being situated perpendicularly to the main plane of extension, the second axis of rotation being situated perpendicularly to the main plane of extension, the first rotation element and the second rotation element being drivable in opposite directions. | 06-21-2012 |
20130284227 | ENERGY SOURCE AND METHOD FOR SUPPLYING AN AUTONOMOUS ELECTRICAL LOAD SYSTEM AND THE USE OF SAME - An energy source for supplying an autonomous electrical load system with electrical energy includes a thermogenerator device configured to generate a thermoelectric voltage to be fed to the electrical load system. The thermogenerator device is under the influence of a temperature difference between a warmer first thermal coupling device and a colder second thermal coupling device. The energy source further includes a microfluidic cooling device having a heat-absorption region, a heat-emission region, and a closed microfluidic circulation system configured to circulate a fluid between the heat-absorption region and the heat-emission region. The heat-absorption region has a thermally conductive connection to the second thermal coupling device. The heat-emission region is configured to be coupled to an external heat sink using a thermally conductive connection such that the circulating fluid carries thermal energy away from the second thermal coupling device and transports the thermal energy to the external heat sink. | 10-31-2013 |
20130298672 | YAW-RATE SENSOR - A yaw-rate sensor, having a substrate which has a main extension plane, for detecting a yaw rate about a first direction extending either parallel to the main extension plane or perpendicular to the main extension plane. The yaw-rate sensor has a drive device, a first Coriolis mass and a second Coriolis mass, the drive device being configured to drive at least one part of the first Coriolis mass and at least one part of the second Coriolis mass in a direction parallel to a drive direction extending perpendicular to the first direction. | 11-14-2013 |
20130340522 | YAM RATE SENSOR - A yaw rate sensor, including a substrate and a main extension plane, for detecting a yaw rate around a first direction in parallel to the main extension plane, a first Coriolis mass, and a second Coriolis mass, and a drive device configured to drive the first and second Coriolis masses in parallel to a drive direction perpendicular to the first direction, the first and second Coriolis masses, for a yaw rate around the first direction, experiencing a Coriolis acceleration in parallel to a detection direction, which is perpendicular to the drive and first directions, the first and second Coriolis masses having first/second partial areas and third/fourth partial areas, respectively. The first and third partial areas are farther from the axis of symmetry in parallel to the first direction, and the second and fourth partial areas are closer to the axis of symmetry in parallel to the first direction. | 12-26-2013 |
20140116134 | MICROMECHANICAL STRUCTURE - Micromechanical structure, in particular a yaw rate sensor having a substrate including a main plane of extent for detecting a first yaw rate about a first direction perpendicular to the main plane, a second yaw rate about a second direction parallel to the main plane, and a third yaw rate about a third direction parallel to the main plane and perpendicular to the second direction, includes a rotational oscillating element driven to rotational oscillation about a rotational axis parallel to the first direction. The micromechanical structure includes a yaw rate sensor configuration for detecting the first yaw rate that is completely surrounded by the rotational oscillating element in a plane parallel to the main plane. The micromechanical structure includes at least one first connection of the yaw rate sensor configuration on the rotational oscillating element, and at least one second connection of the yaw rate sensor configuration on the substrate. | 05-01-2014 |
20140169594 | MEMS COMPONENT FOR GENERATING PRESSURE PULSES - A MEMS component for generating pressure pulses is provided, its micromechanical structure including at least three function levels: a first function level in which at least one stationary trench structure is implemented, a second function level, which is implemented above the first function level and includes at least one triggerable displacement element as well as through-openings as pressure outlet openings, the displacement element protruding into the trench structure and being movable in parallel with the function levels, whereby positive and negative pressure pulses are generated, and a third function level, which is implemented above the second function level and includes at least one triggerable cover element for at least one part of the pressure outlet openings in the second function level. | 06-19-2014 |
20150052999 | rotational rate sensor having preset quadrature offset - A rotational rate sensor includes a substrate and a seismic mass situated thereon, and configured for detecting a rate of rotation about a rotation axis, the seismic mass having a second mass element coupled to a first mass element, which is drivable to a drive movement along a drive direction perpendicular to the rotation axis, the first and second mass element being deflectable along a detection direction essentially perpendicular to the drive direction and to the rotation axis, the rotational rate sensor having at least one compensating arrangement to produce a compensating force acting on the second mass element, the compensating force being oriented in a compensation direction essentially parallel to the detection direction, the at least one compensating arrangement being the only compensating arrangement and being configured exclusively to produce the compensating force oriented in the compensation direction, the rotational rate sensor being configured such that a quadrature offset force acting on the second mass element is directed exclusively in a preferred direction opposite and parallel to the compensation direction. | 02-26-2015 |
20150063608 | Capacitive mems element including a pressure-sensitive diaphragm - An implementation for an electret in a capacitive MEMS element including a pressure-sensitive diaphragm, which is produce-able using standard methods of semiconductor technology for easy integration into the manufacturing process of MEMS semiconductor elements. Such MEMS elements include at least one pressure-sensitive diaphragm including at least one deflectable diaphragm electrode of a capacitor system for signal detection and one fixed non-pressure-sensitive counter-element including at least one counter-electrode of this capacitor system, at least one electrode of the capacitor system being provided with an electrically charged electret, so that there is a potential difference between the two electrodes of the capacitor system. The electret includes at least two adjacent layers made from different dielectric materials, electrical charges being stored on their boundary surface. | 03-05-2015 |
20150078590 | Membrane Arrangement for a MicroElectromechanical Measuring Transducer and Method for Producing a Membrane Arrangement - The disclosure relates to a micro-electromechanical membrane arrangement with a substrate, which has a multiplicity of recesses on a surface, a first electrically conductive electrode layer, which is arranged on the surface of the substrate and has a multiplicity of first depressions coinciding with the recesses, and an electrically conductive membrane layer, which can be deflected in a direction perpendicular to the active surface of the substrate, is arranged over the first electrode layer and is kept at a distance therefrom by a first distance value. | 03-19-2015 |