Abstract: A micromechanical device with electrostatically caused deflection by a plate capacitor extending along and spaced apart from the neutral fiber of the deflectable element is improved with regard to its manufacturing complexity and/or with regard to its operating characteristics, such as, for example, maximum voltage applicable or deflectability, by using a continuous insulation layer between the distal and proximal electrodes of the plate capacitor, or else the proximal electrode is structured so as to have gaps at the segment boundaries where the distal electrode is mechanically fixed so as to be laterally spaced apart from the distal electrode. Both procedures avoid the problems of generating a roughness of the surface of the proximal electrode facing the distal electrode, as would otherwise be necessitated by etching an insulation layer for providing spacers between the distal and proximal electrodes at the segment boundaries.

Abstract: The force on the electrodes of an electrostatic field is used so that lateral tensile or compressive forces result which can deform a deformable element or can strongly deflect a deflectable structure. For this, a micromechanical device includes, apart from an electrode and a deformable element, an insulating spacer layer via which the electrode is fixed to the deformable element, wherein the insulating spacer layer is structured into several spaced-apart segments along a lateral direction, so that by applying an electric voltage between the electrode and the deformable element lateral tensile or compressive forces bending the deformable element along the lateral direction result. Thereby, the problem that normally accompanies electrostatic drives, namely the problem of the pull-in effect, is overcome. The deflection of the deformable element can be much larger than the gaps of the two electrodes, i.e. the above-mentioned electrode and the deformable element. A usage as a sensor is also possible.

Abstract: A micromechanical mirror arrangement comprising a mirror plate (1) which forms a translation mirror, which is connected via at least one holding element (2), preferably two or more holding elements, to a frame structure (3) and is movable in translation relative to this frame structure, characterized in that the connection region (4) of at least one holding element (2), preferably of all holding elements, with the mirror plate (1) is arranged inwardly offset, viewed from the outer margin (5) of the mirror plate toward to the center (6) of the mirror plate.

Abstract: The force on the electrodes of an electrostatic field is used so that lateral tensile or compressive forces result which can deform a deformable element or can strongly deflect a deflectable structure. For this, a micromechanical device includes, apart from an electrode and a deformable element, an insulating spacer layer via which the electrode is fixed to the deformable element, wherein the insulating spacer layer is structured into several spaced-apart segments along a lateral direction, so that by applying an electric voltage between the electrode and the deformable element lateral tensile or compressive forces bending the deformable element along the lateral direction result. Thereby, the problem that normally accompanies electrostatic drives, namely the problem of the pull-in effect, is overcome. The deflection of the deformable element can be much larger than the gaps of the two electrodes, i.e. the above-mentioned electrode and the deformable element. A usage as a sensor is also possible.

Abstract: A micromechanical element includes a plate-shaped micromechanical functional element, an inner frame and an outer frame. Thereby, a curvature of a main face of the plate-shaped micromechanical functional element is variable. The inner frame encloses the plate-shaped micromechanical functional element along an edge of the main face and is connected to the plate-shaped micromechanical functional element via a plurality of connecting pieces. The outer frame is connected to the inner frame via at least two holding elements. The inner frame is connected to the plate-shaped micromechanical functional element and the outer frame, such that a first angle between the main face of the plate-shaped micromechanical functional element and a main face of the inner frame is smaller than a second angle between a main face of the outer frame and the main face of the inner frame, when the main face of the plate-shaped micromechanical functional element is in a bent state.

Abstract: A cooling system for motor vehicle with a cooling circuit, which includes one or more internal combustion engines, a pump and a cooling device, is described herein. The cooling system includes a short circuit line, which bypasses the pump by connecting a pressure side of the pump to an intake side of the pump. The cooling system further includes a valve device in the region of the short circuit line, and the valve device is switched between two or more positions. When the valve is in the first position, the entire coolant flow is directed through the short circuit line. Further, when the valve is in the second position, the entire coolant flow is directed through the internal combustion engine and not through the short circuit line.

Abstract: The invention relates to closed impellers (1) for centrifugal pumps used for conveying homogeneous liquids, especially in cooling systems of motor vehicles. The aim of the invention is to develop a novel design of closed impellers (1) for centrifugal pumps used for conveying homogeneous liquids, especially in coolant pumps, such that closed impellers comprising single-curved blades (3) as well as closed impellers comprising three-dimensionally curved blades (3) can be produced at a low cost while the effect of cavitation wear is minimized on the parts/subassemblies that are mounted downstream of the impeller and the hydraulic efficiency as well as the suction behavior of the respective impeller design is significantly improved.

Abstract: A micromechanical element includes a movable functional element, a first retaining element, a second retaining element, a third retaining element, and a fourth retaining element. The first retaining element and the functional element are connected at a first junction, the second retaining element and the functional element are connected at a second junction, the third retaining element and the functional element are connected at a third junction, and the fourth retaining element and the functional element are connected at a fourth junction. In addition, the first retaining element and the second retaining element each include a piezoelectric driving element, the driving element of the first retaining element and the driving element of the second retaining element being configured to move the functional element in accordance with electric excitation.

Abstract: A micromechanical mirror arrangement comprising a mirror plate (1) which forms a translation mirror, which is connected via at least one holding element (2), preferably two or more holding elements, to a frame structure (3) and is movable in translation relative to this frame structure, characterized in that the connection region (4) of at least one holding element (2), preferably of all holding elements, with the mirror plate (1) is arranged inwardly offset, viewed from the outer margin (5) of the mirror plate toward to the center (6) of the mirror plate.

Abstract: A micromechanical element includes a plate-shaped micromechanical functional element, an inner frame and an outer frame. Thereby, a curvature of a main face of the plate-shaped micromechanical functional element is variable. The inner frame encloses the plate-shaped micromechanical functional element along an edge of the main face and is connected to the plate-shaped micromechanical functional element via a plurality of connecting pieces. The outer frame is connected to the inner frame via at least two holding elements. The inner frame is connected to the plate-shaped micromechanical functional element and the outer frame, such that a first angle between the main face of the plate-shaped micromechanical functional element and a main face of the inner frame is smaller than a second angle between a main face of the outer frame and the main face of the inner frame, when the main face of the plate-shaped micromechanical functional element is in a bent state.

Abstract: The invention relates to deflectable micromechanical systems as well as their use in which the deflection of at least one deflectable element can be determined. In accordance with the invention, a deflectable element is held with at least one spring element and at least one unit detecting the deflection is present. It is formed as a piezoresistive sensor with contacts arranged at least at a spacing from one another and in a region deforming on deflection. The contacts are connected to an electrical voltage source. An inhomogeneous electrical field is formed perpendicular to the contact surfaces in the depth direction so that the electrical resistance between contacts varying in dependence on the deflection can be detected as a measure for the position. The deforming region is formed from electrically conductive or semiconductive material.

Abstract: The invention relates to a cooling system (1) in a motor vehicle with a cooling circuit in which at least one internal combustion engine (2), one pump (3) and one cooling device (4) are arranged, wherein a short circuit line (5) which bypasses the pump (3) is provided, which connects a pressure side to an intake side of the pump (3), a valve device (6) which can be switched between at least two positions is provided in the region of the short circuit line (5), in the first position the entire coolant flow flows through the short circuit line (5) and in the second position preferably the entire coolant flow flows through the internal combustion engine (2) and not through the short circuit line (5).

Abstract: A micromechanical element includes a movable functional element, a first retaining element, a second retaining element, a third retaining element, and a fourth retaining element. The first retaining element and the functional element are connected at a first junction, the second retaining element and the functional element are connected at a second junction, the third retaining element and the functional element are connected at a third junction, and the fourth retaining element and the functional element are connected at a fourth junction. In addition, the first retaining element and the second retaining element each include a piezoelectric driving element, the driving element of the first retaining element and the driving element of the second retaining element being configured to move the functional element in accordance with electric excitation.

Abstract: The invention relates to deflectable micromechanical systems as well as their use in which the deflection of at least one deflectable element can be determined. In accordance with the invention, a deflectable element is held with at least one spring element and at least one unit detecting the deflection is present. It is formed as a piezoresistive sensor with contacts arranged at least at a spacing from one another and in a region deforming on deflection. The contacts are connected to an electrical voltage source. An inhomogeneous electrical field is formed perpendicular to the contact surfaces in the depth direction so that the electrical resistance between contacts varying in dependence on the deflection can be detected as a measure for the position. The deforming region is formed from electrically conductive or semiconductive material.

Abstract: The invention relates to closed impellers (1) for centrifugal pumps used for conveying homogeneous liquids, especially in cooling systems of motor vehicles. The aim of the invention is to develop a novel design of closed impellers (1) for centrifugal pumps used for conveying homogeneous liquids, especially in coolant pumps, such that closed impellers comprising single-curved blades (3) as well as closed impellers comprising three-dimensionally curved blades (3) can be produced at a low cost while the effect of cavitation wear is minimized on the parts/subassemblies that are mounted downstream of the impeller and the hydraulic efficiency as well as the suction behavior of the respective impeller design is significantly improved.