Abstract: A magnetic levitation system for contactlessly holding and moving a carrier in a vacuum chamber, including a base defining a transportation track, a carrier movable above the base along the transportation track, and at least one magnetic bearing for generating a magnetic levitation force between the base and the carrier. The at least one magnetic bearing includes a first magnet unit arranged at the base and a second magnet unit arranged at the carrier. The magnetic levitation system further includes a magnetic side stabilization device for stabilizing the carrier in a lateral direction, the magnetic side stabilization device comprising a stabilization magnet unit arranged at the base, wherein at least one of the first magnet unit and the first stabilization magnet unit is arranged in a housing space of the base, the housing space being separated from an inner volume of the vacuum chamber by a separation wall.

Abstract: A magnetic levitation system for contactlessly holding and moving a carrier in a vacuum chamber, including a base defining a transportation track, a carrier movable above the base along the transportation track, and at least one magnetic bearing for generating a magnetic levitation force between the base and the carrier. The at least one magnetic bearing includes a first magnet unit arranged at the base and a second magnet unit arranged at the carrier. The magnetic levitation system further includes a magnetic side stabilization device for stabilizing the carrier in a lateral direction, the magnetic side stabilization device comprising a stabilization magnet unit arranged at the base, wherein at least one of the first magnet unit and the first stabilization magnet unit is arranged in a housing space of the base, the housing space being separated from an inner volume of the vacuum chamber by a separation wall.

Abstract: The invention permits the particularly simple, rapid and economic application of measuring elements (100) to objects to be measured (200). This is ensured by means of the integration of a functional material (140) on the connecting surface (113) of a measuring element (100). The mechanical connection is produced by activating the functional material (140). In this way, for example, the application times for strain sensors are drastically reduced. Furthermore, a defined thickness of the remaining functional material (140) is implemented and therefore reproducible properties of the connection are ensured.

Abstract: The invention allows for the contacting of preferably microcomponents using electrical wires. By growing metallic microdepositions on cut surfaces of microcables, a contact region is generated which simplifies the dosing and application of a contact auxiliary and allows ultrasonic bonding, comprising a defined size of the electrically conductive area and allowing the contacting of very stably insulated wires. The application of this method in a panelized manner and in series is inexpensive.

Abstract: The invention makes it possible to determine a force vector that is applied to a tip of a minimally invasive surgical instrument. The force acts upon the housing, is directed to the base, and causes a deformation there in special beam structures. Said deformation is detected by tension-sensitive/extension-sensitive resistors whose changes are a measure for the applied force vector. The inventive measuring element comprises special mounting elements so as to be integrated into tube-type instruments such as guiding wires, fastening zones for additional components, an overload protection, and a head shape that is adapted to the treatment process.

Abstract: A force sensor for detecting at least a force acting in a longitudinal direction of a catheter or guide wire, the force sensor comprising a force pick-up for detecting the force, wherein the force pick-up comprises: a base body with an end face, wherein the base body includes at least one cutout, wherein the cutout causes an asymmetry of the base body relative to the longitudinal direction of the catheter or guide wire upon flexing of the base body upon force Fz loading thereon from an axial direction, wherein the end face includes a surface area that is substantially greater than the cross-sectional area of the base body in the region of the cutout, but not substantially smaller than the cross-section of the rest of the base body. A method for using this force sensor is also disclosed.

Abstract: The invention allows for the contacting of preferably microcomponents using electrical wires. By growing metallic microdepositions on cut surfaces of microcables, a contact region is generated which simplifies the dosing and application of a contact auxiliary and allows ultrasonic bonding, comprising a defined size of the electrically conductive area and allowing the contacting of very stably insulated wires. The application of this method in a panelized manner and in series is inexpensive.

Abstract: The invention makes it possible to determine a force vector that is applied to a tip of a minimally invasive surgical instrument. The force acts upon the housing, is directed to the base, and causes a deformation there in special beam structures. Said deformation is detected by means of tension-sensitive/extension-sensitive resistors whose changes are a measure for the applied force vector. The inventive measuring element comprises special mounting elements so as to be integrated into tube-type instruments such as guiding wires, fastening zones for additional components, an overload protection, and a head shape that is adapted to the treatment process.

Abstract: A force sensor for detecting at least a force acting in a longitudinal direction of a catheter or guide wire, the force sensor comprising a force pick-up for detecting the force, wherein the force pick-up comprises: a base body with an end face, wherein the base body includes at least one cutout, wherein the cutout causes an asymmetry of the base body relative to the longitudinal direction of the catheter or guide wire upon flexing of the base body upon force Fz loading thereon from an axial direction, wherein the end face includes a surface area that is substantially greater than the cross-sectional area of the base body in the region of the cutout, but not substantially smaller than the cross-section of the rest of the base body. A method for using this force sensor is also disclosed.