A blood pump includes an impeller; a drive shaft coupled to the impeller and configured to rotate with the impeller; and a rotor coupled to the drive shaft and configured to rotate with the drive shaft. The rotor includes a driven magnet having an outer surface. A corrosion-resistant coating may be disposed on the outer surface of the driven magnet. A stator is disposed adjacent the rotor and configured to drive the rotor, causing the rotor to rotate; and a motor is configured to drive the stator. A protection assembly may be disposed adjacent the stator and configured to receive an end of the drive shaft, and may include a protection assembly housing enclosing a protective fluid chamber, the protective fluid chamber including the driven magnet and at least a portion of a bearing configured to engage the end of the drive shaft.

A gantry system comprises a bearing assembly including at least two rows of ball bearings, an inner race portion including an inner race and a first outer peripheral face and an outer race portion including an outer race and a second outer peripheral face. A first mounting plate is mounted to the first outer peripheral face of the inner race portion. The first mounting plate has a substantial portion that is relatively flat where it contacts the first outer peripheral face. In addition, the first mounting plate is relatively thin in comparison to the inner race portion such that the first mounting plate conforms to the surface of the inner race portion.

A drive unit for providing drive from a robot arm to an instrument comprises a plurality of drive elements for engaging corresponding elements of the instrument, and a load cell structure. Each drive element is movable along a drive axis and the drive axes of each of the drive elements are substantially parallel to each other. The load cell structure includes a plurality of deflectable bodies coupled to the drive elements for sensing load on the drive elements parallel to their drive axes, and a frame. The frame includes an integral member supporting the deflectable bodies in such a way as to isolate each deflectable body from the load applied to the or each other deflectable body.

The invention relates to a holding device comprising at least one locking unit (2) having at least two sockets (3), wherein the sockets (3) are designed to make it possible for joint heads (5) received in the sockets (3) to each pivot about a pivot axis, as well as to a locking unit, to a tool mount and to an instrument holder for use in magnetic resonance imaging (MRI).

A rotatable connection for a mounting device for arrangement in an operating room, the rotatable connection includes an adjustable stop mechanism, which can be disposed between a first connection component and a second connection component, and is configured to define at least two different relative rotational angles of the connection components relative to each other or at least two different ranges or rotation. The adjustable stop mechanism includes at least one stop device having a respective counterstop, which is axially disposed between a first part and a second part that are each mounted in a torsion-proof manner. The at least one stop device is configured to define the different relative rotational angles or ranges of rotation by way of the respective counterstop. The invention further relates a support system or a mounting device comprising such a rotatable connection, and to a method for setting the adjustable stop mechanism.

A hinge has a hinge body forming an articulating section extending between a first end and a second end of the hinge. The articulating section is adapted to bend from a neutral axis when the first and second ends are parallel to an angular range in which the first end is arranged among a plurality of angles within the angular range relative to the second end. The hinge body may define a receptacle along the articulating section, and an insert may be provided for insertion into the receptacle. The insert can modify the stiffness of the hinge in the angular range and is arranged parallel to the neutral axis.

A joint assembly of an adapter defines a first longitudinal axis and includes first and second hinges, first and second rings, a joint cover, and a biasing mechanism. The joint cover has first and second cover portions. The first ring is pivotally coupled to the first hinge and the first cover portion is pivotally coupled to the first hinge to define a first joint center. The second ring is pivotally coupled to the second cover portion and the second hinge is pivotally coupled to the second ring to define a second joint center that is spaced from the first joint center. The first and second joint centers define a cover axis of the joint cover. The biasing mechanism is engaged with the first ring and the joint cover to bias the joint cover towards an aligned configuration in which the cover axis is aligned with the first longitudinal axis.

In one embodiment, a rotating anode type X-ray tube comprises a fixed shaft having a first surface, a rotor, a cathode emitting electrons, and an anode target. The rotor comprises a first cylinder having a second surface, a second cylinder, and a third cylinder. A first threaded portion on an inner surface of the first cylinder and a second threaded portion on an outer peripheral surface of the third cylinder are tightened. A screw member is screwed in a third threaded portion on an inner peripheral surface of a hole which penetrates the third cylinder, and a tip portion of the screw member presses the second cylinder against the second surface.

Embodiments of the disclosure include an extended length core sample scanning apparatus that enables the imaging of extended length core samples using medical-type CT scanners. The extended length core sample scanning apparatus has a frame that defines a U-shaped receptacle that receives core housing containing the core sample when the core sample is placed in a CT scanner. The extended length core sample scanning apparatus may have two or more rollers located in the U-shaped receptacle to enable translation of the extended length core sample through a CT scanner during scanning. The rollers may also provide for a minimum clearance between the core housing and the walls of the U-shaped receptacle. Methods of imaging an extended length core sample are also provided.

Provided are a bearing and a medical device in which a gap is secured between an inner ring and an outer ring, and the gap can be used as a flow path for a fluid or an object. A bearing having a plurality of rolling elements between an inner ring and an outer ring is provided with a raceway surface on which the rolling elements roll on the outer ring and receiving portions for rotatably accommodating the rolling elements at a position of the inner ring facing the raceway surface.