The present disclosure is to provide a detection device. The detection device is configured to measure the coaxiality of the three camshaft mounting holes of the valve chamber cover during usage; and meanwhile, the detection device has the characteristics of high measurement accuracy, simple structure, low production cost, and the like.

The present disclosure is to provide a detection device. The detection device is configured to measure the coaxiality of the three camshaft mounting holes of the valve chamber cover during usage; and meanwhile, the detection device has the characteristics of high measurement accuracy, simple structure, low production cost, and the like.

An adapter assembly that includes a housing, a channel formed within the housing that is configured to receive a medical device, a first groove formed along an interior wall of the channel that is configured to at least partially receive a first retaining element, and a second groove formed along the interior wall of the channel that is configured to at least partially receive a second retaining element. The first retaining element is configured to extend outward from the first groove and the second retaining element is configured to extend outward from the second groove, such that the first and second retaining elements abut against the medical device received through the channel.

An adapter assembly that includes a housing, a channel formed within the housing that is configured to receive a medical device, a first groove formed along an interior wall of the channel that is configured to at least partially receive a first retaining element, and a second groove formed along the interior wall of the channel that is configured to at least partially receive a second retaining element. The first retaining element is configured to extend outward from the first groove and the second retaining element is configured to extend outward from the second groove, such that the first and second retaining elements abut against the medical device received through the channel.

A radial force device for a contour measuring instrument for measuring a contour of a shaft-shaped workpiece which can be rotated about an axis of rotation. The radial force device has a clamping body, a force introduction roller, at least one counter-roller and a coupling device. The clamping body is shaped for fitting radially around a workpiece portion, received in the contour measuring instrument, of the workpiece. The force introduction roller is designed to apply a mechanical radial force to the workpiece in order to apply a load to the workpiece, wherein the force introduction roller is mounted in a radially movable manner on the clamping body. The counter-roller is mounted in the clamping body and designed to support the workpiece during the application of the force. The coupling device is shaped for coupling the clamping body to the contour measuring instrument.

A method for calculating eccentricity of rotor assembly axis based on radial runout measurement comprises matrix characterization of data and calculation of relative runout value at each point, establishment of a spring equivalent model and calculation of contact force, eccentric direction and magnitude; calculation of relative runout value; establishment of a spring equivalent model to analyze the relationship between force and displacement in each phase of a contact process, and then an uneven contact force at each point is obtained; and determination of eccentricity is to determine the magnitude of eccentricity. Based on the measured radial runout data in production practice, this method realizes the prediction of eccentricity of axis before assembly, improves the coaxiality of rotors after assembly, and has important practical guiding significance for axis prediction as well as assembly phase adjustment and optimization in the assembly process of aero-engine rotor pieces.

The present invention provides a typical rotational part characterization method based on actually measured run-out data. Aiming at the characterization of rotational parts containing morphology data, the present invention proposes a matrix form characterization method in which microscopic run-out data and macroscopic axial size are comprehensively considered. In addition, the method can be applied to an assembly accuracy calculation process, and can characterize a single part containing morphology feature quantities by using only one matrix M. The calculation process of accuracy transfer is simplified, and a high-efficiency calculation model is provided for the prediction of assembly accuracy.

A driving force generating unit 27 that generates a driving force; a movable portion 29 that is movable in a crossing direction crossing an axial direction of the ferrule by the driving force of the driving force generating unit; a friction contact portion 31 that is provided on the movable portion to be in contact with an outer periphery of the ferrule, the friction contact portion being configured to rotate the ferrule by a frictional force when the movable portion is moved; and a controller that controls the driving force generating unit are provided, and the controller controls the driving force generating unit to move the movable portion in one direction of the crossing direction for rotating the ferrule by the friction contact portion for measuring the eccentricity, and further move the movable portion to the one direction of the crossing direction for rotating the ferrule by the friction contact portion for adjusting the eccentric direction to the predetermined direction.

A driving force generating unit 27 that generates a driving force; a movable portion 29 that is movable in a crossing direction crossing an axial direction of the ferrule by the driving force of the driving force generating unit; a friction contact portion 31 that is provided on the movable portion to be in contact with an outer periphery of the ferrule, the friction contact portion being configured to rotate the ferrule by a frictional force when the movable portion is moved; and a controller that controls the driving force generating unit are provided, and the controller controls the driving force generating unit to move the movable portion in one direction of the crossing direction for rotating the ferrule by the friction contact portion for measuring the eccentricity, and further move the movable portion to the one direction of the crossing direction for rotating the ferrule by the friction contact portion for adjusting the eccentric direction to the predetermined direction.

A method for mounting a sensor bearing unit providing a bearing and an impulse ring provided with a target holder and with a target mounted on an axial portion of the target holder. The method including measuring an eccentricity E.sub.1 between the target and the axial portion of the target holder, measuring an eccentricity E.sub.2 between a groove made in the bore of an inner ring of the bearing and the bore, introducing the target holder inside the groove, turning the target holder inside the groove to an angular position in which the eccentricity E.sub.total between the target and the bore of the inner ring is less than or equal to a predetermined value which is lower than the sum of the eccentricities E.sub.1 and E.sub.2, and securing the target holder inside the groove of the inner ring at the angular position.