A method for controlling a braking system of an electromagnetic motor, the electromagnetic motor having a moveable output shaft, comprising the steps of: receiving a velocity signal and/or an acceleration signal based on movement of the output shaft, said velocity signal and/or acceleration signal having a respective frequency spectrum; identifying an event from the velocity and/or the acceleration signal using the respective frequency spectrum, wherein said event corresponds to an uncontrolled movement of the output shaft and has a characteristic frequency spectrum.

A method for controlling a braking system of an electromagnetic motor, the electromagnetic motor having a moveable output shaft, comprising the steps of: receiving a velocity signal and/or an acceleration signal based on movement of the output shaft, said velocity signal and/or acceleration signal having a respective frequency spectrum; identifying an event from the velocity and/or the acceleration signal using the respective frequency spectrum, wherein said event corresponds to an uncontrolled movement of the output shaft and has a characteristic frequency spectrum.

The invention relates to a sensor housing, which has a base body (10) and a media contacting cap (20). The media contacting cap (20) is arranged partially in a recess (11) of the base body (10) in a detachable manner. It has an annularly running recess (21) for partially receiving a sealing element (60) for a metal clamp connection. Furthermore, the invention relates to a sensor. This has a measuring element (30), which is arranged in the media contacting cap (20) of the sensor housing.

Proposed is a multi-sensor assembly, and the assembly of the present disclosure includes: a first sensor provided in a sensor coupling unit positioned at a front end of a housing; a second sensor provided in a mounting groove that is open toward a front surface of the first sensor; a first connector member configured to transmit a signal measured by the first sensor and, simultaneously, to firmly fix the first sensor to the sensor coupling unit; and a second connector member screw portion formed on an outer surface of a rear end of the first connector member so as to be coupled to a fixture screw portion of an adjustable fixture provided at a rear end of the housing, thereby moving relatively thereto.

Proposed is a multi-sensor assembly, and the assembly of the present disclosure includes: a first sensor provided in a sensor coupling unit positioned at a front end of a housing; a second sensor provided in a mounting groove that is open toward a front surface of the first sensor; a first connector member configured to transmit a signal measured by the first sensor and, simultaneously, to firmly fix the first sensor to the sensor coupling unit; and a second connector member screw portion formed on an outer surface of a rear end of the first connector member so as to be coupled to a fixture screw portion of an adjustable fixture provided at a rear end of the housing, thereby moving relatively thereto.

According to one embodiment, a holding apparatus includes a holding mechanism, a movement mechanism, a measuring instrument, a detector, and a controller. The holding mechanism holds a mobile body. The mobile body is movable through a gap between first and second structure bodies. The first structure body is columnar and extends in a first direction. The second structure body is tubular and is located around the first structure body along a first plane perpendicular to the first direction. The movement mechanism moves the holding mechanism along a circumferential direction around the first direction. The measuring instrument measures a movement amount in the circumferential direction of the holding mechanism. The detector detects a tilt of the holding mechanism in the first plane. The controller operates the movement mechanism and moves the holding mechanism based on a measurement result of the measuring instrument and a detection result of the first detector.

According to one embodiment, a holding apparatus includes a holding mechanism, a movement mechanism, a measuring instrument, a detector, and a controller. The holding mechanism holds a mobile body. The mobile body is movable through a gap between first and second structure bodies. The first structure body is columnar and extends in a first direction. The second structure body is tubular and is located around the first structure body along a first plane perpendicular to the first direction. The movement mechanism moves the holding mechanism along a circumferential direction around the first direction. The measuring instrument measures a movement amount in the circumferential direction of the holding mechanism. The detector detects a tilt of the holding mechanism in the first plane. The controller operates the movement mechanism and moves the holding mechanism based on a measurement result of the measuring instrument and a detection result of the first detector.

The object of the present disclosure is to minimize a number of positioning pins used to position an inner molded portion when an outer molded portion is molded around the inner molded portion. The present disclosure provides a composite molded component including an inner molded portion and an outer molded portion that covers the inner molded portion. An anti-rotation detent hole, which is open at a surface of the inner molded portion, is formed in the inner molded portion, a through hole that extends from a surface of the outer molded portion to the anti-rotation detent hole is formed in the outer molded portion, the anti-rotation detent hole is a hole that is delimited by an inner peripheral surface and a bottom surface, and at least part of the inner peripheral surface is formed in a non-circular shape.

The object of the present disclosure is to minimize a number of positioning pins used to position an inner molded portion when an outer molded portion is molded around the inner molded portion. The present disclosure provides a composite molded component including an inner molded portion and an outer molded portion that covers the inner molded portion. An anti-rotation detent hole, which is open at a surface of the inner molded portion, is formed in the inner molded portion, a through hole that extends from a surface of the outer molded portion to the anti-rotation detent hole is formed in the outer molded portion, the anti-rotation detent hole is a hole that is delimited by an inner peripheral surface and a bottom surface, and at least part of the inner peripheral surface is formed in a non-circular shape.

A sensor device may include a rotor, a stator disposed outside the rotor and a sensor module disposed outside the stator. The rotor may include a sleeve and a magnet coupled to the sleeve, and the magnet may be disposed inside the sleeve. The sleeve may include a fixing part which protrudes from an end of the sleeve and is in contact with the magnet. The sleeve includes a second body, and a third body. The second body is disposed to cover an upper surface of the magnet, and the third body is disposed to cover an outer circumferential surface of the magnet. The magnet is disposed between the shaft and the third body, thereby providing an advantageous effect of increasing a coupling force between the magnet of the rotor and a yoke.