A wire rope inspection system is provided with: an excitation unit configured to apply a magnetic flux to a wire rope that is an inspection target; a detection unit configured to detect a magnetic flux of the wire rope to which the magnetic flux has been applied by the excitation unit; a detachable unit configured to be detachably mounted to a stationary unit fixed in proximity to the wire rope, the detachable unit being provided with at least the detection unit; and a positioning mechanism configured to position the detachable unit with reference to the stationary unit such that the detection unit is arranged at a predetermined position with reference to the wire rope.

The invention relates to a method for condition monitoring of a rope of a hoisting apparatus, and to an arrangement for condition monitoring of a rope of a hoisting apparatus, preferably of an elevator for transporting passengers and/or goods. The arrangement for condition monitoring of a rope of a hoisting apparatus according to the present invention, in which rope comprises one or more conductive load bearing member for bearing the load exerted on the rope in longitudinal direction and extending parallel to each other and to the longitudinal direction of the rope, comprises an at least one eddy current testing probe, placed near said rope for generating an alternating magnetic field, said alternating magnetic field causing eddy currents in said rope, and for detecting a secondary magnetic field being generated by said eddy currents in said rope as eddy current detection data, and an on-line monitoring unit receiving and utilizing said eddy current detection data for on-line condition monitoring of said rope.

This wire rope inspection device is provided with an urging unit for urging a detection unit in a direction to approach a wire rope by an elastic force to an inspection position at which the detection unit is arranged at a time of an inspection operation for inspecting the wire rope and a drive unit for moving the detection unit in a direction away from the wire rope to a normal operation position at which the detection unit is arranged at a time of a normal operation.

A magnetic body inspection device (100) is a magnetic body inspection device for inspecting states of a plurality of magnetic bodies (W) by a total magnetic flux method that measures a magnetic flux inside the magnetic body (W). The device includes a plurality of detection coils (10) each for detecting the magnetic field of each of the magnetic bodies (W), an excitation unit (11) provided for the plurality of magnetic bodies (W), and a detection signal output unit (12) for outputting a detection signal based on the magnetic field of each of the magnetic bodies (W).

A low-power wire rope safety diagnosis method and a system thereof are provided. Since a sensor should be continuously turned on to allow a plurality of sensor nodes to diagnose safety of a wire rope in real time and it consumes much power, there is provided a method and system which can perform the safety diagnosis only when a movement is detected while being in a standby mode to reduce the power consumption, and determine a defect more correctly and consistently by utilizing deep learning when defects are determined through a wire rope safety diagnosis.

A low-power wire rope safety diagnosis method and a system thereof are provided. Since a sensor should be continuously turned on to allow a plurality of sensor nodes to diagnose safety of a wire rope in real time and it consumes much power, there is provided a method and system which can perform the safety diagnosis only when a movement is detected while being in a standby mode to reduce the power consumption, and determine a defect more correctly and consistently by utilizing deep learning when defects are determined through a wire rope safety diagnosis.

A wire rope inspection device (100) includes a controller 21 configured or programmed to detect a state of a wire rope (W) based on a difference at substantially a same position between a first detection signal acquired by a differential coil (10) in a first measurement and a second detection signal acquired by the differential coil in a second measurement after the first measurement.

This invention relates to a method for defining absolute position information of an elevator car. The method comprises: obtaining continuously a pulse position information of the elevator car; and defining an absolute position information of the elevator car by adding a predefined correction value to the obtained pulse position information of the elevator car. The predefined correction value indicates a drift between the obtained pulse position information of the elevator car and the actual pulse position of the elevator car. The invention also relates to a safety control unit and an elevator system performing at least partly the method.

A wire rope inspection device (100) includes a controller 21 configured or programmed to detect a state of a wire rope (W) based on a difference at substantially a same position between a first detection signal acquired by a differential coil (10) in a first measurement and a second detection signal acquired by the differential coil in a second measurement after the first measurement.

A wire rope inspection device (100) is provided with a first detection coil (30) and a second detection coil (40), and a processing unit (61). The second detection coil is arranged to be inclined to the first detection coil when viewed from a direction (X-direction) perpendicular to a first direction (Z-direction) along which the first detection coil moves relative to the wire rope (W). The processing unit identifies an abnormality position of the wire rope in the first direction based on a detection signal detected by the first detection coil and identifies an area of the abnormality position of the wire rope in a cross-section based on a detection signal detected by the second detection coil.