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.

The embodiments disclose a stress and strain gauge including at least one stress and strain sensor module configured to sense stresses and strains being applied by an animal biting a rope extending from a protective hand guard, a stress and strain gauge indicator coupled to the at least one stress and strain sensor configured for measuring the sensed stresses and strains as strain levels, a processor coupled to the stress and strain gauge indicator configured to dynamically analyze and compare the strain levels to predetermined threshold strain level measurements to determine a current animal play level that varies incrementally, and an alert module wirelessly coupled to the processor configured to notify a user of the protective hand guard in real-time of the current incremental animal play level.

The embodiments disclose a stress and strain gauge including at least one stress and strain sensor module configured to sense stresses and strains being applied by an animal biting a rope extending from a protective hand guard, a stress and strain gauge indicator coupled to the at least one stress and strain sensor configured for measuring the sensed stresses and strains as strain levels, a processor coupled to the stress and strain gauge indicator configured to dynamically analyze and compare the strain levels to predetermined threshold strain level measurements to determine a current animal play level that varies incrementally, and an alert module wirelessly coupled to the processor configured to notify a user of the protective hand guard in real-time of the current incremental animal play level.

A conveyor system that includes a sprocket, a conveyor element, a sensor, a tensioning system, and an electronic processor. The conveyor element is coupled to the sprocket to move around the sprocket. The sensor is positioned adjacent to the sprocket and configured to generate an output signal indicative of a detection of the conveyor element. The electronic processor is coupled to the sensor and to the tensioning system. The electronic processor is configured to receive the output signal from the sensor, estimate a trajectory of the conveyor element based on the output signal, determine a value for slack distance based on the estimated trajectory of the conveyor element, and control the tensioning system based on the value for slack distance.

A conveyor system that includes a sprocket, a conveyor element, a sensor, a tensioning system, and an electronic processor. The conveyor element is coupled to the sprocket to move around the sprocket. The sensor is positioned adjacent to the sprocket and configured to generate an output signal indicative of a detection of the conveyor element. The electronic processor is coupled to the sensor and to the tensioning system. The electronic processor is configured to receive the output signal from the sensor, estimate a trajectory of the conveyor element based on the output signal, determine a value for slack distance based on the estimated trajectory of the conveyor element, and control the tensioning system based on the value for slack distance.

A containment force apparatus and method a containment force apparatus for measuring containment force on a load, the apparatus comprising a first element configured to contact the load; a second element configured to engage at least a portion of a packaging material on the load and move between a first position associated with the first element to a second position perpendicular to the first position and spaced from the first element a measured distance; an actuator configured to urge the second element to move between the first position and the second position; and a force sensor configured to measure a force exerted on one of the first element or the second element.

A containment force apparatus and method a containment force apparatus for measuring containment force on a load, the apparatus comprising a first element configured to contact the load; a second element configured to engage at least a portion of a packaging material on the load and move between a first position associated with the first element to a second position perpendicular to the first position and spaced from the first element a measured distance; an actuator configured to urge the second element to move between the first position and the second position; and a force sensor configured to measure a force exerted on one of the first element or the second element.

Example implementations relate to a display and strap with sensors. In some examples, an apparatus may comprise a strap, a pressure sensor coupled to the strap, and a display coupled to the strap. In some examples, the apparatus may include a tensioner mechanism coupled to the strap and a motor coupled to the tensioner mechanism. The motor may actuate the tensioner mechanism to adjust the strap to a particular amount of tension, and the particular amount of tension may be based on an amount of pressure detected by the pressure sensor.

Example implementations relate to a display and strap with sensors. In some examples, an apparatus may comprise a strap, a pressure sensor coupled to the strap, and a display coupled to the strap. In some examples, the apparatus may include a tensioner mechanism coupled to the strap and a motor coupled to the tensioner mechanism. The motor may actuate the tensioner mechanism to adjust the strap to a particular amount of tension, and the particular amount of tension may be based on an amount of pressure detected by the pressure sensor.

The present invention discloses a monitoring system of a cable laying state, comprising: a rotary connector, a composite steel cable and a monitoring system. Both ends of the rotary connector are respectively connected with a laid cable and the composite steel cable, wherein the rotary connector is provided with a tension sensor, a video sensor and an inertial navigation measurement module; and tensile force, video, and inertial navigation information are transmitted to the monitoring system through the composite steel cable. The monitoring system of the cable laying state disclosed by the present invention combines a video technology, a measurement technology and an inertial navigation technology and can monitor an environment in a pipeline, a cable core stress state and a three-dimensional coordinate of an actual path during a cable laying process in real time.