A method of recognizing consecutive objects on a conveying path in a detection zone arranged on the conveying path comprises the following steps: generating an electromagnetic radio frequency field radiating into the detection zone by way of a radio frequency sensor; measuring a time curve of a dielectric conductivity in the detection zone by using of the radio frequency field of the radio frequency sensor; and determining contour information of the consecutive objects from the time curve of the dielectric conductivity.

A sensor and monitoring system that can prevent the accumulation of scraps of a transport object on the sensor are provided. A sensor 4 is located below a return-side portion 2a of a conveyor belt 2, and includes: a detector 40 that detects a detection object 3 embedded in the conveyor belt; and a cover 41 covering at least an upper part of the detector, wherein the cover has a downward surface 411 that extends continuously downward from a top part of the cover while extending outward in the horizontal direction.

A differential impulse conveyor system including detectable markers disposed in a series on a moving component of the conveyor system. A stationary sensor disposed in close proximity to the markers generates a signal when the moving component is in a first range of motion to dispose the markers proximal to the sensor, and the sensor either fails to generate a signal when the moving component is not within the first range of motion. The sensor signal causes a current conditioning device to condition current from a current source to operate a motor to power the conveyor tray at a first rate of acceleration in a first mode, and the lack of the signal causes the current conditioning device to operate the motor to power the conveyor tray at a second rate of acceleration in a second mode. Markers may be positionable to optimize the timing of the current modes.

A differential impulse conveyor system including detectable markers disposed in a series on a moving component of the conveyor system. A stationary sensor disposed in close proximity to the markers generates a signal when the moving component is in a first range of motion to dispose the markers proximal to the sensor, and the sensor either fails to generate a signal when the moving component is not within the first range of motion. The sensor signal causes a current conditioning device to condition current from a current source to operate a motor to power the conveyor tray at a first rate of acceleration in a first mode, and the lack of the signal causes the current conditioning device to operate the motor to power the conveyor tray at a second rate of acceleration in a second mode. Markers may be positionable to optimize the timing of the current modes.

In a food conveyor system configured to drive a conveyor belt in one direction to direct food material for further processing and drive the conveyor belt in a reverse direction upon the sensing of metal in the food material, the conveyor belt is cleaned by one or more belt cleaners including scrapers which are automatically angularly repositioned upon the changing of the drive direction of the conveyor belt, with the angular movement being limited to acute angles relative to the vertical. The belt cleaners are mounted through linkage assemblies for ease of cleaning and replacement. The food conveyor system also employs one or more chute members for directing the food material, with the one or more chute members being mounted through a quick release connection employing keyhole slots upon flexing of the chute member(s).

A system for assembling elements into framing components is provided along with a method for the use thereof. The system may comprise a frame, a fastening tool, a first conveyor, a second conveyor, and a holder. The pieces of the system may be connected so that they may operate automatically, with only minimal operation by a user. The system increases the speed, efficiency, precision, repeatability, and safety of assembling framing components.

A sensing system (110) positioned relative to the conveyor belt (34) to sense the physical configuration of the belt side links (44) and (46) as well as the inclination or tilt of the side links.

A conveyor system includes a transport chain with a sequence of interconnected chain links, a guide structure for slidingly supporting the transport chain so that chain links of the transport chain define a substantially flat support surface for supporting articles to be transported, and a motor for causing the transport chain to move with respect to the guide structure along a first direction parallel to the support surface. The motor comprises an electric linear motor including a plurality of magnets, each one located in a respective chain link, and a plurality of propulsion electromagnets located on the guide structure.

A contactless monitoring system detects operating performance of movers in an independent cart system. A contactless sensor is provided on an actuator to automatically track a mover as it travels along the track. The sensor includes a transmitter configured to transmit a signal and a receiver configured to receive the signal after it is reflected off the mover. The actuator may be configured to mover the sensor in a single axis or in multiple axes of motion. As a mover travels along the track, the sensor transmits a signal towards the mover and detects the signal after it has been reflected off the mover. A controller may synchronize motion of the actuator with motion of the mover, such that the sensor may continually transmit the signal off the mover for at least a portion of the travel by the mover along the track.

Provided is a position information processing device 3 for a conveyor belt, including a plurality of magnet rows 14, a magnetic sensor unit 31, and a processing unit 33, each of the plurality of magnet rows forms a pole arrangement providing position information, the plurality of magnet rows are different from one another in the pole arrangement, the magnetic sensor unit is configured to detect respective poles of the plurality of magnets forming the magnet row on the inner circumferential side or the outer circumferential side of the belt body, and the processing unit is configured to specify the pole arrangement of the magnet row based on an output from the magnetic sensor unit.