An apparatus for distributing tie plates alongside rails of a railroad track including a singulating system for separating and singulating tie plates to be distributed along the rails of a railroad track, an orientation system positioned beneath the singulating system for orienting the tie plates with the correct side up, and a distribution system for distributing tie plates along the rails of a railroad track.

Described is a component (1) for powering robots, automation systems and the like which comprises, on a frame (2), a series of belts (3, 4) for conveying objects (9) designed to be gripped by a robot. The conveyor belts (3, 4) constitute a closed path and have a first belt (3) and at least a second belt (4) positioned in such a way that the objects (9) pass from the first belt (3) to the second belt (4) cyclically and continuously.

Described is a component (1) for powering robots, automation systems and the like which comprises, on a frame (2), a series of belts (3, 4) for conveying objects (9) designed to be gripped by a robot. The conveyor belts (3, 4) constitute a closed path and have a first belt (3) and at least a second belt (4) positioned in such a way that the objects (9) pass from the first belt (3) to the second belt (4) cyclically and continuously.

The invention relates to an apparatus for the lateral overlapping of portions which are transported in a longitudinal direction and which each comprise at least one slice cut off from a food product, having at least one overlapping unit which comprises a belt conveyor having at least two tracks, wherein an upper track and a lower track are deflected at the incoming side about a common input axle and at the outgoing side about two output axles disposed at different height levels.

The invention relates to an apparatus for the lateral overlapping of portions which are transported in a longitudinal direction and which each comprise at least one slice cut off from a food product, having at least one overlapping unit which comprises a belt conveyor having at least two tracks, wherein an upper track and a lower track are deflected at the incoming side about a common input axle and at the outgoing side about two output axles disposed at different height levels.

A packaging assembly and a method of operating such a packaging assembly, the packaging assembly comprises at least one of a thermoform packaging machine, a separation robot, a conveyor and a checkweigher. The separation robot is operable to adjust a distance between packages of a group of packages formed by the packaging machine. The conveyor and the separation robot may be operated together to provide a flow of packages that is supplied to the checkweigher, wherein the flow of packages may include substantially constant distances between the individual packages.

There is provided a component mounting system including: a component mounting device group in which a plurality of component mounting devices that mount components supplied to a board transported in from an upstream side by a tape feeder and transport out the board to a downstream side, and cut a carrier tape after supplying the components by a cutter device and discharge scraps of carrier tape, are installed on a floor surface while being arranged in a direction of conveying the board; a main conveyor that is installed along an arrangement direction of the plurality of component mounting devices in a region on the floor surface under the component mounting device group, and transports the scraps of carrier tape discharged from each of the plurality of component mounting devices; and a scraps storage that is installed outside the region and stores the scraps of carrier tape transported by the main conveyor.

There is provided a component mounting system including: a component mounting device group in which a plurality of component mounting devices that mount components supplied to a board transported in from an upstream side by a tape feeder and transport out the board to a downstream side, and cut a carrier tape after supplying the components by a cutter device and discharge scraps of carrier tape, are installed on a floor surface while being arranged in a direction of conveying the board; a main conveyor that is installed along an arrangement direction of the plurality of component mounting devices in a region on the floor surface under the component mounting device group, and transports the scraps of carrier tape discharged from each of the plurality of component mounting devices; and a scraps storage that is installed outside the region and stores the scraps of carrier tape transported by the main conveyor.

A feeding assembly and a method of feeding components comprising a track along which components can be moved, said track comprising a sloped surface and a ledge, wherein said sloped surface slopes in a direction perpendicular to the direction which the components move along the track so that the components maintain a tilted orientation as they move along the track, a pickup platform comprising a pocket which can receive components from said track, and a pivot on which the pickup platform can be selectively rotated between a first position and second position. In the first position, the pocket is aligned with the track and the pocket is parallel with the sloped surface of the track, so that a component can move from the track into the pocket of the pickup platform. In the second position the pocket is in a horizontal orientation.

The present disclosure provides a warehousing system, a material transporting method, a control terminal, a robot and a storage medium. Where the robot performs material fetching according to a control instruction of a control terminal, transports a material to a destination, and automatically docks with a conveyor line at the destination so as to automatically transport the material to the conveyor line. Manual participation is not needed in the material transporting process, therefore material transporting efficiency can be improved; besides, by configuring different conveyor lines corresponding to different workstations, the material conveying of each workstation does not affect each other, and the workstation with low material processing efficiency does not cause effect on other workstations, thereby facilitating to improve overall work efficiency of all workstations.