A singulating conveyor having a herringbone pattern includes transporting rollers extending from the entry end to the exit end. The rollers are divided into four longitudinal zones, and each longitudinal zone is divided into a pair of side-by-side complementary outside and inside lateral zones. The rollers of each of the eight lateral zones are driven by a separate motor and V-Belt drive system that can be operated at differing speeds. The speed of the transporting rollers in the four longitudinal zones increases successively from the longitudinal zone adjacent the conveyor entry end towards the longitudinal zone having the discharge rollers, and the speed of the rollers of the outside lateral zones operate at higher speeds than the rollers of the adjacent inside lateral zones. Some of the rollers in the outside lateral zones preferably have higher coefficients of friction than the rollers of adjacent inside lateral zones.

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.

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.

A metal container conveyor system is provided. The metal container conveyor system includes (i) a conveyor body for moving metal containers, and (ii) at least one diverter mechanism configured to change a width of a portion of the conveyor body.

A divider arrangement, guide device, for guiding packages between at least two conveyor belts, and method of controlling the same is provided.

An article induction system for preparing a stream of articles, such as mail parcels, for processing employs a series of conveyors operating under control of a controller for feeding articles to an operator at a cull belt at an optimal paced rate. The article induction system includes a destacking section, a separation and alignment section, a buffer section and a culling section manned by an operator. A controller controls the speed of each component based on measurements provided by sensors so as to feed articles to the operator at a desired paced rate.

A side-by-side reducer (SSR) conveyor has one lateral side of driven rollers operating at a different longitudinal running speed than another lateral side of driven rollers. The one lateral has an input section of driven rollers skewed away from the other lateral side followed by a converging zone of driven rollers skewed toward the other lateral side. The separation prevents frictional contact between side-by-side cartons so that one can be longitudinally moved a different velocity than the other to converge in a tandem arrangement.

A divider system for diverting objects from an infeed lane into one or more discharge lanes includes a dividing screw set, a discharge screw set, and a diverting mechanism. The dividing screw set conveys a sequence of objects to an output end of the screw set where the objects are divided by rotation of the dividing screw set and outputted alternately to first and second discharge screws of the discharge screw set to form a first series of objects conveyed by the first discharge screw and a second series of objects conveyed by the second discharge screw. The divider system includes a diverting mechanism which can be selectively actuated to divert objects from one discharge screw to the other discharge screw to form a diverted group.

A method for transferring at least one object (7) from a conveying surface (9) of a supply conveyor (6) onto a surface (15), the method including the following steps: —conveying the object (7) in a conveying direction, the object (7) including a base (7a) that rests on the conveying surface (9), —bringing the object (7) into contact with a guide (16) placed in the conveying direction at a distance from the downstream end line (12) of the supply conveyor (6), —ending the contact between the base (7a) of the object and the conveying surface (9), —dropping the object (7) onto the receiving surface (15), the step of ending the contact between the base (7a) of the object (7) and the conveying surface (9) only taking place after the step of bringing the object (7) into contact with the guide (16).

A conveyor system for conveying electrically conductive articles such as aluminum bottles or cans. The conveyor system comprises a plurality of coils below the top surface of an electromagnetic conveyor at a junction between an infeed conveyor and a discharge conveyor. The coils propagate electromagnetic flux waves that induce currents in the electrically conductive articles that force the articles to follow a conveying path from the infeed to the discharge conveyor. Dead spots on the electromagnetic conveyor can be eliminated by adjusting the coil drive waveforms. And a long electromagnetic conveyor driven by a train of narrow pulses is used to singulate electrically conductive articles.