The invention relates to a dispenser for transferring layers of goods from a pallet onto a receiving surface and then down a discharge conveyor. The dispenser incorporates a vertically movable platform capable of bringing a first tier of goods in alignment with a rotary table. Sweeper arm moves the goods on to the table as it rotates. Goods accumulate on the rotary table and then become guided down a discharge conveyor for further processing.

A conveyor bed including a conveyor frame, a first set of rollers, a second set of rollers, and a pivotable frame is provided. The first set of rollers are coupled to the conveyor frame to transport an article from an upstream location to a downstream location. The pivotable frame pivotably coupled to a side of the of the conveyor frame. The second set of rollers mounted to the pivotable frame, positioned below the first set of rollers. A belt wrapped is around the second set of rollers, and selectively engages and disengages the first set of rollers in response to pivoting the pivotable frame based on predefined criteria.

Various embodiments described herein generally relate to techniques for conveying articles on a conveyor system of a robotic material handling system in a material handling environment. In accordance with an embodiment, the robotic material handling system includes a front portion and a rearward conveyor. The front portion may be expandable to a first configuration and retractable to a second configuration. On detecting a jam on the front portion, the robotic material handling system may actuate expansion of the front portion to the first configuration, and attempt to dislodge the jammed articles by causing one or more of (i) separating the jammed articles by activating one or more of a plurality of zones of the front portion under the jammed articles, and/or (ii) activating one or more of the plurality of zones under the jammed articles in a reverse direction.

Various embodiments described herein relate to controlling an accumulation conveyor that comprises at least a first zone that is upstream of a second zone and the second zone that is upstream of a third zone. A second control module associated with the second zone receives a third feedback signal, indicating that a third sensor is blocked, from a third control module associated with the third zone. The second control module sets a second drive assembly associated with the second zone to a disengaged state, and receives a first signal from a first control module associated with the first zone. The first signal indicates that one of a first article having an irregular boundary or a second article having a regular boundary exits from the first zone. The second control module controls the second drive assembly and a second brake assembly based on the indication by the first signal.

An article processing station is characterized by an accumulating article shaft and robotic EOAT receiving articles entering the shaft. The shaft includes a grouped article receiving deck within an egress portion of the shaft, opposingly paired sidewalls, and an end wall downstream of the sidewalls. The deck includes spaced apart deck fingers, the end wall includes spaced apart wall fingers, and the EOAT includes spaced apart tool fingers. The tool fingers are registerable in relation to spaces of the spaced apart wall fingers and the spaced apart deck fingers so as to pass there through. The tool travels to, through and from the shaft, so as to receive articles entering the ingress portion of the shaft while traveling from the ingress portion towards the egress portion in furtherance of depositing an article group upon the deck during travel from the shaft.

An apparatus for handling three-dimensionally curved snack food chips. The apparatus includes a first conveyor for conveying a series of the snack food chips on a conveying surface and an inverting station located at an output end of the first conveyor. The inverting station includes an inverter configured for transferring the snack food chips from an output end of the first conveyor into contact with an internal concave surface of the inverter. A drive system for the inverter is configured to move the internal concave surface downwardly to cause movement of the snack food chips downward from an upper portion to a lower portion of the internal concave surface. A depositing station is located and configured for depositing the snack food chips from the lower portion of the internal concave surface onto a second conveyor configured for receiving snack food chips from the depositing station and conveying them away.

A system and an apparatus capable of independently driving movers are described herein. The system and apparatus includes: a track that forms a path for movers; a plurality of movers movably mounted on the track for moving along the path; and a plurality of drive elements fixedly arranged along the track. The drive elements each have a surface that is oriented to contact a driven member of the movers. The drive elements are configured to sequentially engage the driven member of a plurality of the movers to provide controlled independent motion of the movers along the track. The drive elements may be driven by rotary motors. A method of independently driving movers is also described herein.

A system and an apparatus capable of independently driving movers are described herein. The system and apparatus includes: a track that forms a path for movers; a plurality of movers movably mounted on the track for moving along the path; and a plurality of drive elements fixedly arranged along the track. The drive elements each have a surface that is oriented to contact a driven member of the movers. The drive elements are configured to sequentially engage the driven member of a plurality of the movers to provide controlled independent motion of the movers along the track. The drive elements may be driven by rotary motors. A method of independently driving movers is also described herein.

A conveyor controller for being implemented into a conveyor system includes control circuitry and one or more network interfaces for coupling with other conveyor controllers. In one embodiment, the control circuitry configured for detecting whether another conveyor controller is connected and to determine which network interface is used in order to set the direction of the conveyor system. In another embodiment, the control circuitry is configured, to receive configuration data from a conveyor controller connected to a network interface, and to detect if another conveyor controller is and to transmit configuration message to another conveyor controller that includes additional configuration data associated with the conveyor controller. In still another embodiment, the control circuitry transmits configuration data to a replacement conveyor controller upon getting a request from the replacement conveyor controller that has been connected to a network interface.

Herein described is a system and method for packaging packages (C), comprising the steps of: forming a row of packages (C) advancing, one following the other, along a pre-set advancement direction (A), picking up at least two first packages (C) from the row, superimposing each of said first packages (C) on a respective second package (C) of the row, releasing each of the first packages (C) resting on the respective second package (C), obtaining at least two stacks of packages, each of which comprises at least two mutually superimposed packages (C) and stabilising the stacks of packages (C).