Described and depicted is a processing device for processing, preferably filled and scaled, packages, in particular cardboard composite packages, having a processing station for processing the packages, preferably for forming the packages and/or for applying additive packaging materials to these packages, having a transport device for supplying, in particular accumulated, packages along a supply path and for further transport of separated packages in the direction of the processing station along a relay path and having a separating device for separating the packages supplied via the transport device, wherein the separating device has a plurality of sliding means circulating respectively along a common, closed transport track and distributed along the transport track for moving the packages in an interlocking manner from the supply path to the relay path at least substantially transverse to the supply path and/or relay path in the region of the separating device. So that a reliable operation of the processing device can be achieved with at same time higher processing speeds, it is provided that the sliding means mounted on two rotary discs which are spaced apart from one another in the vertical direction and are rotatable about a respective axis of rotation, and in that the axes of rotation of the rotary discs are arranged parallel to one another and spaced horizontally apart from one another.

A positive displacement sorter and method of diverting articles includes a conveying surface configured to convey articles in a longitudinal direction and at least one diagonal take-away lane, extending diagonally from the conveying surface to receive articles being diverted from said conveying surface. A plurality of pushers are configured to move together in a lateral direction in order to displace an item on the conveying surface to the diagonal take-away lane. A rotational system is configured to rotate a leading portion of a diverted article in the direction of the take-away lane. A belt drive system is provided for driving live roller conveyors about a curved section of a roller conveyor of the sorter. The drive belt is guided along a single conical drive plane that maintains the orientation of the drive belt relative to the single conical drive plane and limits twisting and stress in the drive belt.

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 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 kitting system is disclosed. In various embodiments, the kitting system includes a conveyance structure configured to impart to an item a first net resultant force substantially in a first direction, wherein the first direction is associated with a direction of flow from a source end of the conveyance structure to a destination end opposite the source end and associated with a pick-up zone from which the item is to be retrieved; a sensor configured to provide a sensor output associated with the pick-up zone; and a processor configured to provide a control input to one or both of the conveyance structure and a disrupter device associated with the conveyance structure based at least in part on the sensor output.

The destacker apparatus (1), comprises: a succession of conveyors (10, 11, 12) arranged inclined relative to the horizon, each comprising a mobile surface (S) for receiving and supporting articles (J, K) carried upwards by the conveyors (10, 11, 12); and a device for varying the pressure of a fluid (2).

The surface (S) of the conveyors (10, 11, 12) has through holes and the pressure varying device (2) is fluid dynamically connected to this surface (S).

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.

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 physical distribution system includes first and second conveyance paths, first and second sensors, and a processor. The first sensor detects a package passing along the first conveyance path. The second conveyance path merges with the first conveyance path at a junction. The second sensor detects a package passing along the second conveyance path. The processor counts a first number of packages present in a first convergence monitoring section determined in the first conveyance path upstream the junction, and counts a second number of packages present in a second convergence monitoring section determined in the second conveyance path upstream the junction, determines an order in which packages in the first and second convergence monitoring sections pass the junction, based on the first number and the second number, and control the first and second conveyance paths, such that the packages pass the junction in the determined order.

A method for grouping and/or separating products transported in rows. With the aid of a first conveyor belt, the products to be grouped or separated are conveyed onto a second conveyor belt connected in series with the first conveyor belt until a downstream product of the products to be grouped or separated runs up against a dividing web of a dividing device associated with the second conveyor belt. After or as the downstream product runs up against the dividing web, a conveyance of products into the upstream region of the second conveyor belt effected by means of the first conveyor belt is interrupted. The second conveyor belt is driven continuously in a transport direction specified by the second conveyor belt, and the dividing web runs along with the second conveyor belt in its transport direction over a defined distance and is then removed from the product flow of the second conveyor belt.