A method for transferring and/or stacking products, the method including providing a first plurality of products as a first unit, pushing the first unit onto a lifting plate, lowering the plate, providing a second plurality of products as a second unit, pushing the second unit onto the top of the first unit to create a stack.

The innovation disclosed herein is an improved palletiser for loading and packaging unstable articles, such as plastic, glass, steel, aluminium, etc. containers onto a pallet for bulk storage and/or transport. The innovation includes a pallet station having a pallet housing that receives pallets, a layer pad store substantially aligned with the pallet housing, a container lifting sub-assembly that receives a predetermined row of containers, a pusher assembly that urges the predetermined row of containers onto a pallet, and a layer pad transfer assembly.

A labeling machine for producing respective multipacks, the multipacks comprising a group of products secured together by a label. The labeling machine includes a conveyor that comprises a conveyor module for forming a group of products from a plurality of individual products and for providing the group of products to a labeling process to produce a multipack of products. The labeling machine includes at least one labeler. The conveyor module comprises at least two conveying units which each conveying unit comprising at least one carrier. The movement of the conveying units may be individually controllable allowing two carriers on different conveying units to cooperate as a fixing unit. A method of producing respective multipacks, which each comprise a group of products, using the labeling machine is also provided.

A jump shuttle conveyor system is configured to receive formed food patties from a molding assembly of a patty forming machine. The system includes a lifting plate and belt assembly coupled to a frame which are configured to be indexed to different vertical positions relative to the frame. Formed food patties are received on a belt of the belt assembly thereon, and can be moved off of the belt onto a transfer shuttle conveyor system. An output conveyor system can be provided to receive the formed food patties.

A stacking system for aligning and stacking stamped sheet metal parts is provided. The stacking system includes a frame configured to coordinate a plurality of sub-systems including a parts catcher, receiving head including a plurality of alignment cylinders, and a set of elevating tables on a shuttle platform. Parts are received by the catcher from a conveyor belt and transported to a receiving head for alignment to a targeted position. After the formed part is aligned to the stack, the lift table is lowered such that space is available for another part to be aligned. After a predetermined number of formed parts has been stacked, a table shuttle will slide the lift table to an unloading position accessible by a fork truck.

An automated storage and retrieval system includes a storage array of storage locations for case units. An in-out case conveyor is capable of bi-directionally transporting case units to and from the storage array, and an in-out loaded pallet conveyor is capable of bi-directionally transporting loaded pallets towards and away from the storage array. A palletizer-depalletizer cell includes a bi-directional pallet transport system with more than one independently driven pallet transports, each with a different pallet holder independently movable relative to a cell frame. Placement of case units commissioning a pallet layer loading a pallet, and removal of case units decommissioning a pallet layer unloading another pallet are both effected at the common pallet layer interface at a predetermined level of the cell frame. The pallet transports independently index a first and a second of the different pallet holders, each independently holding the pallet loading at the common pallet layer interface.

An automated storage and retrieval system includes a storage array of storage locations for case units. An in-out case conveyor is capable of bi-directionally transporting case units to and from the storage array, and an in-out loaded pallet conveyor is capable of bi-directionally transporting loaded pallets towards and away from the storage array. A palletizer-depalletizer cell includes a bi-directional pallet transport system with more than one independently driven pallet transports, each with a different pallet holder independently movable relative to a cell frame. Placement of case units commissioning a pallet layer loading a pallet, and removal of case units decommissioning a pallet layer unloading another pallet are both effected at the common pallet layer interface at a predetermined level of the cell frame. The pallet transports independently index a first and a second of the different pallet holders, each independently holding the pallet loading at the common pallet layer interface.

The invention relates to an apparatus for stacking battery plates comprising a delivery conveyor for supplying battery plates sequentially along a delivery path. The delivery conveyor includes a plurality of spaced apart plate carriers each configured to support at least one battery plate in use, the plate carriers defining a series of gaps between adjacent plate carriers, wherein each gap is larger than the battery plate. The apparatus further includes a stop mechanism, configured to selectively intercept the delivery path at a plurality of indexed stop positions without impeding the delivery conveyor; wherein when the stop mechanism intercepts the delivery path at a selected one of the stop positions in use, it interrupts the movement of the battery plates on the delivery conveyor causing the battery plate(s) to move off the respective plate carrier and pass through the subsequent gap of the conveyor. The apparatus also includes a plate stacking mechanism for receiving battery plates as they are moved off the delivery conveyor by the stop mechanism.

A board stacking system for stacking board layers into a stack, and associated method are provided. The board stacking system includes a board stacking apparatus adapted to arrange board layers into the stack. The board stacking apparatus having a stack holder comprising an adjustable stacking area for supporting the stack, the stacking area having a length defined between a front edge and a back edge. The board stacking apparatus further having one or more stacking arms operable to receive board layers from a board dispensing mechanism and sequentially arrange the board layers onto the forming stack. The board stacking system further includes a scanner positioned and configured for measuring a width of the board layers and transfer the information to the stack holder to allow adjustment of the length of the stacking area to substantially correspond to the width of the previously measured board layer.

A tray supplier which performs supplying and collecting of trays includes a supply-side tray storage unit, a collection-side tray storage unit, a first tray placer and a second tray placer on which the trays are placed, and a first placer mover and a second placer mover which respectively move the tray placers between the supply-side tray storage unit and the collection-side tray storage unit, in which a first movement shaft of the first placer mover and a second movement shaft of the second placer mover are disposed parallel to each other, lifting and lowering units which lift or lower the first tray placer and the second tray placer are provided, and interference between the placer movers does not occur.