A folding apparatus for folding absorbent sanitary articles having an absorbent central body and two wings projecting from opposite side edges of said absorbent central body, comprising: a vacuum conveyor comprising a conveyor belt which holds the absorbent central bodies of said absorbent sanitary articles and moves said absorbent sanitary articles in a longitudinal direction, and a pair of stationary folding elements that engage respective wings of said absorbent sanitary articles while these are moved in said longitudinal direction by said vacuum conveyor, wherein said conveyor belt comprises a plurality of recessed seats which receive the absorbent central bodies of said absorbent sanitary articles, with said wings extending laterally outwards from said recessed seats on an outer surface of said conveyor belt.

A folding apparatus for folding absorbent sanitary articles having an absorbent central body and two wings projecting from opposite side edges of said absorbent central body, comprising: a vacuum conveyor comprising a conveyor belt which holds the absorbent central bodies of said absorbent sanitary articles and moves said absorbent sanitary articles in a longitudinal direction, and a pair of stationary folding elements that engage respective wings of said absorbent sanitary articles while these are moved in said longitudinal direction by said vacuum conveyor, wherein said conveyor belt comprises a plurality of recessed seats which receive the absorbent central bodies of said absorbent sanitary articles, with said wings extending laterally outwards from said recessed seats on an outer surface of said conveyor belt.

A stacker module includes a lift table, a stacker configured to place sheets that are successively supplied thereto onto the top of a stack forming on the lift table, a controller configured to lower the lift table as the stack grows, a height-adjustable eject table, and an eject mechanism configured to transfer a completed stack from the lift table onto the eject table. The eject mechanism is height-adjustable for transferring stacks onto the eject table in different height positions of the lift table.

A stacker module includes a lift table, a stacker configured to place sheets that are successively supplied thereto onto the top of a stack forming on the lift table, a controller configured to lower the lift table as the stack grows, a height-adjustable eject table, and an eject mechanism configured to transfer a completed stack from the lift table onto the eject table. The eject mechanism is height-adjustable for transferring stacks onto the eject table in different height positions of the lift table.

A method for separating blanks includes continuous conveying of a sheet metal strip in a transport direction to a laser cutting station, concurrent cutting of the sheet metal strip by at least one cutting laser, wherein a cut sheet metal strip is formed from successive sections of the same cutting geometry, transporting the cut sheet metal strip on a first conveyor belt in the transport direction, taking over the cut sheet metal strip from the first conveyor belt, transporting the cut sheet metal strip in the transport direction, separately ejecting the at least one residual blank of each section, transporting the at least one blank of each section into overlap with a second conveyor belt and ejecting the at least one blank from the suction conveyor, and transporting the blanks ejected one after the other from the suction conveyor horizontally in the transport direction to a collecting station.

A method for separating blanks includes continuous conveying of a sheet metal strip in a transport direction to a laser cutting station, concurrent cutting of the sheet metal strip by at least one cutting laser, wherein a cut sheet metal strip is formed from successive sections of the same cutting geometry, transporting the cut sheet metal strip on a first conveyor belt in the transport direction, taking over the cut sheet metal strip from the first conveyor belt, transporting the cut sheet metal strip in the transport direction, separately ejecting the at least one residual blank of each section, transporting the at least one blank of each section into overlap with a second conveyor belt and ejecting the at least one blank from the suction conveyor, and transporting the blanks ejected one after the other from the suction conveyor horizontally in the transport direction to a collecting station.

A feed appliance for feeding products to a further processing appliance includes a standby circulatory apparatus with a takeover station and with several transport units that are circulatorily movable independently of one another for each receiving a product at the takeover station, a provision conveyor for feeding the products to the takeover station, and a control device for controlling the feed of the products and of the transport units into a takeover section of the takeover station and for controlling the takeover of the fed products by the transport units. The standby circulatory apparatus for creating a gapless product stream includes a release device for the cyclically controlled release of individual transport units into the takeover section. For this, the control device is designed to release a transport unit only given a feed of a cyclically correct product into the takeover section.

A feed appliance for feeding products to a further processing appliance includes a standby circulatory apparatus with a takeover station and with several transport units that are circulatorily movable independently of one another for each receiving a product at the takeover station, a provision conveyor for feeding the products to the takeover station, and a control device for controlling the feed of the products and of the transport units into a takeover section of the takeover station and for controlling the takeover of the fed products by the transport units. The standby circulatory apparatus for creating a gapless product stream includes a release device for the cyclically controlled release of individual transport units into the takeover section. For this, the control device is designed to release a transport unit only given a feed of a cyclically correct product into the takeover section.

A system has: a transport chain, which is roof-shaped in an upper region, along which printed products are transportable astride, collectable, and optionally stitchable in an intermediate stitching station; and a stop, which is adjustable in accordance with a format of a printed product of the printed products being delivered, is arranged in a transport direction of the printed products, and is positioned after the intermediate stitching station along the transport chain, the stop corresponding to a location of delivery of the printed product from the transport chain. A cyclic transfer of the printed product during the delivery takes place via a delivery system, the delivery system having in an infeed region a printed product transporter configured to transfer the printed product being delivered, the printed product transporter having pivot arms, the pivot arms being controllable according to a measured thickness of the printed product being delivered.

The present invention is directed to a method of loading workpieces using a piler conveyor P including a first conveyor which sequentially conveys the workpieces by continuous operation at a first speed, a second conveyor which magnetically attracts, on a lower surface, the workpieces passed from the first conveyor for sequential conveyance by intermittent operation, and a loading frame where the workpieces are placed, the method including a first step S1 of gradually accelerating the second conveyor to the second speed, a second step S2 of operating the second conveyor at the second speed and passing the workpieces 1 from the first conveyor to the second conveyor, a third step S3 of gradually decelerating the second conveyor from the second speed for operation, and a fourth step S4 of stopping the second conveyor and causing the second conveyor to lose a magnetic force and dropping a workpiece 1 positioned above the loading frame onto the loading frame 30, wherein the first speed and the second speed are set at an equal constant speed.