A conveyor includes a frame, a carriage supported by the frame for sliding movement in a longitudinal direction, a lower conveyor deck supported by the frame and an upper deck. The lower deck has a plurality of contact elements, which may be wheels, for supporting sheets of material moving through the conveyor. The upper deck includes a rear portion having a plurality of longitudinally extending transversely spaced first belts each supported by a plurality of first pulleys and a front portion including a plurality of longitudinally extending transversely spaced second belts each supported a plurality of second pulleys. The plurality of second pulleys includes a first second pulley and a second second pulley that are supported by the carriage for movement with the carriage relative to the frame.

The cross-fold module for a folding machine comprises a cross-fold knife which is movable in a reciprocating manner in a folding-knife movement direction, and a pair of folding rollers which form a folding roller gap in which a sheet that previously was fed in the feeding direction is creased for folding by the cross-fold knife. A delivery transport device for the folded product receives the folded product in a receiving portion close to an outlet of the folding roller gap and transports the folded product to a delivery portion. At least the cross-fold knife and the pair of folding rollers are adjustable horizontally, perpendicular to the folding-knife movement direction and perpendicular to the feeding direction.

The invention relates to a device for feeding products in sheets into an insertion device before a digital printer, including a lifting system for a stack of laminar elements, which in turn includes an extraction mechanism for the last board, an insertion system with an advance mechanism, a rotation system for the stack(s), a positioning stop, connected to an advance and reverse mechanism, a squaring and scaling station, able to create a loading and accumulating hopper, and a telescopically-adjustable transportation system, with the capacity to move the previously-scaled sheets until the insertion device is fed.

A layboy conveyor includes a first end and a second end and an upper conveyor having a top and a bottom and a first end and a second end and a lower conveyor having a top and a bottom and a first end and a second end. The lower conveyor top is disposed adjacent to the upper conveyor bottom and defines with the upper conveyor bottom a transport path configured to transport a sheet of material in a direction from the first end of the layboy conveyor to the second end of the layboy conveyor. A drive is operably connected to the upper conveyor and to the lower conveyor, and the drive is configured to drive the upper conveyor bottom and the lower conveyor top in the direction. A length of the lower conveyor top is adjustable.

Disclosed herein are systems and devices which transport and stack flexible textile workpieces (e.g., clothing) in a processing line. A proposed stacking device includes a conveyor belt wound through a series of rollers which permit horizontal extension of the conveyor path toward a downstream workstation. The extendable conveyor path allows for easy transferring and stacking of the workpieces at the downstream workstation.

Described herein is a conveyor belt including: —a support structure; —a mobile belt; —a plurality of rollers, which are associated to the support structure and are suitable to support and move the belt along a closed path. Said plurality of rollers includes a drive roller and at least three idler rollers. Two rollers are supported directly by the support structure, while two rollers are supported by a mobile frame, which is slidingly associated to the support structure to be moved between a retracted position, in which a roller arranged at the second end is positioned completely inside said support structure, and an extracted position, in which said roller protrudes outside the support structure. In the transition between the two positions, the length of the useful conveyor area of the belt varies and is compensated by an equivalent variation in length of another portion of the closed path.

The present invention relates to a transfer module (26) for a folder-gluer machine (1), the transfer module comprising a lower conveyor (36) and an upper conveyor (38) adapted to receive a folding box (2) therebetween and to transport the folding box in a direction of transportation (D) towards a downstream-located loading surface (90) in a stacker module. The upper conveyor (36) of the transfer module extends further in the direction of transportation than the lower conveyor (38) and the lower conveyor comprises a first conveyor belt (38a) and second conveyor belt (38b), each having an inlet end (67a, 67b) and an outlet end (65a, 65b), and wherein the outlet ends are displaceable in the direction of transportation.

The cross-fold module for a folding machine comprises a cross-fold knife which is movable in a reciprocating manner in a folding-knife movement direction, and a pair of folding rollers which form a folding roller gap in which a sheet that previously was fed in the feeding direction is creased for folding by the cross-fold knife. A delivery transport device for the folded product receives the folded product in a receiving portion close to an outlet of the folding roller gap and transports the folded product to a delivery portion. At least the cross-fold knife and the pair of folding rollers are adjustable horizontally, perpendicular to the folding-knife movement direction and perpendicular to the feeding direction.

The present invention relates to a stacker module (28) for a folder-gluer machine (1). The stacker module comprises a loading surface (90) configured to receive a plurality of folding boxes and to descend vertically as the number of folding boxes on the loading surface increases, and a linearly movable ejector (76) configured to be moved from a retracted position (RP) to an extended position (DP).The stacker further comprises an upper guide (110), configured to move between a clearing position (CP) which is vertically distant from the upper surface of the stack, and a guiding position (GP), in which the upper guide is located closer to the upper surface of the stack, and wherein the upper guide is in the guiding position when the ejector is moved from the retracted position to the evacuation position.

A post compression carton rejection system for receiving cartons in-line from a carton assembly system having a compression conveying section for compressing folded and glued cartons for delivery to a packing system. The post compression carton rejection system comprise a frame adapted to be supported between the compression conveying section and the packing system. An infeed conveyor is mounted to the frame and has an infeed belt for transporting folded and glued cartons from the compression conveying section and an infeed drive for driving the infeed belt. An outfeed conveyor is mounted to the frame between the infeed conveyor and a conveyor exit proximate the packer, in use, and comprises a nose extension conveyor having an outfeed belt including a dump gate controllably retractable at the conveyor exit to selectively dump folded and glued cartons, an outfeed drive for driving the outfeed belt and a dump gate actuator for opening and returning the dump gate. A controller operatively controls the infeed drive, the outfeed drive and the dump gate actuator to selectively create gaps before and after a stream of defective folded and glued cartons and dump the defective folded and glued cartons at the dump gate.