Each of the sheets is conveyed by a horizontal conveyance unit in a state of being overlapped with a next sheet from above. Each of the sheets is conveyed out of the horizontal conveyance unit in a state of being folded along a fold line with the fold line oriented upward, the fold line extending in a conveyance direction of the horizontal conveyance unit. An oblique conveyance unit receives the sheet from the horizontal conveyance unit and successively conveys the sheets in an oblique downward direction. A sensor is arranged to detect passage of the sheets at a position where steps pass. Each of the steps is formed by two sheets adjacent to each other diverted to the oblique downward direction by the oblique conveyance unit.

Cutting equipment (41) which processes overlapped continuous forms (23H, 23L) is disclosed. The cutting is carried out by means of a cutting device (29), which separates the sheets from the forms, introduction devices (28H and 28L), which enter the continuous forms (23H, 23L) into the cutting device and a singularizing device (46) for overlapped sheets, which includes two transport paths (81 and 82), the one above the other, with differentiable transfer times; the singularizing device comprises a diverter (83) upstream of the transport paths (81 and 82); the introduction devices (28H and 28L) are actuatable for temporarily projecting a leading edge of one of the overlapped forms (23H, 23L) with respect to the other form up to a switching zone of the diverter (83), or for advancing together the overlapped forms (23H, 23L); the diverter (83) is configurable for addressing a continuous form or both forms (23H, 23L) to one or to both transport paths (81 and 82); and the introduction devices (28H and 28L) are also actuatable, in the case of projecting of one of the continuous forms, for lining up trailing edges of the sheets of the one and the other form for a joint cutting of the overlapped forms (23H, 23L) by means of the cutting device (29).

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.

Each of the sheets is conveyed by a horizontal conveyance unit in a state of being overlapped with a next sheet from above. Each of the sheets is conveyed out of the horizontal conveyance unit in a state of being folded along a fold line with the fold line oriented upward, the fold line extending in a conveyance direction of the horizontal conveyance unit. An oblique conveyance unit receives the sheet from the horizontal conveyance unit and successively conveys the sheets in an oblique downward direction. A sensor is arranged to detect passage of the sheets at a position where steps pass. Each of the steps is formed by two sheets adjacent to each other diverted to the oblique downward direction by the oblique conveyance unit.

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.

The module (3) comprises a frame having vertical pillars (30A, 30B), a rotary turnover structure (4) arranged horizontally between the vertical pillars and comprising rotation shafts (400A) supported by bearings (300A) with which the vertical pillars are respectively equipped. A motor (303B) applies a first mechanical torque to one of the rotation shafts when a folding package turnover is ordered in the machine. The module also comprises additional means (5) for applying a second mechanical torque to the other rotation shaft upon a folding package turnover.

The module (3) comprises a frame having vertical pillars (30A, 30B), a rotary turnover structure (4) arranged horizontally between the vertical pillars and comprising rotation shafts (400A) supported by bearings (300A) with which the vertical pillars are respectively equipped. A motor (303B) applies a first mechanical torque to one of the rotation shafts when a folding package turnover is ordered in the machine. The module also comprises additional means (5) for applying a second mechanical torque to the other rotation shaft upon a folding package turnover.

The conveyor comprises two single-transport-belt conveyor subassemblies (42AL, 42AH) arranged facing each other symmetrically relative to a pinching plane of the conveyor (42A), two sets of rollers (423L, 423H) incorporated in the two conveyor subassemblies and distributed on either side of the pinching plane. A first set of rollers (423L) guides a belt (420AL) of the first conveyor subassembly and a second set of rollers (423H) guides a belt (420AH) of the second conveyor subassembly. The conveyor subassemblies comprise sets of vertically arranged jacks (424L, 424H) which are associated with the sets of rollers, each of the rollers being mounted on a dedicated respective jack.

The conveyor comprises two single-transport-belt conveyor subassemblies (42AL, 42AH) arranged facing each other symmetrically relative to a pinching plane of the conveyor (42A), two sets of rollers (423L, 423H) incorporated in the two conveyor subassemblies and distributed on either side of the pinching plane. A first set of rollers (423L) guides a belt (420AL) of the first conveyor subassembly and a second set of rollers (423H) guides a belt (420AH) of the second conveyor subassembly. The conveyor subassemblies comprise sets of vertically arranged jacks (424L, 424H) which are associated with the sets of rollers, each of the rollers being mounted on a dedicated respective jack.

There is provided a recording system that can suppress a reduction in throughput when post-processing is performed in a post-processing apparatus.