A Stacking Apparatus is proposed that performs the purpose of receiving the boxes being produced by a Rotary Die Cutter and transporting the boxes through the apparatus such that stacks of the boxes are created and exit from the discharge end of the apparatus. It embodies the four functional modules, Layboy Function, Shingling Function, Stacking Function and Hopper Function. These four functions are embodied such that it has the advantages of a fixed position Hopper Function and still provides Die Board Access, Running Layboy Roll Out and Sample Sheets.

A sheet manufacturing apparatus including a defibrating unit able to defibrate, in air, feedstock containing fiber; and a forming unit forming sheets, using at least part of defibrated material defibrated by the defibrating unit, by heating and pressurizing, and cutting; conveyance direction of the sheet in the forming unit being the short-side direction of the sheet.

Method for cutting media from a multi-roll printing system, comprising the steps of: selecting one of a first medium and a second medium, which first medium and second medium are output in parallel with respect to one another from the multi-roll printing system; transporting the selected medium to a cutting media transport path spaced apart from a further media transport path in a traverse direction perpendicular to a plane of the cutting media transport path; and cutting the selected medium positioned at the cutting media transport path.

The present invention further relates to a cutting assembly and a multi-roll printing system.

A printed unit block aligning device includes a supporting element and an alignment transfer rail. The supporting element is opened and closed between a supporting position and a releasing position. The alignment transfer rail receives the group of the printed unit blocks dropped in response to move of the supporting element to the releasing position, aligns the printed unit blocks in each line unit block in a vertical direction, and feeds the printed unit blocks vertically at a constant speed using alignment transferring element. An electrical controlling element is provided that electrically controls timing of dropping the printed unit blocks from the supporting element onto the alignment transfer rail. While a speed of transfer of the horizontal feeding and transferring element are uniform for any imposition structure, the electrical controlling element controls timing of dropping the printed unit blocks in a manner that depends on the numbers of layers in each vertical line in different imposition structures.

The invention relates to an apparatus, in particular a roll cross cutter, for forming a shingled stream of underlapping or overlapping sheets, in particular paper or cardboard sheets, comprising a transport device for transporting sheets, a shingling device for underlapping or overlapping of the sheets at least in some regions, a braking device following the shingling device in the transport direction of the sheets for braking of shingled sheets, in particular by the formation of a brake gap for the passage of sheets brought together in a shingled manner, and a cross-cutting device upstream of the shingling device for cutting a material strip into individual sheets. According to the invention, an intake section is provided between the shingling device and the braking device for intake and further transport of a sheet, trailing in the shingled stream, into the braking device.

A cardboard box dividing device includes lower conveyors on which a plurality of connected cardboard box bodies are stacked and transported; an upstream side positioning member and a downstream side positioning member movable along a transport direction and a thickness direction of each connected cardboard box body in upstream and downstream portions of the lower conveyors; a positioning drive device capable of independently moving the upstream side positioning member and the downstream side positioning member; a pressing device pressing, from above, the plurality of connected cardboard box bodies stacked on the lower conveyors; a cutting knife disposed along a width direction of the connected cardboard box body and dividing the plurality of connected cardboard box bodies stacked on the lower conveyors into a front part and a rear part; and a lifting/lowering device relatively moving the plurality of connected cardboard box bodies and the cutting knife along an up-down direction.

Processing units 4 to 6 aligned along the transport path for a sheet bundle S are accommodated in a housing together with transport units 2 and 3. Windows 10a to 10c are provided in the housing front face, and variable-color lighting units 17 are arranged inside the housing. Light emitting surfaces (projection plates 18) of the variable-color lighting units are arranged facing the windows. Sensor units 13, 15a, and 15b that detect an anomaly of an operation of the transport unit and sensor units 14 and 16 that detect an anomaly of the operation of respective processing units are provided. A binding processing unit stops when an anomaly is detected by the sensor unit, when a system error occurs, or when an emergency stop instruction is input. The color of emission light from a light emitting surface changes to indicate the operation status of the binding processing system.

A front end conveyor includes a frame having a first side and a second side, a lower deck and an upper deck. The lower deck includes a plurality of sheet supports, and upper portions of the sheet supports lie in a first plane. The upper deck includes a plurality of sheet guides that define with the sheet supports a sheet transport path through the front end conveyor. A chad wall extends transversely to the sheet transport direction and has a top edge located below the sheet transport path and a front surface facing in the upstream direction and a plurality of fingers projecting from the front surface in the upstream direction. The top edge of the chad wall is positioned relative to the sheet transport path such that hanging chads depending from the sheets will impact the chad wall.

A front end conveyor includes a frame having a first side and a second side, a lower deck and an upper deck. The lower deck includes a plurality of sheet supports, and upper portions of the sheet supports lie in a first plane. The upper deck includes a plurality of sheet guides, and the plurality of sheet supports and the plurality of sheet guides define therebetween a sheet transport path for moving sheets in a sheet transport direction toward the downstream end of the front end conveyor. A transverse scrap conveyor is mounted below the lower deck to carry scrap in a direction perpendicular to the sheet transport direction. The transverse scrap conveyor is secured to and supported by the frame such that the transverse scrap conveyor is movable with the frame as a unit.

A front end conveyor include a lower deck having a plurality of lower sheet supports, an upstream upper deck having an upstream end at the upstream end of the front end conveyor, a downstream end and a plurality of first upper sheet guides and a downstream upper deck having an upstream end, a downstream end at the downstream end of the front end conveyor, and a plurality of second upper sheet guides. The lower sheet supports and the upper sheet guides define a sheet transport path for moving sheets of material though the conveyor. The downstream end of the upstream upper deck and the upstream end of the downstream upper deck are independently pivotably mounted to the frame such that the upstream end of the upstream upper deck and the downstream end of the downstream upper deck shiftable toward and away from the lower deck.