WO2021233593A1 - Machine de traitement de feuille et procédé permettant de traiter des feuilles dans une machine de traitement de feuille - Google Patents

Machine de traitement de feuille et procédé permettant de traiter des feuilles dans une machine de traitement de feuille Download PDF

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Publication number
WO2021233593A1
WO2021233593A1 PCT/EP2021/057388 EP2021057388W WO2021233593A1 WO 2021233593 A1 WO2021233593 A1 WO 2021233593A1 EP 2021057388 W EP2021057388 W EP 2021057388W WO 2021233593 A1 WO2021233593 A1 WO 2021233593A1
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WO
WIPO (PCT)
Prior art keywords
sheet
stack
processing machine
unit
sheet processing
Prior art date
Application number
PCT/EP2021/057388
Other languages
German (de)
English (en)
Inventor
Erik Bormann
Johannes HELBIG
Original Assignee
Koenig & Bauer Ag
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Koenig & Bauer Ag filed Critical Koenig & Bauer Ag
Priority to EP21715801.3A priority Critical patent/EP4107104A1/fr
Publication of WO2021233593A1 publication Critical patent/WO2021233593A1/fr

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H31/00Pile receivers
    • B65H31/30Arrangements for removing completed piles
    • B65H31/3054Arrangements for removing completed piles by moving the surface supporting the lowermost article of the pile, e.g. by using belts or rollers
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D1/00Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor
    • B26D1/01Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work
    • B26D1/04Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member
    • B26D1/06Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates
    • B26D1/08Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D1/00Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor
    • B26D1/01Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work
    • B26D1/04Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member
    • B26D1/06Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates
    • B26D1/08Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type
    • B26D1/085Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type for thin material, e.g. for sheets, strips or the like
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D1/00Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor
    • B26D1/01Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work
    • B26D1/04Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member
    • B26D1/06Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates
    • B26D1/08Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type
    • B26D1/09Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type with a plurality of cutting members
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D11/00Combinations of several similar cutting apparatus
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D3/00Cutting work characterised by the nature of the cut made; Apparatus therefor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B26HAND CUTTING TOOLS; CUTTING; SEVERING
    • B26DCUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
    • B26D7/00Details of apparatus for cutting, cutting-out, stamping-out, punching, perforating, or severing by means other than cutting
    • B26D7/06Arrangements for feeding or delivering work of other than sheet, web, or filamentary form
    • B26D7/0675Arrangements for feeding or delivering work of other than sheet, web, or filamentary form specially adapted for piles of sheets
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H33/00Forming counted batches in delivery pile or stream of articles
    • B65H33/02Forming counted batches in delivery pile or stream of articles by moving a blade or like member into the pile
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H2301/00Handling processes for sheets or webs
    • B65H2301/40Type of handling process
    • B65H2301/42Piling, depiling, handling piles
    • B65H2301/422Handling piles, sets or stacks of articles
    • B65H2301/4228Dividing piles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H2301/00Handling processes for sheets or webs
    • B65H2301/40Type of handling process
    • B65H2301/42Piling, depiling, handling piles
    • B65H2301/422Handling piles, sets or stacks of articles
    • B65H2301/4229Handling piles, sets or stacks of articles cutting piles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H2402/00Constructional details of the handling apparatus
    • B65H2402/30Supports; Subassemblies; Mountings thereof
    • B65H2402/35Supports; Subassemblies; Mountings thereof rotating around an axis
    • B65H2402/351Turntables
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65HHANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
    • B65H2801/00Application field
    • B65H2801/42Die-cutting

Definitions

  • the invention relates to a sheet processing machine according to the preamble of claim 1 and a method for processing sheets in a sheet processing machine according to the preamble of claim 49.
  • the sheets are, for example, printed, embossed, grooved, perforated, punched, cut, stapled, glued and, for example, folded into packaging.
  • the sheets are, for example, printed, embossed, grooved, perforated, punched, cut, stapled, glued and, for example, folded into packaging.
  • several identical or different copies z. B. a poster, a folding box or packaging, printed on a common sheet and then punched. These copies are referred to as utility.
  • a sheet processing machine can include various processing steps such as printing, cutting, embossing, creasing, punching, perforating, gluing and / or stapling. Such sheet processing machines often also have inspection devices. Usually, sheets are processed and cut to size in processing machines with shaped punching and cutting devices.
  • Such a processing machine is designed, for example, as a punching, cutting, perforating, embossing and / or creasing machine.
  • a processing machine is referred to below as a punching and / or punching machine
  • a cutting, perforating, embossing and / or creasing machine is also meant in particular.
  • flat punches in addition to rotary punches, there are also flat punches, in particular flat-bed punches. These are cyclical through a repetitive movement processed several sheets one after the other.
  • the sheets are preferably moved largely horizontally through the processing machine with a transport system, preferably a chain gripper system.
  • a punching unit such a machine usually also has other units such.
  • the disadvantage of the technology is that it is limited in speed.
  • the speeds that can currently be achieved are around 10,000 sheets / hour.
  • the cause is physically justified and lies in the discontinuous movement process of the sheet to be punched.
  • the sheet is brought to a standstill in each unit of the flatbed die cutter and then has to be accelerated to working speed again for transport to the next unit.
  • These braking and acceleration processes stress the structure of the punched sheet and therefore do not allow higher processing speeds.
  • Rotary punching machines can, for example, be equipped with the modules punching unit, creasing unit, embossing unit and stripping unit.
  • Such a rotary punch is known, for example, from WO 2017/089420 A2.
  • DE 101 47486 A1 discloses a sheet-fed rotary printing machine in which a punching or cutting device is integrated.
  • the printing machine is assembled in a series design and comprises a sheet feeder, at least one printing unit, a punching or cutting device arranged downstream of the printing unit, and a sheet delivery.
  • the DE 19 70846 U teaches a cutting device for web-shaped material for cultivation a machine that processes web-shaped goods such as a printing machine.
  • the cutting device has two knife holders designed as cylindrical rollers with receiving devices for knives and counter knives. For example, web sections are generated from the web-shaped material.
  • the frame of the cutting device is pivotably supported on a traverse of the printing machine.
  • the sheet processing machine has a device for treating substrates, a display for forming stacks of treated substrates and a blanking unit.
  • the delivery for forming stacks of treated substrates is connected to the blanking unit via a transport path.
  • US 9 033646 B2 discloses a device for dividing a stack into two partial stacks in a sheet processing machine. After processing individual sheets, they are collected in a collecting station to form a stack. The stack is then divided into an upper and a lower partial stack by means of the dividing device. The individual partial stacks are fed to a bundler for bundling the batches.
  • DE 691 03 185 T2 discloses a machine for forming partial stacks starting from a main stack of sheets.
  • a stack separating device lifts the sheets of the partial stack to be formed from the main stack, whereupon the partial stack is deposited on a transport device designed as a belt.
  • the transport device has a fixed part and a displaceable part, the displaceable part being able to penetrate into the free space between the raised partial stack and the remaining main stack.
  • the invention is based on the object of creating a sheet processing machine and a method for processing sheets in a sheet processing machine.
  • the object is achieved according to the invention by the features of claim 1 and claim 49.
  • the dependent claims show advantageous developments and / or embodiments of the solution found.
  • a sheet processing machine advantageously comprises at least one shaping unit.
  • the at least one shaping unit advantageously has at least one forme cylinder and at least one impression cylinder.
  • at least one sheet delivery is advantageously arranged.
  • the advantages that can be achieved with the invention are in particular that at least one cutting unit with at least one cutting tool is arranged after the at least one sheet delivery in the transport direction.
  • the at least one cutting unit is advantageously arranged as part of the sheet processing machine, that is to say inline, after the at least one sheet delivery. This means that there is no need to interrupt the machining processes in order to transport sheets from the at least one sheet delivery to the at least one cutting unit, and the advantage of the high processing speed of the rotary punching machine can be retained.
  • the production speed of the sheet processing machine is advantageously at least 15,000 (fifteen thousand) and / or a maximum of 50,000 (fifty thousand), for example 20,000 (twenty thousand), sheets per hour.
  • At least one transfer transport system is advantageously arranged in particular between the at least one sheet delivery and the at least one cutting unit.
  • the production speed is additionally increased.
  • the at least one cutting tool is advantageously designed to carry out at least one cut orthogonal to the transport direction. Such cuts, which are arranged parallel to an axis of rotation of the forme cylinder, cannot be carried out in the at least one forming unit, since this requires great forces due to the rotation of the forme cylinder and the impression cylinder.
  • the production speed has been reduced in previous machining processes and / or the contours of use have been slightly turned in on a sheet to be machined, so that the cut to be carried out has an angle of unequal ninety degrees to the transport direction.
  • this results in a high number of leftover pieces with comparatively few benefits and thus a low utilization of the area of the at least one sheet.
  • These disadvantages can be eliminated by using the at least one cutting unit which carries out at least one cut orthogonally to the transport direction.
  • a high production speed is guaranteed in comparison to previous processing processes and / or a higher area utilization is achieved in the arrangement of panels on the at least one sheet. Waste in the form of unused remnants of the sheet is minimized.
  • the at least one transfer transport system advantageously has at least one handling device.
  • the at least one handling device is advantageously designed to generate at least a partial stack of sheets starting from at least one stack of sheets.
  • the at least one handling device is advantageously designed to generate at least a partial stack of the sheets.
  • the at least one handling device is advantageously designed to form the at least one partial stack starting from at least one stack of the sheets.
  • the at least one handling device is advantageously designed to separate the at least one partial stack from the at least one stack of sheets.
  • the at least one transfer transport system advantageously transports the sheets to the unit processing at least one further sheet by means of at least one cycle conveyor.
  • a simple and quick dismantling of the at least one is advantageous Stacks in partial stacks in the at least one handling device.
  • the stack is advantageously divided automatically within the processing machine, in particular within the transfer transport system.
  • the speed of the transport and / or the division of the stack in the at least one handling device is advantageously adapted to the processing speed of the sheets in the individual units of the processing machine, thereby ensuring optimum machine utilization.
  • a production line for processing sheet-like substrates, preferably for producing folding box die-cut products, is advantageously created.
  • a mechanical separation process for separating individual copies of a sheet from one another is advantageously attached to and combined with a, preferably rotary, punching process, for example alternatively to a flat-bed punching process.
  • the rotary stamping process advantageously achieves high processing speeds of at least 15,000 (fifteen thousand) and / or a maximum of 50,000 (fifty thousand), for example 20,000 (twenty thousand), sheets per hour.
  • the high processing speed preferably has a continuous material flow, in which the acceleration and braking forces acting on the sheet are low, in particular in comparison to a flat-bed punching machine.
  • the production speed of the sheet processing machine is advantageously at least 15,000 (fifteen thousand) and / or a maximum of 50,000 (fifty thousand), for example 20,000 (twenty thousand), sheets per hour.
  • a sheet processing machine can advantageously be used for the blank separation of several punches upstream of the blank separation, preferably at least one rotary die cutter and / or, for example, at least one flat bed die cutter.
  • the chaining of the units by the at least one transfer transport system advantageously minimizes the personnel expenditure. Furthermore, there is advantageously an optimal use of space due to the linking of the units to one another by the at least one transfer transport system.
  • the required area of the sheet processing machine can be reduced in comparison to a processing machine with a downstream punching machine that is separate therefrom, for example a flat bed punching machine.
  • the at least one transfer transport system and in particular the at least one further unit processing the sheets, for example the blanking unit can advantageously be integrated into existing further processing machines, preferably optimally in their workflow, for example instead of existing blanking areas.
  • At least one remnant piece can advantageously remain in the at least one sheet during the punching process by the at least one shaping unit.
  • the at least one arch which has at least one web as a remainder, advantageously requires no cut, in particular no intermediate cuts, of the at least one shaping unit for this web.
  • An intermediate cut is a cut between a panel and a remnant piece adjacent to it, for example a web.
  • the separation takes place advantageously in the at least one further unit processing the sheets. This can advantageously result in a high Production output can be achieved with very high quality sheets.
  • the at least one stack can be easily and quickly broken down into partial stacks in the at least one handling device in an advantageous manner.
  • the stack is advantageously divided automatically within the processing machine, in particular within the transfer transport system.
  • the speed of transport and / or the division of the stack in the at least one handling device is advantageously adapted to the processing speed of the sheets in the individual units of the processing machine, thereby ensuring optimum machine utilization.
  • FIG. 1 shows a side view of the processing machine in a preferred embodiment
  • FIG. 2 shows an overview of the processing machine in a preferred embodiment in a top view
  • FIG. 3 shows an exemplary sheet with two copies and remnants, the two copies being separated from one another by a web
  • 4 shows a further exemplary sheet with two copies and remnants, the two copies being arranged directly next to one another and connected;
  • 5 shows a schematic representation of a stack of sheets comprising a plurality of partial stacks;
  • FIG. 6 shows a schematic illustration of a stack of copies comprising a plurality of stacks of partial copies, each of which is separated from one another by an intermediate sheet, for example;
  • FIG. 8 shows a schematic representation of a stack of copies in the copy display with an intermediate sheet
  • FIG. 10 shows an exemplary representation of part of the sheet processing machine starting with the at least one handling device up to the at least one panel display in a plan view;
  • FIG. 11 shows a representation of the part of the sheet processing machine from FIG. 10 in a side view
  • FIG. 12 shows an exemplary illustration of the at least one handling device and the at least one transfer means, the at least one conveying means not being shown;
  • FIG. 13 shows a schematic representation of an exemplary cutting unit
  • FIG. 14 shows a perspective illustration of the cutting unit from FIG. 13 from the side Opinion.
  • a processing machine 01 is preferably designed as a sheet processing machine 01, in particular as a punching machine 01, more preferably as a rotary punching machine 01, for processing at least one, preferably at least two, more preferably a plurality of, arcuate substrates 02 or sheets 02.
  • Sheet processing machine 01 also means, in particular, a punching machine 01.
  • the processing machine 01 has at least one unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400, preferably a plurality of units 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 on.
  • the processing machine 01 in particular the sheet processing machine 01, preferably comprises at least one, preferably at least two, more preferably at least three, more preferably at least four, as the shaping unit 300; 400; 500; 600 trained unit 300; 400; 500; 600 for processing sheets 02, for example at least one first shaping unit 300 and / or at least one second shaping unit 400 and / or at least one third shaping unit 500 and / or at least one fourth shaping unit 600.
  • an assembly 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 is preferably to be understood in each case as a group of devices which functionally interact, in particular in order to be able to carry out a preferably self-contained processing operation of the at least one substrate 02.
  • an assembly 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 each have a machine section of the processing machine 01, which is preferably arranged at least partially spatially separable from further machine sections.
  • the term substrate 02 in particular of the arch-shaped substrate 02, specifically of the sheet 02, basically any flat substrate 02 that is present in sections, that is to say also of the substrate 02 that is present in tabular or plate-shaped form, that is to say also boards or plates.
  • the arched substrate 02 or sheet 02 defined in this way is formed, for example, from cardboard and / or corrugated cardboard, ie cardboard sheets and / or corrugated cardboard sheets, or by sheets, panels or, if appropriate, sheets of plastic, cardboard, glass, wood or metal. More preferably, the sheet-shaped substrate 02 is paper and / or cardboard, in particular a sheet of paper and / or a sheet of cardboard.
  • sheet 02 denotes both sheets 02 which have not yet been used by means of at least one unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 were processed, as well as those sheets 02 that have already been processed by means of at least one unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 were edited and possibly changed in their shape and / or their mass.
  • paper is a flat material consisting essentially of fibers, mostly of vegetable origin, which is formed by dewatering a fiber suspension on a sieve. This creates a fiber felt that is then dried.
  • the weight per unit area of paper is preferably a maximum of 225 g / m 2 (two hundred and twenty-five grams per square meter).
  • cardboard is a flat material consisting essentially of fibers of vegetable origin, which is formed by dewatering a fiber suspension on one or between two sieves. The fiber structure is compressed and dried.
  • Cardboard is preferably manufactured from cellulose by gluing or pressing it together. Cardboard is preferably designed as solid cardboard or corrugated cardboard.
  • the basis weight of paperboard is in excess of 225 g / m 2 (two hundred and twenty five grams per square meter).
  • Corrugated cardboard is cardboard made of one or more layers of a corrugated paper, which is on one layer or between several layers of another preferably smooth paper or Cardboard is glued.
  • the term cardboard refers to a sheet of paper, preferably coated on one side, with a mass per unit area of at least 150 g / m 2 (one hundred and fifty grams per square meter) and a maximum of 600 g / m 2 (six hundred grams per square meter).
  • a cardboard box preferably has a high strength relative to paper.
  • a sheet 02 to be processed preferably the at least one sheet 02, preferably has a weight per unit area of at least 60 g / m 2 (sixty grams per square meter) and / or of a maximum of 700 g / m 2 (seven hundred grams per square meter), preferably a maximum of 500 g / m 2 (five hundred grams per square meter), more preferably a maximum of 200 g / m 2 (two hundred grams per square meter).
  • a sheet 02 to be processed preferably the at least one sheet 02, preferably has a thickness of a maximum of 1.5 cm (one point five centimeters), preferably a maximum of 1.0 cm (one point zero centimeter), more preferably a maximum of 0.6 cm (zero point six centimeters).
  • the at least one sheet 02 has a thickness of at least 0.01 cm (zero point zero one centimeter), preferably of at least 0.03 cm (zero point zero three centimeters).
  • the at least one substrate 02 in particular the at least one sheet 02, preferably has a sheet width, preferably parallel to a transverse direction A, of at least 200 mm (two hundred millimeters), preferably at least 300 mm (three hundred millimeters), more preferably at least 400 mm (four hundred millimeters) Millimeters).
  • the sheet width is preferably a maximum of 1,500 mm (one thousand five hundred millimeters), more preferably a maximum of 1,300 mm (one thousand three hundred millimeters), even more preferably a maximum of 1,060 mm (one thousand and sixty millimeters).
  • An arc length preferably parallel to a transport direction T, is, for example, at least 150 mm (one hundred and fifty millimeters), preferably at least 250 mm (two hundred and fifty millimeters), more preferably at least 350 mm (three hundred and fifty millimeters). Furthermore, an arc length is, for example, a maximum of 1,200 mm (one thousand two hundred millimeters), preferably a maximum of 1,000 mm (thousand millimeters), more preferably a maximum of 800 mm (eight hundred millimeters).
  • benefit 03 preferably denotes the number of identical and / or different objects that are manufactured from the same piece of material and / or are arranged on a common carrier material, for example a common sheet 02.
  • a benefit 03 is preferably that area of a sheet 02 which is designed as a product of the sheet processing machine 01, in particular as an intermediate product for the production of an end product, and / or, for example, is further processed into a desired or required end product and / or is designed to be further processable.
  • the desired or required end product which is preferably produced by further processing the respective utility 03, is preferred here, a packaging, in particular a folding box, or a label and / or a label, in particular a label and / or a label of a packaging.
  • the at least one sheet 02 preferably has at least one copy 03, preferably at least two copies 03, more preferably at least four copies 03, more preferably at least eight copies 03, for example twelve copies 03.
  • the at least two panels 03 of the at least one sheet 02 are each connected to one another and / or to the respective adjacent panel 03 by at least one stopping point, preferably by at least two stopping points, more preferably by at least four stopping points.
  • a remnant 04; 05; In the preceding and in the following, 06 is that area of a sheet 02 which does not correspond to any use 03. Collected remnants 04; 05; 06 are preferably referred to as waste.
  • a remnant 04; 05; 06 is preferably designed as a trim and / or breakout and / or can be removed.
  • the at least one remaining piece 04; 05; 06 generated in at least one shaping unit 300, preferably by at least one processing step of the respective sheet 02, for example in at least one punching process.
  • the at least one remnant piece 04; 05; 06 at least partially removed from the respective sheet 02 and thus in particular separated from the respective benefits 03 of the sheet 02.
  • At least one fourth shaping unit 600 designed as a stripping unit is designed to remove at least one first residual piece 04, in particular at least one waste piece 04, and / or designed to remove at least one waste piece 04.
  • At least one unit 1200 designed as a blanking unit 1200 is preferably designed to remove at least one second remnant piece 06, in particular at least one gripper edge 06, and / or designed to remove at least one gripper edge 06.
  • a sheet 02 comprises a remnant piece 05 designed as a web 05.
  • the at least one web 05 separates the panels 03 from one another.
  • the at least one blanking unit 1200 is preferably the at least one remnant piece 05; 06, in particular the at least one web 05 and / or the at least one gripper edge 06, designed to be removed.
  • the at least one substrate 02 in particular the at least one sheet 02, has several edges 07; 08; 09 on.
  • an edge 07 designed as a front edge 07 is oriented in the transport direction T on the sheet 02 at the front and is arranged orthogonally to the transport direction T.
  • the front edge 07 is that edge 07 of the at least one sheet 02 that can be grasped for the transport of the at least one sheet 02 preferably by at least one component of the sheet processing machine 01, in particular by at least one transport means of at least one transport system, and / or on which at least one component the
  • Sheet processing machine 01 in particular by the at least one transport means of the at least one transport system that holds at least one sheet 02.
  • An edge 08 formed as a rear edge 08 of the at least one sheet 02 is preferably arranged opposite the front edge 07. More preferably, the front edge 07 and the rear edge 08 are arranged parallel to one another. In particular, the rear edge 08 is oriented at the rear in the transport direction T on the at least one sheet 02 and is orthogonal arranged to the transport direction T.
  • the sheet 02 further comprises two edges 09 designed as side edges 09. The two side edges 09 are preferably arranged parallel to the transport direction T. The two side edges 09 are preferably each arranged orthogonally to the front edge 07 and / or to the rear edge 08 of the sheet 02.
  • the at least one sheet 02 preferably has at least one print image.
  • the print image describes above and below a representation on the at least one sheet 02, which corresponds to the sum of all image elements, the image elements during at least one work stage and / or at least one printing process on the sheet 02, for example before or during processing by the Sheet processing machine 01, have been transferred and / or are transferable.
  • the surface of the at least one sheet 02 preferably has at least one unprinted area, in particular unprinted edge area, which is preferably designed as the at least one remnant piece 06 and / or the at least one gripper edge 06.
  • the at least one sheet 02 has the at least one gripper edge 06 on its front edge 07 or on its rear edge 08.
  • the at least one sheet 02 preferably has the at least one gripper edge 06 both on its front edge 07 and on its rear edge 08.
  • the sheet 02 preferably has at least one printing mark 11, preferably at least two printing marks 11.
  • a printing mark 11 is a mark, for example, for checking a register and / or a register and / or preferably for aligning the at least one sheet 02 in the transport direction T and / or in the transverse direction A.
  • At least one stack 12 of sheets 02 preferably has a plurality of sheets 02, in particular the at least one sheet 02 and, in addition, a plurality of further sheets 02.
  • the at least one stack 12 preferably has at least 1,000 (one thousand) sheets 02, preferably at least 2,000 (two thousand) sheets 02, and additionally or alternatively, preferably a maximum of 15,000 (fifteen thousand) sheets 02, further preferably a maximum of 10,000 (ten thousand) sheets 02 , more preferably a maximum of 8,000 (eight thousand) sheets 02.
  • the at least one stack 12 has a height of at least 100 mm (one hundred millimeters), preferably of at least 200 mm (two hundred millimeters), more preferably of at least 300 mm (three hundred millimeters) and additionally or alternatively of a maximum of 3,000 mm (three thousand millimeters) , preferably of a maximum of 2,500 mm (two thousand five hundred millimeters), more preferably of a maximum of 2,000 mm (two thousand millimeters), more preferably of a maximum of 1,600 mm (one thousand six hundred millimeters), more preferably of a maximum of 1,300 mm (one thousand three hundred millimeters).
  • the at least one stack 12 preferably comprises at least two partial stacks 13 of sheets 02, preferably at least four partial stacks 13, more preferably at least eight partial stacks 13.
  • a ream 13 can be understood to mean a packing unit of flat paper of the same type, that is, non-folded, non-rolled paper in sheets or sheets 02.
  • the ream 13 preferably comprises at least 50 (fifty) sheets 02, more preferably at least 200 (two hundred) sheets 02, more preferably at least 400 (four hundred) sheets 02, and additionally or alternatively preferably a maximum of 700 (seven hundred) sheets 02, more preferably a maximum of 600 (six hundred) sheets 02, more preferably a maximum of 500 (five hundred) sheets 02.
  • the at least one partial stack 13 preferably has a height of at least 5 mm (five millimeters), preferably of at least 10 mm (ten millimeters), and additionally or alternatively a height of a maximum of 400 mm (four hundred millimeters), preferably of a maximum of 300 mm (three hundred Millimeters), more preferably of a maximum of 200 mm (two hundred millimeters).
  • the at least one partial stack 13 preferably has the at least one unit 1200; 1500, preferably by the at least one blanking unit 1200 and / or by the at least one cutting unit 1500, on sheets 02 to be processed.
  • a stack of copies 14 and / or delivery stack 14 preferably comprises a number of copies 03, which corresponds to the number of sheets 02 of a stack 12.
  • the at least one stack of copies 14 preferably has a maximum height of 2,000 mm (two thousand millimeters), more preferably a maximum of 1,600 mm (one thousand six hundred millimeters), more preferably a maximum of 1,300 mm (one thousand three hundred millimeters).
  • a partial copy stack 16 preferably comprises a number of copies 03, which corresponds to the number of sheets 02 of a partial stack 13.
  • a machine direction B is preferably a direction B, which points from a first unit 100 of the processing machine 01 to a last unit 700 and / or 1400 of the processing machine 01.
  • the machine direction B points from an assembly 100, in particular a first assembly 100 configured as a feeder assembly 100, to a last assembly 700, in particular an assembly 700 configured as a sheet delivery 700, and / or to a last assembly 1400, in particular a delivery assembly or Unit 1400 configured with a utility display 1400.
  • the machine direction B is preferably a horizontally running direction B.
  • the transverse direction A is preferably a horizontally running direction A.
  • the transverse direction A is oriented orthogonally to the machine direction B.
  • the transverse direction A is preferably oriented from an operator side of the processing machine 01 to a drive side of the processing machine 01.
  • a vertical direction V is preferably that direction V which is arranged orthogonally to a plane spanned by the machine direction B and the transverse direction A.
  • the vertical direction V is preferably perpendicular from below and / or from a floor of the processing machine 01 and / or from a lowermost component of the processing machine 01 upwards and / or to an uppermost component of the processing machine 01 and / or to an uppermost cover of the processing machine 01 oriented.
  • the operator side of the processing machine 01 is preferably that side of the processing machine 01 parallel to the machine direction B from which an operator has at least partial and at least temporary access to the individual units 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 of the processing machine 01 is possible, for example during maintenance work and / or changing at least one shaping tool.
  • the drive side of the processing machine 01 is preferably that side of the processing machine 01 parallel to the machine direction B which is opposite the operator's side.
  • the drive side preferably has at least parts, preferably at least a large part, of a drive system.
  • an operator has at least temporary access to the individual units 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 adjusted and / or installed on the drive side by at least one component of the processing machine 01.
  • the spatial area provided for the transport of the at least one substrate 02 within the processing machine 01, which the substrate 02 at least temporarily occupies when it is present, is the transport path.
  • the transport direction T is preferably a direction T in which the at least one substrate 02 is transported if it is present at any point on the transport path.
  • the transport direction T preferably points in the direction T, in which the at least one substrate 02 apart from vertical movements or vertical components of movements.
  • the direction of transport T within an assembly 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 in the direction T which from a first contact of the at least one substrate 02 with this unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 for a final contact of the substrate 02 with this unit 100; 200; 300; 400; 500; 600;
  • the working width is the maximum width which the at least one substrate 02 may have in order to be able to pass through the at least one unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400, in particular the respective units 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400 to be able to be transported to the processing machine 01 and / or to still be able to use the at least one shaping unit 300; 400; 500; 600 of the processing machine 01 can be processed.
  • This therefore corresponds to the maximum with the at least one shaping unit 300; 400; 500; 600 of the processing machine 01 processable width of the at least one substrate 02.
  • the working width of the processing machine 01 is preferably at least 30 cm (thirty centimeters), more preferably at least 50 cm (fifty centimeters), even more preferably at least 80 cm (eighty centimeters) Centimeters), even more preferably at least 120 cm (one hundred and twenty centimeters) and even more preferably at least 150 cm (one hundred and fifty centimeters).
  • the processing machine 01 preferably comprises at least one unit 100 configured as a feeder unit 100.
  • the feeder unit 100 is preferably configured as a feeder, more preferably as a sheet feeder, more preferably as a sheet feeder unit.
  • the feeder unit 100 is preferably designed as the first unit 100 of the processing machine 01 in the transport direction T.
  • the feeder unit 100 is preferably the at least one sheet 02 on the transport path of the processing machine 01 designed to feed and / or the at least one sheet 02 to at least one unit 200 downstream of the feeder unit 100 in the transport direction T; 300; 400;
  • At least one unit 200 designed as a contact unit 200 is preferably arranged.
  • the at least one contact unit 200 is preferably the at least one sheet 02, preferably the at least two sheets 02, more preferably a plurality of sheets 02, preferably sequential to the at least one shaping unit 300; 400; 500; 600 trained feeding.
  • the at least one contact unit 200 preferably has at least one device for detecting the at least one sheet 02.
  • the at least one sheet 02 can be aligned at least partially, preferably completely, by the at least one contact unit 200 with regard to its position in the transport direction T and / or in the transverse direction A.
  • the processing machine 01 preferably has at least one, preferably at least two, more preferably at least three, more preferably at least four, for example exactly four, each as a shaping unit 300; 400; 500; 600 trained unit 300; 400; 500; 600 on.
  • In the transport direction T after the at least one feed unit 100 and preferably additionally after the at least one contact unit 200 is preferably the at least one, preferably at least two, more preferably at least three, more preferably at least four, for example exactly four, each as a shaping unit 300; 400; 500; 600 trained unit 300; 400; 500; 600 arranged.
  • the at least one shaping unit 300; 400; 500; 600 at least one shaping unit, preferably exactly one Form imaginationswerk, on.
  • the at least one shaping unit is preferably designed as at least one embossing unit and / or at least one scoring unit and / or at least one punching unit, more preferably as a rotary punching unit, and / or at least one stripping unit.
  • at least one of the shaping units 300; 400; 500; 600 at least one shaping unit, preferably at least one embossing unit and / or at least one creasing unit and / or at least one punching unit and / or at least one stripping unit.
  • the corresponding unit 300; 400; 500; 600 is then preferably designed as a punching unit and / or creasing unit and / or embossing unit and / or stripping unit.
  • the at least one shaping unit 300; 400; 500; 600 is preferably designed as a punching unit and / or creasing unit and / or embossing unit and / or stripping unit.
  • the at least one shaping unit 300 is preferred; 400; 500; 600 formed punching and / or cutting and / or perforating and / or scoring and / or stamping and / or creasing the at least one sheet 02.
  • the at least one shaping unit 300; 400; 500; 600 designed to remove at least one remnant piece 04 designed as a scrap piece 04 from the at least one sheet 02.
  • the at least one shaping unit 300; 400; 500; 600 preferably the at least one shaping unit of the shaping unit 300; 400; 500; 600, at least one, preferably a forme cylinder, and at least one impression cylinder.
  • the at least one forme cylinder and / or the at least one impression cylinder is preferably designed as a magnetic cylinder and / or has at least one elevator, preferably particularly in the case of the forme cylinder, at least one elevator with at least one tool.
  • the at least one forme cylinder and the at least one impression cylinder are preferably designed to form at least one, preferably exactly one, shaping point with one another.
  • the shaping point is preferably that area in which the at least one forme cylinder on the one hand and the at least one impression cylinder on the other hand are closest.
  • the at least one shaping unit 300; 400; 500; 600, preferably the at least one shaping unit, more preferably the at least one forme cylinder, preferably has at least one tool on.
  • the at least one tool is preferably arranged in the region of the shaping point in direct contact with the impression cylinder, for example designed to be in contact with it at least in the case of the absence of the at least one sheet 02.
  • the at least one sheet 02 which is formed by the at least one shaping unit 300; 400; 500; 600 is processed, that is to say which on the transport path in the transport direction T after the at least one shaping unit 300; 400; 500; 600 is arranged, preferably has at least one punched impression.
  • the at least one punched impression is designed, for example, as a groove and / or groove and / or embossing and / or cut and / or perforation and / or crack and / or as a broken-off scrap piece 04.
  • the at least one punch impression is preferred, in particular if it is designed as a perforation and / or cut, at least partially the at least one benefit 03 from the at least one remnant piece 04; 05; 06 and / or designed to be separating from the at least one further up 03 of the at least one sheet 02.
  • the at least one sheet 02 which is formed by the at least one shaping unit 300; 400; 500; 600 is processed, that is to say which on the transport path in the transport direction T after the at least one shaping unit 300; 400; 500; 600 is arranged, the at least one use 03, preferably at least two use 03, more preferably at least four use 03; more preferably at least eight copies 03, and at least one remnant 04; 05; 06 on.
  • At least one unit 700 designed as a delivery unit 700 is arranged.
  • the delivery unit 700 has at least one chain conveyor system, for example with gripper bridges.
  • the at least one delivery unit 700 is designed as a sheet delivery 700.
  • Preferred the at least one sheet delivery 700 is designed to deposit the at least one sheet 02 on at least one stacking support 17, for example at least one as a pallet 17 or as a conveyor belt or a different type of stacking support 17.
  • the at least one sheet delivery 700 is preferably designed to form at least one stack 12 of sheets 02 or at least a partial stack 13 of sheets 02, preferably on the at least one stacking support 17.
  • the stack 12 or the partial stack 13 preferably comprises the at least one sheet 02 and further, preferably a plurality of, sheets 02.
  • the transport direction T after the at least one sheet delivery 700 there is preferably at least one transport system 800; 900; 1000, preferably as a transfer transport system 800; 900; 1000, trained unit 800; 900; 1000 arranged.
  • the at least one transfer transport system 800 is preferred; 900; 1000 the at least one sheet 02 and preferably additionally further sheets 02, preferably the at least one stack 12 or the at least one partial stack 13, from the at least one sheet delivery 700 to the at least one unit 1100 downstream in the transport direction T; 1200; 1400 trained to transport.
  • the at least one stack 12 and / or the at least one partial stack 13 is preferably transported by the transfer transport system 800; 900; 1000 transportable.
  • At least one unit 1100 embodied as an intermediate alignment 1100.
  • the at least one intermediate alignment 1100 is preferably designed to align and / or loosen the at least one partial stack 13, which preferably comprises the at least one sheet 02 and further sheets 02.
  • the at least one intermediate alignment 1100 for this purpose has at least one stop, preferably at least two stops, against which the at least one partial stack 13 is aligned.
  • the panels 03 are removed from the remnants 04; 05; 06, preferably the remaining pieces 05; 06, separated.
  • the remaining pieces 04 are preferably separated; 05; 06 of the benefits 03 in partial stacks and / or in huge quantities.
  • the benefit 03 and / or remnants 04; 05; 06 in particular depending on the size of the remnants 04; 05; 06, remnants 04; 05; 06, which is usually in an upstream shaping unit 300; 400; 500; 600, in particular the stripping unit, can be removed by removing at least one blanking unit 1200.
  • the at least one blanking unit 1200 preferably has at least one blanking unit 1201 and at least one conveyor belt 1202.
  • the at least one blank separator 1201 generates and / or effects a shearing movement with a shear force in the separating process between the panels 03, in particular the partial panel stack 16, which is designed as panel partial stacks 16, and the remaining pieces 04; 05; 06, in particular the stacks of leftover pieces 04; 05; 06.
  • the remaining pieces 04; 05; 06 is transported away from the at least one blanking unit 1200 after the separation process and, for example, passed into a waste container 51 and / or into a shredding device 51.
  • the at least one further unit 1200; 1500 preferably downstream of the at least one blanking unit 1200 and / or the at least one cutting unit 1500, at least one delivery unit 1400, preferably designed as a panel display 1400. That is at least preferred a blanking unit 1200 followed by at least one delivery unit 1400.
  • at least one, preferably at least two, more preferably at least four, more preferably at least eight, panel part stack 16 is transported by means of at least one transport means 1401, for example at least one rake 1401, from the panel separation unit 1200 into the at least one delivery unit 1400.
  • the at least one, preferably at least two, more preferably at least four, more preferably at least eight, panel part stacks 16 are collected on at least one stacking base 17, preferably at least one pallet 17, and / or to at least one panel stack 14 and / or display stack 14 stacked.
  • a utility stack 14 comprises at least two, more preferably at least four, more preferably at least eight, utility sub-stacks 16.
  • a sheet 02 is preferably inserted as an intermediate sheet 02 between each panel part stack 16 to increase stability.
  • the at least one shaping unit is preferably at least one shaping unit 300; 400; 500; 600 of the shaping units 300; 400; 500; 600 designed as an embossing unit.
  • the at least one embossing unit is preferably designed to produce at least one relief embossing and / or at least one Braille embossing on the at least one sheet 02.
  • the at least one relief embossing is preferably either raised or lowered in relation to its surroundings of the surface of the sheet 02.
  • the at least one forme cylinder is designed to produce at least one raised and at least one recessed relief embossing.
  • different relief embossings produced by the at least one embossing mechanism in the surface of the at least one sheet 02 have different heights.
  • the at least one shaping unit is at least one shaping unit 300; 400; 500; 600 of the shaping units 300; 400; 500; 600 designed as a scoring unit.
  • the shaping mechanism which is designed as a grooving mechanism, is preferably designed to grooved the at least one sheet 02.
  • the scoring unit is also designed to punch and / or score and / or perforate and / or emboss the at least one sheet 02.
  • the at least one creasing unit is preferably designed to produce at least one fold, for example for at least one fold.
  • the at least one shaping unit is at least one shaping unit 300; 400; 500; 600 of the shaping units 300; 400; 500; 600 designed as a punching unit.
  • the shaping mechanism embodied as a punching unit is preferably embodied as punching and / or perforating and / or scoring the at least one sheet 02.
  • the at least one shaping unit is at least one shaping unit 300; 400; 500; 600 of the shaping units 300; 400; 500; 600 designed as a punching mechanism with at least one suction device, preferably hole suction device.
  • the shaping work designed as a punching work with at least one suction device is designed to punch and / or perforate and / or score the at least one sheet 02, with at least one scrap piece 04 being removed from the at least one sheet 02 at the same time.
  • the at least one scrap piece 04 is preferably completely separated from the at least one sheet 02 by processing in the at least one shaping unit and held on the forme cylinder with air, preferably suction air, and blown into at least one suction box of the shaping unit.
  • waste pieces 04 which cannot be removed by further processing steps and / or for example with a maximum area of 0.25 cm 2 (zero point two five square centimeters), can be removed from the at least one sheet 02.
  • the processing machine 01 preferably has at least one shaping unit 300 with at least one punching unit with at least one suction.
  • the at least one shaping unit is at least one shaping unit 300; 400; 500; 600 of the shaping units 300; 400; 500; 600 designed as a stripping mechanism.
  • the shaping unit designed as a stripping mechanism is at least one waste piece 04, preferably at least two waste pieces 04, more preferably at least four waste pieces 04, more preferably a plurality of waste pieces 04, from which at least one sheet 02 is removed, preferably broken out and / or sucked off.
  • the processing machine 01 preferably has at least two, preferably at least three, for example two or three or four, shaping units 300; 400; 500; 600 on.
  • the at least two shaping units 300; 400; 500; 600 one after the other along the transport path, preferably without further units 100; 200; 700; 800; 900; 1000; 1100; 1200; 1400; 1500 other function in between.
  • the at least two shaping units 300 which are preferably arranged one after the other, preferably differ. 400; 500; 600 from each other with regard to their shaping mechanisms.
  • the processing machine 01 has at least one shaping unit 400 with at least one punching unit and, for example, additionally a shaping unit 300 upstream of this shaping unit 400 with at least one punching unit with at least one, particularly in the case of the generation of at least one label, for example at least one label of a plastic packaging Suction on.
  • the shaping unit 400 with the at least one punching unit that is to say in particular without a further shaping unit 300; 400; 500; 600 arranged in between, the at least one sheet delivery 700.
  • the processing machine 01 has at least one shaping unit 400 with at least one punching unit and, for example, additionally a shaping unit 300 upstream of this shaping unit 400 with at least one punching unit with at least one, especially in the case of generating at least one further label, for example at least one label made of paper Suction on.
  • at least one shaping unit 300 with at least one scoring unit or with at least one embossing unit is upstream of the at least one shaping unit 400 with the at least one punching unit.
  • the shaping unit 400 with the at least one punching unit that is to say in particular without a further shaping unit 300; 400; 500; 600 arranged in between, the at least one sheet delivery 700.
  • the processing machine 01 has at least three shaping units 300; 400; 500; 600 on.
  • the first shaping unit 300 preferably has at least one embossing unit or scoring unit. If the embossing unit is present in the first shaping unit 300, it is preferably arranged in front of the second shaping unit 400 having the scoring unit.
  • the at least one shaping unit 300; 400 for example the first or second shaping unit 300; 400, followed preferably by a shaping unit 400; 500 with at least one punching unit.
  • the third or fourth shaping unit 500; 600 at least one stripping mechanism.
  • the shaping unit 500 is preferred; 600 with the at least one stripping mechanism directly following the shaping unit 400; 500 arranged with the at least one punching unit, in particular without a further shaping unit 300; 400; 500; 600 in between.
  • the at least one sheet delivery 700 is arranged.
  • the at least one sheet delivery 700 is preferably designed to generate the at least one stack 12 of sheets 02.
  • the at least one stack 12 of sheets 02 is generated in the at least one sheet delivery 700.
  • the at least one sheet delivery 700 is designed to generate the at least one partial stack 13 of the sheets 02.
  • the at least one sheet 02 and further sheets 02 of the sheets 02 are preferably deposited on the at least one stacking support 17 in the at least one sheet delivery 700 and the at least one stack 12, for example a first stack 12, is formed.
  • the transport is extended.
  • another stacking pad 17, for example designed as a pallet 17 is placed in the sheet delivery 700 or a stacking pad 17, for example designed as a conveyor belt, is moved so that a free area of the conveyor belt is arranged in the sheet delivery 700, and preferably at least one second stack 12 formed by depositing the sheets 02.
  • the at least one sheet delivery 700 is preferably not designed to convey any further sheets 02 while the first stack 12 is being transported away.
  • the at least one sheet delivery 700 has at least one non-stop device.
  • the at least one non-stop device is designed to introduce at least one element, for example a rake, into the transport path of the at least one sheet 02, so that the at least one sheet 02 is not placed on a sheet 02, for example already deposited, underneath the inserted element of a first partial stack 13 can be deposited, but rather forms a further second partial stack 13 as the first sheet 02.
  • the first partial stack 13 is transported away, for example, while further sheets 02 of the sheets 02 are placed on the at least one first sheet 02 of the second partial stack 13 in the sheet delivery 700 be filed.
  • the at least one sheet delivery 700 is preferably not designed to convey any further sheets 02 during the introduction of the at least one element into the transport path.
  • At least one, preferably precisely one, unit 1500 designed as a cutting unit 1500 with at least one cutting tool 1501 is arranged in the transport direction T.
  • the at least one cutting unit 1500 is preferably arranged inline after the at least one sheet delivery 700.
  • the at least one unit 1500 embodied as a cutting unit 1500 is preferably embodied to process the sheets 02.
  • the at least one cutting unit 1500 is preferably arranged in the sheet processing machine 01 instead of the at least one blanking unit 1200.
  • the at least one cutting unit 1500 is advantageously more cost-effective than the at least one blanking unit 1200.
  • the at least one cutting unit 1500 is also advantageously designed to perform at least one cut, in particular at least one straight cut, quickly and easily.
  • the at least one transfer transport system 800; 900; 1000 arranged.
  • the at least one transfer transport system 800; 900; 1000 designed to transport the sheets 02 with at least one cycle conveyor, preferably without interruption, more preferably step-by-step, in particular with each machine cycle, to the at least one cutting unit 1500.
  • This enables further processing of the sheets 02, in particular of the at least one partial stack 13, in the at least one cutting unit 1500 during the subsequent machine cycle, which advantageously means that neither the cutting unit 1500 is idling nor the sheets 02 to be processed are backed up or closed processing partial stacks 13 on the cutting unit 1500 arises.
  • a cycle conveyance describes a guiding of the sheets 02 along the transport path, with at least one sheet 02 or at least one stack 12 or at least one partial stack 13 within at least one machine cycle of the sheet processing machine 01 from a unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500 to an adjoining unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500 is transported.
  • a machine cycle describes above and below preferably a sum of those process steps and / or sequences that take place within the processing machine 01, preferably within an assembly 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500, run in a consistent order.
  • the relevant process steps and / or sequences are preferably only repeated with the next machine cycle in the same sequence.
  • a clock drive shaft completes a complete rotation around its axis of rotation within one machine cycle.
  • a machine cycle comprises in each case a processing step of the at least one sheet 02 within an assembly 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500, as well as the transport of the at least one sheet 02 to a respective processing point and / or the transport from the respective processing point to a subsequent unit 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500.
  • processing processes and / or processing processes for example aligning, punching, transport, separation of copies 03 and / or display of copies 03, preferably simultaneously in different units 100; 200; 300; 400; 500; 600; 700; 800; 900; 1000; 1100; 1200; 1400; 1500 on different arches 02 of arches 02 instead.
  • this is at least one transfer transport system 800; 900; 1000 den at least one partial stack 13 generated in the at least one sheet delivery 700 is designed to be transported to the at least one cutting unit 1500.
  • the at least one transfer transport system 800 is preferred; 900; 1000 designed to transport the at least one stack 12 generated in the at least one sheet delivery 700.
  • the at least one transfer transport system 800 is preferred; 900; 1000 designed to divide the at least one stack 12 into at least two partial stacks 13. This is preferably at least one transfer transport system 800; 900; 1000 designed to transport the at least two partial stacks 13 to the at least one cutting unit 1500.
  • the at least one transfer transport system 800 preferably comprises; 900; 1000 has at least one unit 900 designed as a handling device 900.
  • the at least one transfer transport system 800; 900; 1000 has the at least one assembly 900 designed as a handling device 900.
  • the at least one handling device 900 is preferably designed to divide the at least one stack 12 into the at least two, preferably at least four, more preferably at least six, more preferably into a plurality of partial stacks 13.
  • the at least one handling device 900 is preferably designed to generate the at least one partial stack 13 of sheets 02 starting from the at least one stack 12 of sheets 02.
  • the at least one cutting unit 1500 is preferably additionally or alternatively den at least one partial stack 13 of the sheets 02, preferably exactly one partial stack 13 per machine cycle, designed to be processing.
  • the at least one partial stack 13 of sheets 02 in the at least one cutting unit 1500 downstream of the sheet delivery 700 is preferably processed with the at least one cutting tool 1501.
  • By machining a partial stack 13 instead of a stack 12 overloading of the at least one cutting tool 1501 during the machining process in the at least one cutting unit 1500, for example due to the cutting forces to be applied, is avoided.
  • the service life of the at least one cutting tool 1501 is preferably also increased, for example due to low wear.
  • the efficiency of the cutting unit 1500 is increased compared to processing the individual sheets 02.
  • the at least one cutting unit 1500 preferably has the at least one cutting tool 1501.
  • the at least one cutting unit 1500 preferably has precisely one cutting tool 1501.
  • the at least one cutting tool 1501 preferably has at least one, preferably precisely one, knife.
  • the at least one cutting tool 1501 is preferably designed to generate at least one cut.
  • the at least one cut can preferably be produced by the at least one cutting tool 1501.
  • the at least one cutting tool 1501 is preferably oriented orthogonally to the transport direction T, preferably parallel to the transverse direction A. A longest edge of the at least one cutting tool 1501 is thus preferably arranged orthogonally to the transport direction T, preferably parallel to the transverse direction A.
  • the at least one cutting tool 1501 in the at least one sheet 02, preferably the at least one partial stack 13, is a cut orthogonal to the transport direction T. , preferably formed parallel to the transverse direction A generating.
  • the at least one cutting tool 1501 preferably has at least one linear guide 1502, preferably at least two, for example exactly two, linear guides 1502.
  • the at least one linear guide 1502 is preferably designed to lead the at least one cutting tool 1501 into an active area of the at least one cutting tool 1501 and / or to lead out of the active area and / or to lead in and / or to lead out.
  • the effective area of the at least one cutting tool 1501 is preferably the area along the transport path in which the at least one cutting tool 1501 comes into contact with the at least one sheet 02, preferably the at least one partial stack 13, more preferably in which area along the transport path this is at least a cutting tool 1501 is designed to carry out at least one cut.
  • the at least one linear guide 1502, the at least one cutting tool 1501, is preferably designed to lead in the vertical direction V, preferably from above, into the at least one working area and / or, preferably to lead out, upwards.
  • the at least one cutting tool 1501 is preferably designed to cut into the at least one sheet 02, preferably the at least one partial stack 13, in the vertical direction V, preferably from above, in particular vertically.
  • the force of gravity of the at least one cutting tool 1501 is used in order to minimize the force to be used for processing, in particular cutting, the at least one sheet 02, in particular the at least one partial stack 13.
  • the at least one cutting tool 1501 is designed to carry out at least one cut orthogonally to the transport direction T.
  • the at least one cutting tool 1501 preferably cuts the at least one partial stack 13 with at least one cut orthogonally to the transport direction T, preferably parallel to the transverse direction A.
  • the at least one cutting tool 1501 is preferably at least two, more preferably at least three, more preferably at least four, during a machine cycle. Making cuts orthogonal to the transport direction T. trained and / or performs.
  • the at least one partial stack 13 is meanwhile moved along the transport path in the transport direction T, for example by at least one transport means, in particular by at least one conveyor belt, so that in each case one area of the at least one partial stack 13 to be processed for each cut of the at least one cutting tool 1501 in the
  • the effective area of the at least one cutting tool 1501, for example below the at least one cutting tool 1501 is arranged.
  • Several cuts are advantageously possible per machine cycle.
  • a plurality of panels 03 of the at least one sheet 02 which are preferably arranged one behind the other in the transport direction T, are advantageously separated from one another, in particular during a machine cycle.
  • all of the panels 03 of the at least one sheet 02 which are preferably arranged one behind the other in the transport direction T, are thus separated from one another.
  • the at least one cutting tool 1501 is preferably designed to cut the sheets 02 of the at least one partial stack 13 together, preferably at the same time.
  • the at least one sheet 02 of the sheet 02 preferably has at least one use 03.
  • the at least one benefit 03 preferably has at least one outer delimiting edge.
  • the at least one outer delimiting edge is preferably designed to delimit the at least one benefit 03, in particular its outline within the at least one sheet 02, and / or with respect to remnants 04; 05; 06 of the at least one sheet 02, which remnants 04; 05; 06 are preferably arranged outside the outline of the at least one benefit 03 on the sheet 02, designed to be delimited.
  • the at least one outer delimiting edge for example at least a first section of the outer delimiting edge, is preferably arranged orthogonally to the transport direction T on the at least one sheet 02.
  • the at least one sheet 02 has at least two, preferably at least four, more preferably at least eight, for example twenty, copies 03.
  • the at least two, preferably at least four, more preferably at least eight, for example twenty, benefits 03 are preferably arranged in at least two, preferably at least three, more preferably at least four, for example five, rows and / or in at least two columns.
  • the at least two rows are preferably arranged one behind the other in the transport direction T.
  • the at least two columns are preferably arranged next to one another in the transport direction T.
  • At least two columns of panels 03 are made by the at least one processing in the at least one shaping unit 300; 400; 500; 600 separated from each other.
  • at least two panels 03 arranged next to one another in the transport direction T are produced by the at least one processing in the at least one shaping unit 300; 400; 500; 600 separated from each other.
  • the at least two panels 03 arranged next to one another in the transport direction T and / or the at least two columns are processed in the at least one shaping unit 300; 400; 500; 600 through at least one remnant piece 04; 05; 06, for example by at least one gripper edge 06, held at its position in the at least one sheet 02.
  • the sheet processing machine 01 is designed such that the at least one cutting tool 1501 makes the at least one cut along the at least one outer boundary edge of the at least one panel 03, in particular the first section of the outer boundary edge, i.e. preferably orthogonally to the transport direction T. is formed and / or performs.
  • the at least one up 03 of the at least one sheet 02 of the at least one partial stack 13 is preferably of at least one remnant 04; 05; 06 and / or separated from at least one further up 03 of the at least one sheet 02, which contains at least one remaining piece 04; 05; 06 and / or which at least one further use 03 in the transport direction T before or after the at least one use 03 on which at least one sheet 02 is arranged.
  • the at least one cutting tool 1501 is preferably at least two, preferably at least three, more preferably at least four, for example five, panels 03 of the at least one sheet 02 of the sheets 02, preferably which at least two panels 03 are arranged one behind the other in the transport direction T, more preferably which at least two panels 03 are arranged in at least two different rows, formed by the at least one cut, preferably by at least two cuts, more preferably by at least three cuts, for example by four cuts, separating and / or separating them.
  • the at least one cutting tool 1501 is preferably the at least two, preferably at least three, more preferably at least four, for example five, copies 03 of all sheets 02 of the at least one partial stack 13, preferably which at least two copies 03 are arranged one behind the other in the transport direction T, more preferably which at least two panels 03 are arranged in at least two different rows, formed by the at least one cut, preferably by at least two cuts, more preferably by at least three cuts, for example by four cuts, separated from one another within a sheet 02.
  • the at least two rows of the panels 03 of the at least one sheet 02, preferably all of the sheets 02 of the at least one partial stack 13, are preferably completely separated from one another after they have been processed in the at least one cutting unit 1500.
  • the at least two copies 03 of the at least one sheet 02, preferably all sheets 02 of the at least one partial stack 13, are preferably completely separated from one another after they have been processed in the at least one cutting unit 1500 and are located as individual copies 03, for example as part of the at least one partial stack 16 , before.
  • a blank separating unit 1200 arranged in the transport direction T after the at least one cutting unit 1500 for separating the blanks 03 from one another is preferably omitted.
  • the at least one cutting tool 1501 is designed to carry out and / or carries out the at least one cut over an entire width of at least one sheet 02 of the sheets 02, preferably of the at least one partial stack 13.
  • the at least one cutting tool 1501 is preferably designed and / or carries out the at least one cut over the entire working width of the sheet processing machine 01.
  • the cutting tool 1501 is thus preferably during a processing step, preferably during a cut of the cutting tool 1501, more preferably at the same time, at least two, in particular juxtaposed, uses 03 of the at least one sheet 02, preferably all sheets 02 of the at least one partial stack 13, of at least two columns arranged next to one another from the at least one further panel 03 and / or the at least one remnant piece 04; 05; 06 designed separating, which at least one further use 03 and / or which at least one remaining piece 04; 05; 06 is arranged in the transport direction T before or after the at least two benefits 03.
  • This is in particular a time saving compared to a separation one after the other and / or preferably increases the efficiency of the at least one cutting unit 1500.
  • the at least one sheet 02 of the sheet 02 preferably has the at least one gripper edge 06, preferably the at least two gripper edges 06.
  • the sheet processing machine 01 is designed so that the at least one cutting unit 1500 removes the at least one gripper edge 06, preferably the at least two gripper edges 06, from the at least one sheet 02, in particular from all sheets 02 of the at least one partial stack 13 is and / or removed.
  • the at least one sheet 02 Since the at least one sheet 02 is transported in the at least one shaping unit 300; 400; 500; 600 and the at least one sheet delivery 700 on the at least one gripper edge 06 at least temporarily from at least one holding element, for example a gripper, of the at least one shaping unit 300; 400; 500; 600 and / or the at least one sheet delivery 700 is held and, for example, in addition to protecting and / or protecting against waste, the benefit 03 of the Sheet 02, the at least one sheet 02 has the at least one gripper edge 06 in the at least one sheet delivery 700. Removal of the at least one gripper edge 06 is only advantageous in the transport direction T after the at least one sheet delivery 700. By removing the at least one gripper edge 06 in the at least one cutting unit 1500, the work of an operator who would otherwise have to remove the at least one gripper edge 06 by hand, for example, is made easier.
  • the at least one cutting unit 1500 is also used for cuts which have an angle of unequal ninety degrees to the transport direction T.
  • the at least one cutting unit 1500 has at least one further cutting tool 1501 for this purpose, which produces at least one cut at the required angle to the transport direction T, in particular not equal to ninety degrees, for example zero degrees.
  • the at least one cutting unit 1500 is preferably designed to generate and / or generates at least one cut at an angle not equal to ninety degrees to the transport direction T.
  • the sheet processing machine 01 preferably has the at least one transfer transport system 800; 900; 1000 on.
  • This is preferably at least one transfer transport system 800; 900; 1000 arranged in the transport direction T after the at least one sheet delivery 700, in particular without at least one further unit 300; 400; 500; 600; 1200; 1500, preferably without at least one further unit 300 processing the sheets 02; 400; 500; 600; 1200; 1500, like the at least one shaping unit 300; 400; 500; 600 or the at least one blanking unit 1200 or the at least one cutting unit 1500, in between.
  • At least one transfer transport system 800; 900; 1000 an inline concatenation, that is, a coupling of the units 100; 200; 300; 400; 500; 600; 700; 1100; 1200; 1400; 1500 with one another without leaving the transport path within the sheet processing machine 01, further preferably at least one coupling of the at least one shaping unit 300; 400; 500; 600 with the at least one further unit 1200 processing the sheets 02; 1500, in particular the at least one blanking unit 1200 and / or the at least one cutting unit 1500.
  • the at least one shaping unit 300; 400; 500; 600 to use the processing machine 01 designed as a rotary punching machine 01 and within the units 800; 900; 1000; 1100; 1200; 1400; 1500, which are located downstream of the at least one sheet delivery 700 in the transport direction T, also to further process or process the sheets 02 at a high production speed.
  • the sheets 02 preferably remain within the sheet processing machine 01 during all processing steps or processing steps without leaving the transport path within the sheet processing machine 01.
  • the processing of a substrate 02 describes above and below the changing of at least one property of the substrate 02 in question with regard to its physical properties and / or material properties, in particular its mass and / or shape and / or appearance, for example punching the substrate 02 in the at least one Shaping unit 300; 400; 500; 600.
  • the substrate 02 can be converted into at least one further processable intermediate product and / or end product by at least one processing operation.
  • the processing of a substrate 02 describes above and below the changing of at least one property of the substrate 02 in question, such as its position and / or physical properties and / or material properties, for example by aligning the substrate 02 in the at least one system unit 200.
  • the at least one further sheet 02 processing the sheets 02 is preferred Unit 1200; 1500, in particular the at least one blanking unit 1200 and / or the at least one cutting unit 1500.
  • This at least one further unit 1200 processing the sheets 02; 1500 is preferably designed to separate the individual panels 03 of the at least one sheet 02 from one another.
  • copies 03 separated from one another are then present, for example in the form of the at least one partial copy stack 16.
  • the at least one transfer transport system 800; 900; 1000 is preferably along the transport path and / or in the transport direction T between the at least one sheet delivery 700 and the unit 1200; 1500, in particular the at least one blanking unit 1200 and / or the at least one cutting unit 1500. This preferably enables optimal feeding of the sheets 02 to the at least one further unit 1200 processing the sheets; 1500.
  • the sheet 02 is positioned along the transport path between the at least one transfer transport system 800; 900; 1000 and the at least one further unit 1200; 1500, in particular the at least one blanking unit 1200 and / or the at least one cutting unit 1500, the at least one unit 1100 configured as an intermediate alignment 1100.
  • the sheets 02, in particular the at least one partial stack 13, are preferably aligned with respect to the at least one stop.
  • the at least one further unit 1200; 1500 in particular the at least one blanking unit 1200 and / or the at least one cutting unit 1500, the sheets 02 in the form of the at least one Part of the stack 13 formed processing.
  • the at least one tool of the at least one blanking unit 1200 and / or the at least one cutting tool 1501 of the at least one cutting unit 1500 is spared and / or forces to be applied are preferably minimized. Nevertheless, a high processing speed compared to processing individual sheets 02 is preferably ensured.
  • the at least one transfer transport system 800 preferably transports; 900; 1000 the sheets 02 by means of the at least one cycle conveyor to the at least one further sheet 02 processing unit 1200; 1500, preferably the at least one blanking unit 1200 and / or the at least one cutting unit 1500.
  • the at least one transfer transport system 800 preferably comprises; 900; 1000 at least one unit 800 designed as a feed means 800.
  • the at least one feed means 800 is preferably directly connected to the at least one Sheet delivery 700 arranged, so preferably without at least one further unit in between.
  • the at least one feed means 800 is preferably arranged upstream of the at least one handling device 900 in the transport direction T.
  • the at least one sheet delivery 700 is preferably designed to generate the at least one stack 12 of sheets 02.
  • the at least one feed means 800 is preferably designed to feed the at least one stack 12 to the at least one unit 900 designed as a handling device 900.
  • the at least one stack 12 is preferably fed by the at least one feed means 800 of the transfer transport system 800; 900; 1000 to the at least one handling device 900 of the at least one transfer transport system 800; 900; 1000 transported.
  • the at least one feed means 800 preferably conveys the at least one stack 12 from the at least one sheet delivery 700 to the at least one handling device 900.
  • the at least one feed means 800 is preferably designed as at least one transport means.
  • the at least one supply means 800 is preferably at least one transport means of the transfer transport system 800; 900; 1000.
  • the at least one feed means 800 which is designed to feed the at least one stack 12 to the at least one handling device 900, is preferably designed as a conveyor belt or conveyor belt or conveyor roller or logistics system.
  • the at least one feed means 800 is designed as a conveyor belt or conveyor belt.
  • the at least one stack 12 is positioned and / or positionable and / or is transported with at least one stacking base 17, for example a pallet 17, or directly, i.e. without a stacking base 17, on the at least one feed means 800 designed as a transport means, for example a conveyor belt or conveyor belt .
  • the at least one feed means 800 has at least one, preferably at least two, preferably at least four, for example fifteen, conveyor rollers.
  • the at least one feed means 800 is designed as a logistics system.
  • the at least one feed means 800 embodied as a logistics system has at least one robot, for example with at least one gripper arm, for example at least two gripper arms.
  • the at least one supply means 800 designed as a logistics system has at least one, preferably at least two, for example four, driverless transport means, preferably at least one transport means designed as a driverless guided vehicle (AGV).
  • AGV driverless guided vehicle
  • the at least one driverless transport means is preferably guided without contact and / or controlled by at least one control system.
  • the at least one driverless transport means has grid navigation, with at least one sensor of the driverless transport vehicle being designed to detect grid points, or laser navigation, where the at least one sensor is designed to detect markings and / or reference points, and / or, for example, has at least one virtual guideline along which the at least one means of transport is guided.
  • the at least one sensor is designed, for example, as a camera, laser scanner, lidar, magnetic sensor or color sensor.
  • the at least one driverless transport vehicle of the at least one supply means 800 embodied as a logistics system has at least one first position and at least one second position. In the first position, the at least one driverless transport vehicle is preferably designed to receive the at least one sheet 02 and / or the at least one stack 12.
  • the at least one driverless transport vehicle is preferably designed to dispense the at least one sheet 02 and / or the at least one stack 12.
  • the at least one driverless transport vehicle is preferably designed to be movable and / or movable between the first and the second position.
  • at least one sheet 02 and / or at least one stack 12 and / or at least one partial stack 13 can be fed to the at least one handling device 900 from outside the transport path.
  • at least one sheet 02 and / or at least one stack 12 and / or at least one partial stack 13 is brought onto the transport path from outside the transport path, for example starting from another processing machine and / or from outside the sheet processing machine 01, and fed to the at least one handling device 900 .
  • the at least one transfer transport system 800; 900; 1000 preferably comprises the at least one handling device 900.
  • the at least one handling device 900 is preferably the sheet 02 after the at least one shaping unit 300; 400; 500; 600 of the sheet processing machine 01 is arranged.
  • the at least one handling device 900 is arranged directly following the at least one feed means 800, that is to say without further units in between.
  • the at least one handling device 900 is preferably designed to accept the at least one stack 12 from the at least one feed means 800.
  • the at least one handling device 900 is preferably designed to separate the at least one partial stack 13 from the at least one stack 12 of sheets 02.
  • the at least one partial stack 13 can preferably be separated from the at least one stack 12 by the at least one handling device 900.
  • This is preferably at least one transfer transport system 800; 900; 1000, preferably the at least one handling device 900, the at least one partial stack 13 to the at least one further unit 1200; 1500, preferably designed to feed the at least one blanking unit 1200 or the at least one cutting unit 1500, preferably inline, that is to say preferably without leaving the transport path within the sheet processing machine 01.
  • the at least one handling device 900 forms the at least one partial stack 13.
  • the at least one handling device 900 is preferably designed to form the at least one partial stack 13 starting from the at least one stack 12 of the sheets 02.
  • the at least one handling device 900 forms at least two, preferably at least four, for example eight partial stacks 13 from the at least one stack 12.
  • the at least one handling device 900 is the at least two, preferably at least four, for example eight partial stacks 13 in succession, preferably one partial stack each 13 per machine cycle, the at least one further unit 1200; 1500, preferably designed to feed the at least one blanking unit 1200 and / or the at least one cutting unit 1500.
  • the at least one stack of parts 13 is preferably formed by the at least one handling device 900 with a height or a number of sheets 02 that is provided by the at least one further unit 1200; 1500 can be processed. This ensures that its tool is protected while the sheet 02 is being processed.
  • the at least one handling device 900 has at least one conveying means 901.
  • the at least one stack 12 is preferably positioned and / or can be positioned at least temporarily on the at least one conveyor means 901.
  • the at least one conveying means 901 is preferably designed to accept the at least one stack 12 from the at least one supply means 800.
  • the at least one conveying means 901 is preferably designed as a conveyor belt 901.
  • the at least one conveyor 901 has at least one, preferably at least two, preferably at least four, for example fifteen, conveyor rollers.
  • the at least one conveying means 901 is preferably a means of transport of the transfer transport system 800; 900; 1000.
  • the at least one handling device 900 is preferably designed to separate the at least one partial stack 13 from the at least one stack 12 of sheets 02 positioned on the at least one conveying means 901.
  • the at least one transfer transport system 800; 900; 1000 has at least one, preferably at least two, for example two, rotary element 903.
  • the at least one handling device 900 preferably has the at least one rotary element 903.
  • the at least one conveying means 901 is arranged on the at least one rotary element 903, for example a turntable or a pivoting, preferably rotating, substructure, for example a turntable.
  • the at least one conveying means 901 thus preferably has the at least one rotary element 903.
  • the at least one rotary element 903 is preferably designed to be rotatable and / or pivotable and / or rotatable and / or pivotable about a vertical axis, preferably an axis parallel to the vertical direction V.
  • the at least one rotary element 903 is preferably by at least 30 ° (thirty degrees), preferably by at least 40 ° (forty degrees), and additionally or alternatively by a maximum of 330 ° (three hundred and thirty degrees), preferably by a maximum of 300 ° (three hundred degrees), for example 90 ° (ninety degrees) and / or 270 ° (two hundred and seventy degrees), designed to be rotatable and / or pivotable and / or pivotable and / or rotatable.
  • the at least one rotating element 903 and the at least one conveying means 901 are preferably designed to rotate and / or pivot about the vertical axis.
  • the at least one conveying means 901 is preferably designed to be rotating and / or pivoting and / or rotatable and / or pivotable by the at least one rotating element 903, preferably about the vertical axis.
  • This enables the transport direction T to be changed along the transport path.
  • the Transport path a bend or curve, for example by 90 ° (ninety degrees).
  • the front edge 07 of the sheet 02 is preferably the first edge 07 of the sheet 02 both before the rotation and after the rotation in the transport direction T.
  • a compact, space-saving design of the sheet processing machine 01 is possible.
  • the at least one conveying means 901 is designed to be height-adjustable.
  • the at least one handling device 900 preferably has at least one height adjustment 904 of the at least one conveying means 901.
  • the at least one height adjustment 904 is designed as a lifting table, for example as a scissor lifting table, on which the at least one conveying means 901 is arranged.
  • the at least one height adjustment 904 is arranged on the at least one rotary element 903.
  • the at least one height adjustment 904 has at least one drive, for example a pneumatic drive or an electric motor.
  • the at least one conveying means 901 preferably has at least one first position and at least one second position.
  • the at least one conveying means 901 is preferably arranged in the first position in the vertical direction V at a first height.
  • a height of the at least one conveyor 901 preferably corresponds to that distance between the surface of the at least one conveyor 901 on which surface the at least one stack 12 at least temporarily, in particular during its transport to the at least one downstream unit 1000; 1100; 1200; 1400; 1500, is arranged, and the base of the at least one handling device 900, for example the floor of the hall.
  • the at least one conveying means 901 is preferably arranged in the second position at a second height. In this case, the second height is preferably arranged in the vertical direction V above the first height.
  • the at least one first position is preferably at least one position of the at least one conveying means 901 which is lower in the vertical direction V.
  • the at least one second position is preferably at least one position of the at least one conveying means which is upper in the vertical direction V 901. More preferably, the at least one second position of the at least one conveying means 901 can be adapted to the height of the at least one stack 12 and / or is adapted to it.
  • the at least one conveying means 901 preferably has at least two, preferably at least four, and / or preferably a maximum of ten, preferably a maximum of eight, second, preferably upper, positions.
  • the at least two second, preferably upper, positions are preferably arranged at heights that are different from one another.
  • the at least one handling device 900 is preferably designed in the first, preferably lower, position of the at least one conveying means 901 to position the at least one stack 12 on the at least one conveying means 901.
  • the at least one feed means 800 is preferably at a distance from its surface on which the at least one stack 12 is transported to the base of the at least one feed means 800, for example the floor of the hall, so that the surface of the at least one feed means 800 on the is arranged at the same height as the surface of the at least one conveyor 901 arranged in the first position. This enables the at least one stack 12 to be easily transferred from the at least one feeder 800 to the at least one handling device 900, in particular to the at least one conveyor 901.
  • the at least one conveying means 901 is preferably at a greater distance from the base of the handling device 900 in the second, preferably upper, position than in its first position.
  • the conveyor means 901 has thus been moved in the vertical direction V, preferably raised.
  • the second position of the at least one conveying means 901 is preferably adapted to the at least one stack 12, which is positioned on the at least one conveying means 901, in terms of its height, i.e. the distance between its surface and the base.
  • the at least one handling device 900 in the second position of the at least one conveying means 901 is preferably designed to separate the at least one partial stack 13 from the at least one stack 12.
  • the second position is the at least one Conveying means 901 designed such that at least one separating means 909 is designed to separate the at least one partial stack 13, which preferably comprises the respective uppermost sheets 02 of the at least one stack 12, from the at least one stack 12.
  • the at least one conveying means 901 is moved further in the vertical direction V after the separation of a first partial stack 13, preferably raised, so that at least one second partial stack 13, for example afterwards at least a third partial stack 13 and so on, of the at least one stack 12 can be separated.
  • This preferably enables continuous dividing of the at least one stack 12 into the at least two, preferably at least four, for example eight, partial stacks 13 and / or their uninterrupted further transport within the sheet processing machine 01.
  • the at least one handling device 900 has at least one transfer device 902 after the at least one conveying device 901 in the transport direction T.
  • the at least one partial stack 13 is preferably at least temporarily, in particular before it is conveyed to the unit 1000; 1100; 1200; 1500, positioned and / or positionable on the at least one transfer means 902.
  • the at least one transfer means 902 is preferably designed as a conveyor belt 902 or a conveyor table.
  • the at least one transfer means 902 has at least one, preferably at least two, preferably at least four, for example fifteen, conveyor rollers.
  • the at least one transfer means 902 is preferably a means of transport of the transfer transport system 800; 900; 1000.
  • the at least one transfer means 902 is designed to be height-adjustable.
  • the at least one handling device 900 has at least one height adjustment 906 of the at least one transfer means 902.
  • the at least one transfer means 902 preferably has the at least one height adjustment 906.
  • the at least one transfer means 902 preferably has at least one first position and at least one second position.
  • the at least one first position is preferably at least one position of the at least one takeover means 902 which is lower in the vertical direction V.
  • the at least one second position is preferably at least one position of the at least one takeover means 902 that is upper in the vertical direction V.
  • the at least one transfer means 902 is preferably arranged at a second height in the second position.
  • the second height is preferably arranged in the vertical direction V above the first height.
  • a height of the at least one transfer means 902 preferably corresponds to that distance between the surface of the at least one transfer means 902, on which surface the at least one partial stack 13 at least temporarily, in particular during its transport to the at least one downstream unit 1000;
  • 1100; 1200; 1400; 1500 is arranged, and the base of the at least one handling device 900, for example the floor of the hall.
  • the at least one conveyor means 901 and the at least one transfer means 902 are preferably designed to be height-adjustable and / or height-adjusted relative to one another.
  • the at least one conveying means 901 and the at least one transfer means 902 preferably have a relative height adjustment 904; 906 to each other.
  • either the at least one conveyor means 901 or the at least one transfer means 902 has at least a first, preferably lower, position and at least a second, preferably upper, position.
  • either the at least one stack 12 or the at least one transfer means 902 is and / or can be arranged such that the at least one sub-stack 13, which sub-stack 13 preferably each comprises the at least one top sheet 02 of the at least one stack 12, of the at least a stack 12 is separated and from which at least one transfer means 902 is taken over and preferably transported further.
  • both the at least one conveying means 901 and the at least a transfer means 902 has at least a first, preferably lower, position and at least a second, preferably upper, position.
  • the positions of the at least one conveying means 901 and the positions of the at least one transfer means 902 are coordinated with one another, so that in particular a smooth transfer of the at least one partial stack 13 to the at least one transfer means 902 takes place.
  • the at least one stack 12 is preferably brought to the removal height of the at least one partial stack 13 from the at least one stack 12 and / or the at least one transfer means 902 is appropriately positioned at the removal height in order to accept the at least one partial stack 13.
  • the at least one transfer means 902 is preferably designed to move in the transport direction T and / or to be laterally adjustable.
  • the at least one transfer means 902 is preferably designed to move towards the at least one stack 12 and / or away from the at least one stack 12.
  • the at least one transfer means 902 preferably has at least one guide element 907.
  • the at least one guide element 907 is preferably designed to guide the at least one transfer means 902 in or against the transport direction T.
  • the at least one guide element 907 preferably guides the at least one takeover means 902 in or against the transport direction T.
  • the at least one takeover means 902 preferably has at least one takeover position, for example designed as a third position, and at least one forwarding position, for example designed as a fourth position.
  • the takeover position embodied as a third position is preferably the position in which the at least one takeover means 902 takes over the at least one partial stack 13.
  • the at least one transfer means 902 is preferably arranged at least partially, for example at least with a foremost edge of the transfer means 902, above the at least one conveying means 901, or more preferably at a minimal distance in the transport direction T from the at least one Funding 901 arranged.
  • it has at least one Transfer means 902 in the transfer position, which is embodied, for example, as a third position, is at a minimal distance from the leading edge 07 of the sheets 02 of the at least one stack 12 positioned on the conveying means 901.
  • the transfer position embodied as a fourth position is preferably that position in which the at least one transfer device 902 transfers the at least one partial stack 13 to the at least one unit 1000; 1100; 1200; 1400; 1500, in particular an assembly 1000 designed as a transfer means 1000, is designed to be transferring.
  • the at least one transfer means 902 preferably has the greatest possible, preferably maximum, distance in the transport direction T from the at least one conveying means 901 in the transfer position embodied, for example, as the fourth position.
  • the at least one takeover means 902 has at least one retraction position embodied, for example, as a fifth position.
  • the retraction position of the at least one transfer means 902, for example designed as the fifth position, is preferably arranged along the transport path in front of the transfer position, for example designed as the third position, and in front of the forwarding position, designed for example as the fourth position.
  • the at least one transfer means 902 is at least partially, preferably at least with the at least one foremost edge and further components of the transfer means 902, more preferably with the at least one foremost edge and at least one component of the transfer means designed as a transport means, in the retraction position, for example designed as a fifth position 902, arranged above the at least one conveying means 901.
  • the at least one transfer means 902 is preferably designed to be retractable and / or retractable into the at least one stack 12, preferably into the at least one stack 12 arranged on the at least one conveyor means 901.
  • the at least one transfer means 902 is preferably in the at least one stack 12, preferably arranged on the at least one conveying means 901, by a movement of the Transfer position designed to be retractable and / or retractable into the retracted position.
  • the at least one transfer means 902 preferably has at least one engagement member 908 on its side facing the at least one conveying means 901.
  • the at least one engagement member 908 is preferably designed to engage in the at least one stack 12, preferably arranged on the at least one conveyor means 901.
  • the at least one engagement member 908 preferably moves into a spatial region between the at least one at least partially raised partial stack 13 and the at least one, preferably remaining, stack 12.
  • the at least one engagement member 908 is designed as a conveyor roller 908.
  • the at least one engagement member 908 preferably has at least one drive, for example an electric motor.
  • the at least one engagement member 908, preferably the at least one engagement member 908 designed as a conveyor roller 908, is preferably driven by its drive, preferably driven in rotation.
  • the at least one engagement member 908 embodied as a conveyor roller 908 preferably has a direction of rotation which is configured to convey the at least one partial stack onto the surface of the at least one transfer means 902. This enables a smooth transfer of the at least one partial stack 13 from the at least one conveying means 901 to the at least one transfer means 902, the edges 07; 08; 09, in particular the leading edge 07, the sheet 02 are spared. For example, kinks or upsets in the sheets 02, in particular their edges 07; 08; 09, avoided during the handover.
  • the at least one handling device 900 has at least one separating means 909.
  • the at least one separating means 909 is designed as a counting disk and / or gripper and / or sword.
  • the at least one separating means 909 is preferably designed to be able to move into and / or move into the at least one stack 12.
  • the at least one separating means 909 is preferably designed to separate the at least one partial stack 13 from the at least one stack 12. This is further preferably at least one Separation means 909 designed to separate the at least one partial stack 13 from the at least one stack 12 positioned on the at least one conveyor means 901.
  • the at least one separating means 909 is preferably the at least one separate partial stack 13 on at least one edge 07; 08; 09 at least partially, for example without completely detaching the partial stack 13 from the at least one stack 12, designed in a lifting manner.
  • the at least one separating means 909 is preferably arranged at least temporarily, preferably at least during a release of the at least one partial stack 13 from the stack 12, above, preferably in the vertical direction V above, the at least one conveying means 901.
  • the at least one separating means 909 is preferably designed to position the at least one partial stack 13 on the at least one transfer means 902.
  • the at least one separating means 909 is furthermore preferably the at least two, preferably at least four, for example eight, partial stacks 13, preferably one after the other, preferably one partial stack 13 per machine cycle, positioned on the at least one transfer means 902.
  • the at least one transfer transport means 800; 900; 1000 prefers the at least one unit 1000 embodied as a transfer means 1000.
  • the at least one transfer device 1000 is preferably arranged directly following the at least one handling device 900, that is to say without further units in between.
  • the at least one forwarding means 1000 is preferably the at least one partial stack 13 to the at least one further unit 1200; 1500 trained handing over.
  • the at least one unit 1100 embodied as an intermediate alignment 1100 is preferably arranged in the transport direction T after the at least one transfer device 1000, preferably directly following it, that is to say without further units in between.
  • the at least one forwarding means 1000 is preferably receiving the at least one partial stack 13 from the at least one handling device 900, in particular from the at least one transferring means 902 and transports the at least one partial stack 13 to the at least one intermediate alignment 1100.
  • the at least one transfer means 1000 is designed as at least one conveyor belt.
  • the at least one transfer device 1000 has at least one, preferably at least two, preferably at least four, for example fifteen, conveyor rollers.
  • the at least one transfer means 1000 is preferably at least one transport means of the transfer transport system 800; 900; 1000.
  • the at least one forwarding means 1000 has at least one stop, preferably at least one lateral stop.
  • the at least one stop is preferably positioned in transverse direction A next to the at least one partial stack 13, preferably additionally or alternatively positionable, and designed to align the at least one partial stack 13 in transverse direction A.
  • the at least one forwarding means 1000 has at least two positions.
  • the first position preferably corresponds to that position in which the at least one transfer device 1000 takes over the at least one partial stack 13 and transfers it to the at least one intermediate alignment 1100.
  • the second position preferably corresponds to that position in which the at least one partial stack 13 is pressed against the at least one stop.
  • the second position is preferably shifted in the transverse direction A relative to the first position.
  • the at least one transfer device 1000 preferably moves within one machine cycle from the first position to the second position and back again to the first position.
  • the at least one partial stack 13 is preferably aligned laterally at the at least one stop, so that the at least one partial stack can be precisely positioned on the at least one transfer means 1000 and thus an exact, register-accurate transfer to the at least one intermediate alignment 1100 or to the at least one further sheet 02 processing unit 1200; 1500 takes place.
  • the at least one transfer transport system 800; 900; 1000 at least one rotary element 903 along the transport path of sheet 02 at the position of the at least one forwarding means 1000.
  • the at least one transfer device 1000 is arranged on the at least one rotary element 903, for example a turntable or a pivoting, preferably rotating, substructure, for example a turntable.
  • the at least one rotary element 903 is preferably designed to be rotatable and / or pivotable and / or rotatable and / or pivotable about a vertical axis, preferably an axis parallel to the vertical direction V.
  • the at least one rotary element 903 is preferably by at least 30 ° (thirty degrees), preferably by at least 40 ° (forty degrees), and additionally or alternatively by a maximum of 330 ° (three hundred and thirty degrees), preferably by a maximum of 300 ° (three hundred degrees), for example 90 ° (ninety degrees) and / or 270 ° (two hundred and seventy degrees), designed to be rotatable and / or pivotable and / or rotatable and / or pivotable.
  • the at least one rotary element 903 and the at least one transfer means 1000 are preferably designed to rotate and / or pivot about the vertical axis.
  • the at least one transfer means 1000 is preferably designed to be rotating and / or pivoting and / or rotatable and / or pivotable by the at least one rotating element 903, preferably about the vertical axis.
  • This enables the transport direction T to be changed along the transport path.
  • the transport path has a bend or curve, for example by 90 ° (ninety degrees).
  • the front edge 07 of the sheet 02 is preferably the first edge 07 of the sheet 02 both before the rotation and after the rotation in the transport direction T.
  • a compact, space-saving design of the sheet processing machine 01 is possible.
  • the sheet processing machine 01 has at least two, preferably at least three, for example exactly three, further units 1200; 1500 along the transport path after the at least one sheet delivery 700.
  • the sheet processing machine 01 has at least two, preferably at least three, for example exactly three, blank separating units 1200 along it of the transport path after the at least one sheet delivery 700.
  • the sheet processing machine 01 has at least two, preferably at least three, for example exactly three, cutting units 1500 along the transport path after the at least one sheet delivery 700.
  • the sheet processing machine 01 has at least one blanking unit 1200 and at least one cutting unit 1500 along the transport path after the at least one sheet delivery 700.
  • the sheet processing machine 01 preferably has within the at least one transfer transport system 800; 900; 1000 for this purpose at least one fork in the transport path, for example with at least one curved switch.
  • the at least one stack 12 and / or the at least one sheet 02 and / or the at least one partial stack 13 are preferably passed through the at least one sheet diverter to one of the at least two units 1200; 1500 directed and processed by this.
  • the production speed of the sheet processing machine 01 can advantageously be increased as a result, since several sheets 02 and / or stacks 12 and / or partial stacks 13 are simultaneously replaced by other units 1200; 1500 can be edited and / or are editable.
  • the at least one sheet 02 is preferably positioned in the form of at least one stack 12 in the feeder unit 100.
  • the at least one sheet 02 is preferably withdrawn from the at least one stack 12, for example as the top sheet 02 of the stack 12 or as the bottom sheet 02 of the stack 12. For example, additionally or alternatively, at least one stream of scaled sheets 02 is generated.
  • the at least one sheet 02 for example as a single sheet 02 or as an imbricated stream of sheets 02, is preferably transferred from the feeder unit 100 to the Plant unit 200 promoted.
  • the at least one sheet 02 in the at least one contact assembly 200 is preferably aligned in terms of its position in the transport direction T and / or in the transverse direction A.
  • the at least one sheet 02 is preferably converted, preferably sequentially, to the at least one shaping unit 300; 400; 500; 600 fed.
  • the at least one sheet 02 in the at least one shaping unit 300; 400; 500; 600 processed.
  • the shaping units 300; 400; 500; 600 is the at least one sheet 02 through the at least one shaping unit 300; 400; 500; 600 preferably embossed and / or grooved and / or punched and / or scored and / or cut and / or perforated and / or at least one scrap piece 04 is broken out of the at least one sheet 02.
  • the at least one sheet 02 preferably at least two sheets 02, more preferably a large number of sheets 02 are preferably collected in the at least one delivery unit 700.
  • the at least one stack 12 is preferably produced in the at least one sheet delivery 700.
  • the at least one partial stack 13 is produced in the at least one sheet delivery 700.
  • the at least one stack 12 and / or the at least one partial stack 13 is preferably from the at least one sheet delivery 700 to the at least one further unit 1200; 1500, preferably to the at least one blanking unit 1200 and / or to the at least one cutting unit 1500.
  • the at least one stack 12 and / or the at least one partial stack 13 is preferably transported by the at least one transfer transport system 800; 900; 1000 taken over by the at least one sheet delivery 700.
  • the at least one transfer transport system 800 preferably transports; 900; 1000 the at least one stack 12, which is preferably divided into at least two partial stacks 13 during transport, and / or the at least one partial stack 13 to the at least one further unit 1200 processing the sheets 02; 1500, preferably for the at least one blanking unit 1200 and / or for the at least one cutting unit 1500.
  • the at least one transfer transport system 800 preferably transports; 900; 1000 the at least one partial stack 13 produced in the at least one sheet delivery 700 for the at least one further unit 1200 processing the sheets 02; 1500; preferably to the at least one blanking unit 1200 and / or to the at least one cutting unit 1500.
  • the at least one stack 12 is preferably taken over by the at least one feed means 800, preferably following the creation of the stack in the at least one sheet delivery 700.
  • the at least one stack 12 is positioned on the at least one feed means 800.
  • the at least one stack 12 is received by the at least one feed means 800.
  • the at least one feed means 800 preferably transports the at least one stack 12 along the transport path to the at least one handling device 900.
  • the at least one partial stack 13 is preferably carried out by the at least one handling device 900 of the at least one transfer transport system 800; 900; 1000 is formed starting from the at least one stack 12 of the sheets 02.
  • the at least one conveying means 901 is preferably arranged in such a way that it can take over the at least one stack 12 from the at least one feeding means 800.
  • the at least one conveyor 901 is preferably in the first, preferably lower, position, which preferably enables the at least one stack 12 to be conveyed from the at least one feeder 800 to the at least one conveyor 901.
  • the at least one conveyor 901 takes over the at least one stack 12.
  • the at least one stack 12 is preferably positioned on the at least one conveyor 901 and / or transported by means of the at least one conveyor 901.
  • At least one component of the transfer transport system 800; 900; 1000 preferably in each case the at least one conveying means 901 and / or in each case the at least one forwarding means 1000, each pivoted by the at least one rotary element 903.
  • the at least one component of the transfer transport system 800; 900; 1000 preferably in each case the at least one conveying means 901 and / or in each case the at least one transferring means 1000, each rotated and / or pivoted by the at least one rotary element 903.
  • the at least one conveying means 901 is preferably rotated and / or pivoted by the at least one rotary element 903.
  • the at least one transfer device 1000 rotated and / or pivoted by the at least one rotary element 903, preferably by at least one additional or alternative rotary element 903 to the at least one rotary element 903 of the at least one conveyor 901.
  • the at least one rotary element 903 preferably rotates and / or pivots about the vertical axis, preferably the axis parallel to the vertical direction V.
  • the at least one rotary element 903 preferably rotates and / or pivots by at least 30 ° (thirty degrees), preferably by at least 40 ° (forty degrees), and additionally or alternatively by a maximum of 330 ° (three hundred and thirty degrees), preferably by a maximum of 300 ° (three hundred Degrees), for example by 90 ° (ninety degrees) and / or by 270 ° (two hundred and seventy degrees).
  • the at least one rotary element 903 preferably rotates and / or pivots by at least 30 ° (thirty degrees), preferably by at least 40 ° (forty degrees), more preferably by at least 80 ° (eighty degrees), and additionally or alternatively by a maximum of 150 ° ( one hundred and fifty degrees), preferably a maximum of 140 ° (one hundred and forty degrees), more preferably a maximum of 120 ° (one hundred and twenty degrees), for example by 90 ° (ninety degrees).
  • the at least one rotary element 903 rotates and / or pivots by at least 210 ° (two hundred and ten degrees), preferably at least 220 ° (two hundred and twenty degrees), more preferably at least 240 ° (two hundred and forty degrees), and additionally or alternatively by a maximum of 330 ° ( three hundred and thirty degrees), preferably a maximum of 320 ° (three hundred and twenty degrees), more preferably a maximum of 310 ° (three hundred and ten degrees), for example by 270 ° (two hundred and seventy degrees).
  • the at least one rotary element 903 rotates and / or pivots by 180 ° (one hundred and eighty degrees).
  • the at least one conveying means 901 on which the at least one stack 12 is positioned is preferably rotated and / or pivoted by the at least one rotary element 903.
  • the at least one conveying means 901 with the at least one stack 12 positioned thereon is preferably rotated and / or pivoted.
  • the at least one conveyor 901 is preferably rotated by the at least one rotating element 903, so that the at least one stack 12 then with the front edge 07 shows the sheet 02 in the new transport direction T, that is to say the transport direction T following the at least one handling device 900.
  • the at least one conveyor means 901 is preferably adjusted in height relative to the at least one transfer means 902.
  • the at least one conveyor 901 is preferably moved from the at least one first, preferably lower, position to the at least one second, preferably upper, position or vice versa, preferably by the at least one height adjustment 904.
  • the at least one conveying means 901 is moved from the first, preferably lower, position into the second, preferably upper, position by the at least one height adjustment 904.
  • the height of the at least one transfer means 902 is adjusted, for example by an adjustment from the first, preferably lower, position to the second, preferably upper, position or vice versa, preferably by the at least one height adjustment 906
  • The, preferably upper, position is that position in which the first partial stack 13, which comprises the uppermost sheet 02 of the stack 12, is separated from the at least one stack 12.
  • the height of the at least one conveying means 901 in the at least one transfer means 902 is preferably adjusted relative to one another so that the at least one partial stack 13 can be separated from the at least one stack 12, in particular by moving the at least one transfer means 902 into the at least one, preferably stack 12 positioned on the conveyor 901.
  • the at least one handling device 900 is preferably used for the at least a partial stack 13 is separated from the at least one stack 12. Preferably, exactly one separation process of the at least one partial stack 13 from the at least one stack 12 is carried out in one machine cycle.
  • the at least one stack 12 arranged on the at least one conveyor means 901 is preferably divided.
  • the at least one stack 12 is preferably divided on the at least one conveying means 901 which has the at least one rotary element 903 and / or which is arranged on the at least one rotary element 903.
  • the at least one stack 12 is preferably divided on the at least one rotary element 903.
  • the at least one transfer device 902 preferably moves into the at least one stack 12 positioned on the at least one conveyor device 901.
  • the at least one transfer means 902 moves into the at least one stack 12 positioned on the at least one rotary element 903, preferably on the at least one conveying means 901 with the at least one rotary element 903.
  • the at least one transfer means 902 preferably takes over the at least one partial stack 13 from the at least one conveying means 901, preferably by moving the transfer means 902 from the transfer position into the retraction position.
  • the at least one transfer means 902, preferably in the transfer position transfers the at least one partial stack 13 to the at least one downstream unit 1000; 1100; 1200; 1400; 1500, preferably to the at least one forwarding means 1000.
  • the at least one separating means 909 preferably separates the at least one partial stack 13 from the at least one stack 12 positioned on the at least one conveying means 901, preferably by placing the at least one separating means 909 between two sheets 02 of the at least one
  • the stack 12 moves in and / or the at least one partial stack 13 on at least one edge 07; 08; 09 the arch 02 lifts.
  • the at least one guide element 907 preferably guides the at least one transfer device 902 in or against the transport direction T to the at least one transfer position and / or to the at least one transfer position and / or to the at least one entry position.
  • the at least one engagement member 908, preferably designed as a conveyor roller 908, is in direct contact with the at least one stack 12 by a movement of the at least one transfer means 902 from the transfer position, for example designed as a fourth position, to the transfer position, for example, designed as a third position brought.
  • the movement, preferably rotation, of the at least one engagement member 908 is preferably at least one edge 07; 08; 09, preferably the at least one front edge 07 of the lowermost sheet 02 of the at least one partial stack 13, for example the first partial stack 13, detached from the topmost sheet 02 of the remaining stack 12 arranged below it, for example from the topmost sheet 02 of the second partial stack 13 raised.
  • the stack 12 is moved a little downwards by changing the position of the at least one conveyor 901, preferably by moving the at least one conveyor 901 relative to the at least one transfer device 902. This relative movement preferably creates a gap.
  • the at least one separating means 909 which is preferably designed as a gripper, preferably moves into the stack 12, for example by at least one relative movement of the at least one separating means 909 with respect to the at least one stack 12.
  • the at least one separating means 909 preferably moves into the area which the edge 07; 08; 09 of the lowermost sheet 02 of the at least one partial stack 13 has released, in particular the gap that has arisen.
  • the at least one separating means 909 grips the at least one partial stack 13, for example the first partial stack 13, preferably on the at least one edge 07; 08; 09.
  • the at least one separating means 909 preferably lifts the at least one partial stack 13, in particular the edge 07; 08; 09 the sheet 02, continue on.
  • the at least one transfer means 902 preferably has a movement relative to the at least one separating means 909 and / or to the at least one partial stack 13.
  • the at least one takeover means 902 is preferably moved from the takeover position embodied as the third position, for example, into the takeover position embodied as the fifth position, for example Moved in position, while additionally or alternatively the at least one separating means 909 is moved in the opposite direction, preferably in the transport direction T, from a first position to a second position.
  • the first position of the at least one separating means 909 is preferably arranged along the transport path in front of its second position.
  • the at least one separating means 909 In the second position of the at least one separating means 909, the at least one separating means 909 preferably releases its contact with the at least one partial stack 13, for example by opening the gripper.
  • the at least one partial stack 13 is now preferably complete, that is to say preferably with all of the edges 07; 08; 09 the sheet 02 on which at least one transfer device 902 is positioned.
  • the at least one transfer means 902 preferably conveys the at least one partial stack 13 to the at least one transfer means 1000, preferably by positioning it in the transfer position embodied as a fourth position, for example.
  • the at least one separating means 909 holds the at least one partial stack 13 until it arrives at the at least one forwarding means 1000 and only then releases contact with the at least one partial stack 13 at least one transfer means 902 is moved to its forwarding position, which is embodied, for example, as a fourth position.
  • the at least one separating means 909 is preferably designed as at least one wedge-shaped plate, preferably as at least one sword.
  • the at least one separating means 909 preferably has at least one position that is higher in the vertical direction V and at least one position that is lower in the vertical direction V with respect to the base of the at least one handling device 900.
  • the lower position preferably corresponds to that position in which the at least one separating means 909 is designed to separate the at least one partial stack 13 from the at least one stack 12.
  • At least one in the lower one Separating means 909 arranged in the position preferably comes into direct contact with the at least one stack 12.
  • the at least one separating means 909 preferably moves into the at least one stack 12, preferably between two adjacent sheets 02, for example at at least one corner or at least one edge of the stack 12
  • the at least one separating means 909 is then preferably moved into the upper position and / or the stack 12 is moved a little downwards by changing the position of the at least one conveying means 901, preferably by moving the at least one conveying means 901 relative to the at least one Transfer means 902. This relative movement preferably creates a gap.
  • the at least one partial stack 13, more preferably the at least one corner or edge of the at least one partial stack 13, is preferably at least partially raised.
  • the at least one partial stack 13 is preferably raised so that the at least one transfer means 902 can receive the at least one partial stack 13, preferably by means of at least one relative movement of the at least one transfer means 902 with respect to the at least one stack 12.
  • the at least one transfer means 902 is preferably moved from the transfer position embodied as a third position, for example, into the retraction position embodied as a fifth position, for example.
  • the at least one conveyor roller 908 preferably supports the lifting of the at least one partial stack 13 and its positioning on the at least one transfer means 902 through its rotational movement.
  • the at least one separating means 909 preferably releases its contact with the at least one partial stack 13, for example by at least one pivoting movement of the plate.
  • the at least one partial stack 13 is preferably complete, that is to say preferably with all of the edges 07;
  • the at least one transfer means 902 preferably conveys the at least one partial stack 13 to the at least one transfer means 1000, preferably by positioning it in the transfer position embodied as a fourth position, for example.
  • the at least one separating means 909 has at least one gripper in addition to the sword, the at least one separating means 909 holds the at least one partial stack 13 firmly until it arrives at the at least one transfer means 1000 and only then releases contact with the at least one Partial stack 13.
  • the at least one separating means 909 is preferably moved parallel to the movement of the at least one transfer means 902 to its forwarding position, which is embodied, for example, as a fourth position.
  • the at least one separating means 909 is preferably designed as at least one mechanical sensor, preferably a counting disk.
  • the exact number of sheets 02 of the at least one partial stack 13 is thereby preferably determined and / or can be determined.
  • the sheets are counted mechanically by the at least one mechanical sensor, preferably the counting disk.
  • the movable sensor which is preferably designed as the counting disk, moves into the stack 12 until a defined number of sheets 02 is reached.
  • the mechanical sensor inserted between two immediately adjacent sheets 02 then moves up a little and / or the stack 12 is moved down a little by changing the position of the at least one conveyor 901, preferably by moving the at least one conveyor 901 relative to the at least a takeover means 902.
  • This relative movement preferably creates a gap.
  • the at least one partial stack 13, more preferably the at least one edge of the at least one partial stack 13, is preferably at least partially raised.
  • the at least one partial stack 13 is preferably raised so that the at least one transfer means 902 can receive the at least one partial stack 13, preferably by means of at least one relative movement of the at least one transfer means 902 with respect to the at least one stack 12.
  • the at least one transfer means 902 is preferred from, for example, the third position trained takeover position is moved into the retracted position, designed for example as a fifth position.
  • the at least one conveyor roller 908 preferably supports the lifting of the at least one partial stack 13 and its positioning on the at least one transfer means 902 through its rotational movement. If the at least one partial stack 13 is arranged completely above the at least one transfer means 902, the at least one separating means 909 preferably releases its contact with the at least one partial stack 13, for example by at least pulling out the mechanical sensor.
  • the at least one partial stack 13 is now preferably complete, that is to say preferably with all of the edges 07; 08; 09 the sheet 02 on which at least one transfer device 902 is positioned.
  • the at least one transfer means 902 preferably conveys the at least one partial stack 13 to the at least one transfer means 1000, preferably by positioning it in the transfer position embodied as a fourth position, for example.
  • the next machine cycle preferably follows and a further partial stack 13, for example the at least one second partial stack 13, is preferably separated from the at least one stack 12 .
  • the at least one second partial stack 13 is preferably arranged within the at least one stack 12 below the first partial stack 13 and, after the removal of the first partial stack 13, preferably comprises the top sheet 02 of the remaining at least one stack 12.
  • the remaining stack 12 preferably describes the stack 12 on sheet 02, which after at least one separating process, for example separating the at least one partial stack 13, on which at least one conveyor 901 is arranged.
  • a relative movement preferably takes place in the vertical direction V between the at least one conveying means 901 and the at least one transfer means 902, so that the at least one second partial stack 13 can preferably be detected by the at least one separating means 909 and can be picked up by the at least one transfer means 902.
  • the second, preferably upper, position of the at least one conveying means 901 is changed, in particular its distance from the base of the at least one handling device 900 is increased so that the at least one second partial stack 13 can be grasped by the at least one separating means 909 and by the at least a takeover means 902 can be included.
  • the at least one second partial stack 13 is then preferably separated off in the subsequent machine cycle.
  • the at least one partial stack 13 positioned on the at least one forwarding means 1000 is preferably used for the at least one further unit 1200; 1500, preferably the at least one blanking unit 1200 and / or the at least one cutting unit 1500, and / or to the at least one intermediate alignment 1100, which preferably the at least one further unit 1200; 1500 is upstream, transported.
  • the at least one forwarding means 1000, on which the at least one partial stack 13 is positioned, is preferred by the at least one rotary element
  • the at least one transfer device 1000 with the partial stack 13 positioned thereon is rotated and / or pivoted by the at least one rotary element 903.
  • the at least one partial stack 13 is aligned in the transverse direction A by the at least one stop of the at least one transfer means 1000.
  • the at least one forwarding means 1000 preferably moves laterally, preferably in the transverse direction A, against the at least one stop in order to align the partial stack 13.
  • the at least one transfer device 1000 preferably moves laterally again after the alignment, preferably in transverse direction A, back to its starting position.
  • the at least one partial stack 13 is preferably used for the at least one intermediate alignment 1100 and the at least one further unit 1200; 1500 transported and processed and / or processed by them.
  • the at least one partial stack 13 is preferably used after it has been transported by the at least one transfer transport system 800; 900; 1000 preferably aligned in the transport direction T and / or in the transverse direction A and / or the edges 07; 08; 09 of the individual sheets 02 of the at least one partial stack 13 are brought into congruence with one another.
  • the at least one partial stack 13 of sheets 02 in the at least one further unit 1200; 1500 preferably in the at least one blanking unit 1200 and / or in the at least one cutting unit 1500.
  • the at least one further unit 1200; 1500 preferably in the at least one blanking unit 1200 and / or to the at least one cutting unit 1500, which processes sheets 02 of the at least one partial stack 13 together, for example at the same time.
  • the copies 03 of the sheets 02 of the at least one partial stack 13 in the at least one copy separating unit 1200 are preferably from one another and / or from at least one remnant piece 04; 05; 06 separated.
  • the at least one partial stack 13 is cut by the at least one cutting unit 1500 with at least one cut.
  • the at least one cutting unit 1500 preferably separates at least two panels 03 of the at least one sheet 02, preferably the at least two panels 03 in the transport direction T. are arranged one behind the other, from each other.
  • the copies 03 are preferably collected in the at least one copy display 1400 as at least one stack of copies 14.
  • conveyor belt 1400 aggregate, delivery aggregate, multiple delivery

Abstract

L'invention se rapporte à une machine de traitement de feuille (01) comprenant au moins un ensemble de mise en forme (300 ; 400 ; 500 ; 600), le ou les ensembles de mise en forme (300 ; 400 ; 500 ; 600) comprenant au moins un cylindre de forme et au moins un cylindre de contre-pression, au moins une unité de distribution de feuille (700) étant agencée en aval du ou des ensembles de mise en forme (300 ; 400 ; 500 ; 600) dans la direction de transport (T), au moins un ensemble de coupe (1500) ayant au moins un outil de coupe (1501) étant agencé en aval de la ou des unités de distribution de feuille (700) dans la direction de transport (T). L'invention se rapporte également à un procédé permettant de traiter des feuilles (02) dans une machine de traitement de feuille (01).
PCT/EP2021/057388 2020-05-18 2021-03-23 Machine de traitement de feuille et procédé permettant de traiter des feuilles dans une machine de traitement de feuille WO2021233593A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP21715801.3A EP4107104A1 (fr) 2020-05-18 2021-03-23 Machine de traitement de feuille et procédé permettant de traiter des feuilles dans une machine de traitement de feuille

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DE102020113373.1A DE102020113373B3 (de) 2020-05-18 2020-05-18 Bogenbearbeitungsmaschine
DE102020113373.1 2020-05-18

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WO2021233593A1 true WO2021233593A1 (fr) 2021-11-25

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US5483856A (en) * 1992-05-05 1996-01-16 Marquip, Inc. Apparatus and method for slitting corrugated paperboard boxes
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US9033646B2 (en) 2010-04-29 2015-05-19 Kabushiki Kaisha Isowa Cardboard sheet batch division device, cardboard sheet counter ejector, and method for dividing cardboard sheet
WO2017089420A2 (fr) 2015-11-23 2017-06-01 Koenig & Bauer Ag Dispositif et procédé de traitement de supports
DE102018219716B3 (de) 2018-11-16 2019-12-05 Koenig & Bauer Ag Bogenverarbeitende Maschine

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