AT526274A2 - Laser plotter - Google Patents

Abstract

The invention describes a laser plotter (1) for processing a job (16) for cutting, engraving, marking and/or labeling a preferably flat workpiece (3), which has at least one housing (4) with a processing space (5) for positioning a Workpiece (3) forms on a processing table (7), which has at least one radiation source (8) in the form of a laser (9) and a control unit (10) for controlling the carriage (11), which is preferably operated via a belt drive, with a focusing unit arranged movably thereon (12) or laser head (12). The processing table (7) has at least one or more suction units (44) arranged across the width and length of the processing table (7), on which one or more support elements (43) for positioning the workpiece (3) is or are placed, whereby a suction unit (44) is formed from one to several flow channels (45) arranged next to one another, the flow channels (45) on the side area of the processing table (7) with a suction control (47) and in the opposite area of the suction control (47) with a supply air control ( 48) are connected.

Description

15

20

25

30

35

Laser plotter

The invention relates to a laser plotter for processing a job for cutting, engraving, marking and/or labeling a preferably flat workpiece, as described in claim 1.

Flatbed laser systems are known from the prior art, which are equipped with a belt-driven carriage on which a focusing unit or laser head is also adjustable. Flat workpieces such as paper, plates, textiles, etc. are preferably processed using a laser, in particular a laser beam. This means that the exhaust gases or vapors generated during processing

can be suctioned off, suction devices are arranged.

Here, from WO 2021/159158 A1, the applicant is aware of a possibility in which a suction bar is arranged between the carriage and a processing surface of the processing space for suctioning off the exhaust gases or vapors produced during the processing of the workpiece by a laser beam, with several suction openings of the Suction bar to generate a horizontal suction stream are arranged or aligned parallel to the processing surface. The suction bar is L-shaped and connected to the carriage. The disadvantage here is that

There is no optimal suction in the area of the laser head or focusing unit.

Another solution provides that a suction hose is arranged in the area of the focusing unit or laser head, which is moved with the focusing unit or laser head. The disadvantage here is that when using a suction hose on the focusing unit or laser head, the mobility, in particular the travel speed of the focusing unit or laser head with the attached suction hose is restricted. Furthermore, it can happen that with direct

22008AT_T1

15

20

25

30

35

Arrangement of the suction hose on the focusing unit or laser head, the gases and particles with high temperatures can reach directly into the suction hose, so that

an increased risk of fire arises.

Furthermore, from KR 20190024654 A and KR 20160101448 A a processing head or focusing head is known in which a cross flow is generated in order to prevent the smoke or exhaust gases generated on the tool from reaching the interior of the processing head. However, no toxic exhaust gases or smoke are sucked out, but rather the air flowing out on the opposite side is sucked back in so that no smoke or exhaust gases enter through the opening

can.

The object of the invention is to create a laser plotter in which, on the one hand, the above-mentioned disadvantages are avoided and, on the other hand, the suction power is increased

improve.

The task is solved by the invention. Advantageous training and measures are described in the subclaims.

The object of the invention is achieved by a laser plotter, in which the processing table has at least one or more suction units arranged over the width and length of the processing table, on which one or more support elements for positioning the workpiece are placed, with a suction unit consisting of one to several flow channels arranged next to one another is formed, the flow channels being connected to a suction control on the side area of the processing table and to a supply air control in the opposite area of the suction control.

The advantage here is that optimal table suction is created in which individual areas can be controlled and the entire processing table does not necessarily have to be vacuumed. This means that the necessary suction power provided by the suction unit can be reduced.

It is advantageous to have a design in which a power converter can be used in a flow channel, which is adapted for various table inserts or support elements, such as slats, grids, honeycombs. This ensures that on the

22008AT_T1

15

20

25

30

S

A wide variety of table inserts or support elements can be taken into account so that optimal suction is achieved in the active flow channels.

An advantage is a design in which the suction unit is connected to a distribution channel, which is then connected to the suction via suction lines. This ensures that the flow channels are easily connected

Suction unit to the suction is made possible.

A design is advantageous in which each flow channel can be shut off with a flap control and/or in the distribution channel the entire suction unit can be shut off via a flap control. This ensures that the individual flow channels or the suction unit can be activated or deactivated, so that only those flow channels or suction units that are adjacent to the placed workpiece are used. The workpiece can be automatically recognized so that only the adjacent flow channels or the suction units are activated.

It is an advantage in which the supply air control is designed to generate an initial air flow in the individual flow channels, with the control taking place for each individual flow channel or for the entire suction unit. This ensures that an initial flow can be built up as required

can.

An advantage is a design in which the suction units, in particular the flow channels, are aligned transversely, i.e. in the direction of the width of the processing table, or longitudinally. This ensures that the suction control is arranged on the edge, creating easy accessibility. Depending on the machine width, the supply air controls are preferably arranged in the middle area of the processing table, or in the opposite area of the suction control, which has the advantage that they are usually simple in construction and therefore not suitable for maintenance purposes

must be constantly checked.

Finally, the design is advantageous in which the support element for the processing table is designed as slats, grids, honeycombs. This achieves that

22008AT_T1

15

20

25

30

35

This results in a correspondingly advantageous effect on the workpiece to be machined

Support element can be used.

The invention is then described in the form of an exemplary embodiment, with it being pointed out that the invention is not limited to the illustrated and described exemplary embodiment or solution.

Show it:

Fig. 1 is a diagrammatic representation of a laser plotter when processing a workpiece with the safety shield extended, in a simplified, schematic representation;

Fig. 2 is a diagrammatic representation of the laser plotter in the idle state and the laser head or focusing unit is moved, in a simplified, schematic representation;

3 shows a simplified view of the laser head or focusing unit, in a diagrammatic representation;

4 shows a sectional view through the laser head or focusing unit for a detailed representation of a cassette element for connection to a suction bar, in a simplified, schematic representation;

5 shows a further sectional view through the laser head or focusing unit for a detailed representation of the suction element on the laser head or focusing unit, in a simplified, schematic representation;

6 shows a graphical detailed representation of the laser head or focusing unit without a processing table, in a simplified, schematic representation;

7 shows a further graphical detailed representation from below of the laser head or focusing unit without a processing table, in a simplified, schematic representation;

Fig. 8 is a diagrammatic representation of the table suction with partially placed support elements without the housing of the laser plotter, in a simplified, schematic representation;

9 shows a further diagrammatic representation of the table suction according to FIG. 8, in which a section through a flow channel is shown, in a simplified, schematic representation;

22008AT_T1

15

20

25

30

35

& 8th

Fig. 10 is a side view of the table suction, in a simplified, schematic representation;

11 shows a sectional view of the table suction according to AA in FIG. 10, in a simplified, schematic representation,

As an introduction, it should be noted that in the different embodiments, the same parts are provided with the same reference numbers or the same component names, whereby the disclosures contained in the entire description can be transferred analogously to the same parts with the same reference numbers or the same component names. The position information chosen in the description, such as top, bottom, side, etc., is also related to the figure described and should be transferred accordingly to the new position if the position changes. Individual features or combinations of features from the exemplary embodiments shown and described can also represent independent inventive solutions.

1 to 11 show a laser plotter 1, in particular a flatbed laser plotter 1, for processing workpieces 3, the laser plotter 1 preferably for processing a job 2 for cutting, engraving, marking and/or labeling

of the preferably flat workpiece 3 is formed.

The laser plotter 1 has a housing 4 in which all elements, such as drives, electronics, laser source, etc. are integrated, so that the laser plotter 1 can be operated as a stand-alone device. The laser plotter 1 has at least one processing space 5 for positioning the workpiece 3 on a processing surface 6 of a processing table 7. Furthermore, the laser plotter 1 has at least one radiation source 8 in the form of a laser 9 and a control unit 10 for controlling the carriage 11, which is preferably operated via a belt drive, with a laser head 12 or focusing unit 12 arranged movably thereon. The control unit 10 is also responsible for other functions, such as suction, positioning, etc.

For the sake of completeness, it should be noted that the laser plotter 1 is or can be equipped with connections or lines 13 for power supply or for connection to the intranet and/or Internet 14, as shown schematically. It is possible to connect via an interface or cable or wirelessly

22008AT_T1

15

20

25

30

External components 15, such as a laptop 15a or computer, an automatic feed unit, a conveyor belt, a removal robot, etc. can be connected directly or via the intranet and / or Internet 14, in particular a cloud, or via WiFi or Bluetooth, so that data for processing the workpiece 3 from the external components 15, in particular the laptop 15a, can be transferred. When executing the stand-alone device according to FIG. 1, the workpiece 3 is manually inserted and removed by an operator on the processing table 7 in the processing room 5, with text and/or graphics 16 or a job 2, such as this, for example was created on the laptop 15a, is started via an operating unit 17 on the laser plotter 1 or directly from the external component 15, in particular laptop 15a. The detailed description of the function of the laser plotter 1 and the processing of the workpiece 3 are omitted since such laser plotters 1 are already known from the prior art. It is merely pointed out that it is a laser plotter 1 for processing so-called jobs 2 or graphics and/or text 16 for cutting, engraving, marking and/or labeling a preferably flat blank 3, in particular workpiece 3. The laser plotter 1 is preferably used for workpiece thicknesses of up to 50 mm. Paper, panels and textiles are preferably processed as workpieces 3 or blanks 3. What is essential in such laser plotters 1 is that they have a processing space 8, in which a carriage 11 operated with a belt drive with a movable focusing unit 12 or laser head 12 is moved or moved. For this purpose, from the radiation source 8, in particular laser 9, as shown schematically, a laser beam 18 is directed via deflection elements (not shown) to the focusing unit or laser head 12, from which the laser beam 18 is deflected and focused in the direction of the workpiece 3, so that the blank 3 or workpiece 3 is processed according to job 2 or graphic and/or text 16 loaded into the control unit 10. It is advantageous here if the laser plotter 1 is equipped with a safety shield 20, which is activated and extended during a processing process as can be seen in FIG. This ensures that any reflected laser beams 18 can be collected. Since when the different materials are processed by the laser beam 18, exhaust gases or vapors 19, in particular smoke or gases or particles 19, are produced during the evaporation of material, it is necessary that the laser plotter 1 has an appropriate suction system.

7127

22008AT_T1

15

20

25

30

35

According to the invention, it is now provided that a new type of head suction 21 and a table suction 22 are used.

The head suction 21, as can be seen in Figures 3 to 7, consists of a suction element 23, which is attached to the laser head 12 or focusing unit 12, and preferably a suction bar 24, which is coupled to the carriage 11 or is carried along. The suction element 23 is connected to a cassette element 26 via at least one, preferably two, suction lines 25, the cassette element 26 being coupled in motion to the suction bar 24, so that the gases 19 or particles 19 picked up and sucked out by the suction element 23 are transferred to the suction bar 24, i.e. that a suction flow is formed in the suction channel or suction bar 24, this exhaust gas flow acting on the suction element 23 via the suction lines 25, so that the resulting gases 19 or particles 19 are sucked in by the laser beam 18 from the suction element 23 on the laser head 12 and then on the suction bar 24 are transported. It is advantageous if two suction lines 25 are connected to the suction element 23 on opposite sides, since this allows an optimal suction flow to be generated over the entire circumference of the suction element 23.

Furthermore, an air guide disc 27 is preferably attached to the suction element 23 or to the laser head 12, which has an opening 28 in the center for or around a nozzle 29 of the laser head 12, as can be seen in FIG. It is possible that the suction behavior of the suction element 23 is influenced due to the opening 28 of the air guide disc 27, so that different air guide discs 27 with different sized openings 28 are used. As can be seen from FIG. 5, the suction element 23 has a swirl channel 30 which is connected to connections 31 for the suction lines 25. The swirl channel 30 is opened downwards, i.e. in the direction of the air guide disc 27, and has an opening channel 32, the opening channel 32 being coupled to the opening 28 due to the air guide disc 27, so that sucked in air or gases 19 or particles 19 pass over the Opening 28 and the opening channel 32 can flow into the swirl channel 30, i.e. that the suction element 23 on the laser head 12 or focusing unit 12 has a swirl channel 30 for distributing the air on the circumference, which is or are connected to the suction line or lines 25 and thus the gases or particles 19 are passed on to the suction bar 24 via the suction lines 25. The design of the swirl channel 30 ensures that a constant suction flow is generated around the circumference around the nozzle 29

22008AT_T1

15

20

25

30

35

becomes. Here, the connections 31 for the swirl channel 30 are arranged laterally aligned with the swirl channel 30, so that an aligned suction flow from the swirl channel 30 into the

Connections 31 is created.

So that the gases or particles 19 can be conveyed from the suction element 23 into the suction bar 24, the suction line 25 is connected to the cassette element 26. The suction bar 24 is arranged between the processing table 7 and the carriage 11 or preferably in the carriage 11, so that a simple and short, compact connection of the suction element 23 via the suction lines 25 is achieved. For the sake of completeness, it should be mentioned that the suction bar 24 can also have a different position, for example on the carriage 11, so that the suction lines 25 must be designed accordingly. The suction bar 24 is designed in such a way that the suction bar 24 forms a longitudinal channel 33, which has a suction channel 34, as shown schematically in FIG. 2, or a plurality of suction openings (not shown) transversely to the longitudinal direction. Furthermore, the suction channel 34 or the suction openings are closed or covered with a cover tape 35 and only the cassette element 26 is designed to establish a flow connection with the suction openings or suction channel 34. That is, in the cassette element 26, the cover tape 35 is guided over deflection rollers 36 in such a way that the cover tape 35 is lifted or deflected from the suction channel 34 or suction openings, so that an air guide channel is between the suction bar 24 and the lifted cover tape 35 in the cassette element 26 37, which is preferably designed in the flow direction of the suction bar 24, is arranged for the suction lines 25. The air guide duct 37 is connected to the suction line 25, so that the occurring gases or particles 19, as shown schematically in Figure 3, are sucked in via the suction element 23, in particular the opening 28 of the air guide disc 27 and the swirl channel 30, and via the suction line 25 to the air guide duct 37 and from there via the suction duct 24 or suction opening into the longitudinal channel 33 of the suction bar 24.

Here, the suction bar 24 is connected on one side to a suction 38, in particular a suction pump 38, which sucks the air 39 and/or gases 19 or particles 19 out of the lines or channels, so that a negative pressure is created in the lines or channels arises. The suction bar 24 preferably has a supply air control 40, in particular a controllable valve, on the opposite side to the suction 38. The

22008AT_T1

15

20

25

30

35

&

Supply air control 40 serves to ensure that, in particular fresh, air 39 is sucked into the longitudinal channel 33 of the suction bar 24 to generate an initial air flow 41, if this is desired. Here, the supply air control 40, which is designed in the form of a controllable valve, can also prevent the entry of air 39 or allow any amount of air 39 to flow in. The suction 38 creates a negative pressure in the longitudinal channel 33, so that on the one hand air 39 is sucked in via the supply air control 40 and on the other hand air or gases or particles 19 are sucked in via the suction element 23, so that the gases or particles 19 are mixed with the Mix the sucked in air 39 in the longitudinal channel 33 when the supply air control 40 for sucking in air 39 is activated or set. Otherwise, the gases or particles 19 or air 39 are only sucked in via the suction element 23 via the suction 38 when the supply air control 40 is blocked or closed.

Furthermore, the guidance or deflection of the laser beam 18 is indicated schematically in FIG of the carriage 11 runs. This ensures that the laser beam 18 is completely closed and therefore there is no safety risk. Here, the laser head 12 is provided with a cover 12a. Basically, it can be said that the suction bar 24 is attached or integrated on the carriage 11 or in the carriage 11, with the suction channel 34 or the suction openings being formed horizontally to the processing table 7, so that a horizontal suction flow is generated, which flows via the air guide channel 37 and the associated suction lines 25 are guided to the suction element 23. It is advantageous if the air guide disc 27 is arranged or attached to the suction element 23, since this allows precise control of the suction 38 of the gases 19 via the opening 38 of the air guide disc 27 used. During a machining process, the air guide disc 27 is guided to a defined distance from the material surface of the workpiece 7. The distance can be adjusted automatically, for example via a distance measuring device, or manually, for example via a distance measurement device.

Furthermore, for the sake of completeness, it is mentioned that the laser head 12 or focusing unit 12 is attached or connected to a holding device 42 for the carriage 11, with the cassette element 26 being attached to the holding device 42 and / or

22008AT_T1

15

20

25

30

35

10

is attached to the laser head 12, so that by adjusting the laser head 12, the cassette element 26 is also adjusted, i.e. that the cassette element 26 with the laser head 12 is moved along the carriage 11 and due to the deflection rollers 36 in the cassette element 26, the cover tape 35 from the suction channel 34 accordingly is lifted and placed so that the air guide duct 37 can transfer the sucked gases or particles 19 from the suction element 23 into the longitudinal channel 33.

Furthermore, the laser plotter 1 according to the invention comprises a table suction 22, as can be seen in FIGS. 8 to 11, only the essential parts or components of the table suction 22 with the processing table 7 being shown and the housing 4 and other components of the laser plotter 1 not being shown . Basically, it should be mentioned that the processing table 7, in particular the processing surface 6 of the processing table 7, is formed by support elements 43, which are designed, for example, as slats, grids or honeycombs, but due to the simplified representation these over the entire surface without slats, grids or honeycombs -Pattern shown

became.

The table suction 22 has at least one or more suction units 44 arranged over the width and length of the processing table 7, the processing table 7 in the illustrated embodiment being equipped with four suction units 44 which are arranged below the preferably four support elements 43, i.e. that the processing table 7 has at least one or more, in particular four, suction units 44 arranged across the width and length of the processing table, on which one or more, preferably four, support elements 43 for positioning the workpiece 3 is or are placed. A suction unit 44 consists of one or more flow channels 45 arranged next to one another, with the flow channels 45 being separated or limited by limiting elements 46 in the exemplary embodiment shown. A flow channel 45 or the flow channels 45 are connected to a suction control 47 on the side area of the processing table 7. On the opposite side of the flow channels 45, the flow channels 45 of the suction units 44 are connected to a supply air control 48. In the exemplary embodiment shown, the flow channels 45 are only formed up to the middle of the processing table 7, so that two suction units 44 extend across the width of the processing table 7, with the supply air control 48 for both suction units 44 being in the middle of the processing table 7 and the

22008AT_T1

15

20

25

30

35

under 14

Suction control 47 are arranged on the sides of the processing table 7, as can best be seen in FIG. However, since the length of the processing table 7 is very long, two suction units 44 were also arranged in the exemplary embodiment shown, so that the processing table 7 has four suction units 44, in which the suction control 47 is arranged on the edge or on the sides of the processing table 7 and in The supply air control 48 for the four suction units 44 is arranged in the middle of the processing table 7. Of course, a design is also possible in which only one or two or more suction units 44 are arranged.

The suction units 44 are further connected to a distribution channel 49, which is then connected via suction lines 50 to a suction 51, in particular a suction pump 51, as shown schematically in FIG. 8. The suction 51 sucks the air out of the suction lines 50, the distribution channel 49 and the flow channel 45, so that a negative pressure is created in the lines. On the one hand, the workpiece 3 is sucked and held on the processing table 7 and, on the other hand, gases or particles 19 that occur are also sucked out. Preferably, each flow channel 45 is equipped with a flap control 52 so that each flow channel 45 can be activated individually or in groups, i.e. by activating one or more flap controls 52, the flow channel or channels 45 are released, so that a suction flow from the suction 51 the flow channels 45 is generated. It is also possible for the flap control 52 to be arranged in the distribution channel 49, so that all flow channels 45 of a suction unit 44, in particular those which are connected to the distribution channel 49 via the elbow, are activated via the flap control 52

can be.

Furthermore, the supply air control 48 is designed to generate an initial air flow in the individual flow channels 45, with the control taking place for each individual flow channel 45 or for the entire suction unit 44, i.e. that to generate an initial air flow on the opposite side of the suction 51 Flow channels 45 are supplied with air, so that a constant air flow is generated from the supply air control 48 to the suction 51. Here again, each flow channel 45 can be equipped with a flap or valve of the supply air control 48, so that the air can flow into the flow channel 45 by activating the flap or valve. Of course, it is also possible for all flow channels 45

22008AT_T1

15

20

25

30

EZ

a suction unit 44 as an overall system activated by a flap or a valve

can be, so the flow channels 45 cannot be controlled individually.

In order to be able to generate an optimal initial flow in a flow channel 45, it is possible for a power converter 53 to be inserted or used in the flow channel 45, as can be seen in FIGS. 9 and 11. Here, appropriately adapted power converters 53 can be inserted or used for the different support elements 43 or table inserts, such as slats, grids, honeycombs. The power converter 53 is designed in such a way that a channel 54 is created along the flow channel 45 from the supply air control 48 to the suction control 47 to form the initial flow, with suction openings 55 being arranged at certain intervals on the power converter 53 to suck in air or gases 19 or particles 19 to be able to suck from the area of the support element 53. Here, the suction openings 55 are preferably designed like ribs in the direction of the support element 43, whereby the suction openings 55 are covered. The generation of the flows, in particular the initial flow and / or suction flow, is controlled via the suction 51, in particular the suction pump 51, i.e. a negative pressure is built up in the flow channel 45 by the suction 51, so that air and / or gases 19 from the Support elements 43 and/or via the supply air control 48 to form one

Initial flow is sucked in.

According to the invention, the processing table 7 has at least one or more suction units 44 arranged over the width and length of the processing table 7, on which one or more support elements 43 for positioning the workpiece 3 is or are placed, with a suction unit 44 consisting of one to several flow channels 45 arranged next to one another are formed, the flow channels 45 being connected to a suction control 47 on the side region of the processing table 7 and to a supply air control 48 in the opposite region of the suction control 47. This means that a corresponding suction flow can be generated via the flow channels 45, which can be optimally adapted to the placed workpiece 3 or to the current position of the laser head 12 by the design of the flow channels 45, i.e. that, for example, only those flow channels 45 (for example to 50 %) can be activated, which are arranged around the workpiece 3, so that flow channels 45 located further away are not

22008AT_T1

15

20

18

activated and which are 100% activated in the immediate vicinity for laser processing, so that the suction power can be used optimally.

An embodiment is also possible in which the suction bar 24 is replaced by a suction hose (not shown), which is preferably attached and carried along on the laser head 12 or focusing unit 12. For this purpose, the suction element 23 and preferably the air guide disc 27 are in turn attached to the laser head 12 or focusing unit 12, with the suction lines 25 of the suction element 23 now being connected to the suction hose. A cassette element 26 can in turn be arranged that forms the connection of the suction hose to the suction lines 25. The suction hose is designed in such a way that it can be moved back and forth on the carriage 11 with the laser head 12 or the focusing unit 12. The carriage 11 can also move over the entire processing table 7.

For the sake of order, it should finally be pointed out that for a better understanding of the structure of the laser plotter 1 and its components or its components, some of them are not to scale and/or enlarged and/or reduced in size and before

were only shown schematically.

22008AT_T1

Claims (1)

15 20 25 30 35 1. Patent claims: Laser plotter (1) for processing a job (16) for cutting, engraving, marking and/or labeling a preferably flat workpiece (3), which has at least one housing (4) with a processing space (5) for positioning a workpiece (3) on a processing table (7), which has at least one radiation source (8) in the form of a laser (9) and a control unit (10) for controlling the carriage (11), which is preferably operated via a belt drive, with a focusing unit (12) movably arranged thereon or . Laser head (12), characterized in that the processing table (7) has at least one or more suction units (44) arranged over the width and length of the processing table (7), on which one or more support elements (43) for positioning the workpiece (3) is or are placed, wherein a suction unit (44) is formed from one to several flow channels (45) arranged next to one another, the flow channels (45) on the side area of the processing table (7) with a suction control (47) and in the opposite one The area of the suction control (47) is connected to a supply air control (48). . Laser plotter (1) according to claim 16, characterized in that in one A power converter (53) can be used in the flow channel (45), which can be used for various table inserts or support elements (43), such as slats, grids, Honeycomb is adapted. . Laser plotter (1) according to claim 16 or 17, characterized in that Suction unit (44) is connected to a distribution channel (49), which is then connected to the suction (51) via suction lines (50). . Laser plotter (1) according to one of the preceding claims 16 to 18, characterized characterized in that each flow channel (45) each has a flap control (52) and / or the entire suction unit in the distribution channel (49). (44) can be locked via a flap control (52). 15/27 22008AT_T1 . Laser plotter (1) according to one of the preceding claims 16 to 19, characterized characterized in that the supply air control (48) is designed to generate an initial air flow in the individual flow channels (45), the control taking place for each individual flow channel (45) or for the entire suction unit (44). . Laser plotter (1) according to one of the preceding claims 16 to 20, characterized characterized in that the suction units (44), in particular the flow channels (45), are transverse, i.e. in the direction of the width of the processing table (7), or are aligned longitudinally. . Laser plotter (1) according to one of the preceding claims 16 to 21, characterized characterized in that the support element (43) for the processing table (7) is designed as slats, grids, honeycombs. 16/27 22008AT_T1