Patent Application
20220339812
The field of the invention relates to a punching station, a punching method, and apparatus and methods for preparing and/or treating a relief plate precursor, in particular a printing plate precursor.
Washer apparatus for printing plate precursors are known. Typically, a transport bar is used to move a printing plate precursor through such a washer apparatus. To that end an area of the printing plate precursor is provided with a series of through holes in a punching station. Next an operator couples the pre-perforated printing plate precursor to a transport bar having a plurality of pins which can extend in the holes of the printing plate. The transport bar with the coupled plate is then brought by the operator to an inlet side of the washer apparatus. The transport bar leaves the washer apparatus at an outlet side, where it is recuperated by an operator who decouples it from the printing plate precursor. These steps are repeated for the next printing plate precursor to be washed.
Such a washer apparatus is disclosed in US 2018/0217502. A transport strip is attached to the flexographic printing element. To that end, the flexographic printing element is first perforated, and next the pins of the transport strip are arranged in the perforations.
Another example of a washer apparatus is disclosed in PCT application PCT/EP2019/060370 in the name of the applicant.
A disadvantage of the known apparatus and methods is that the plates have to be positioned in the punching station in a well-aligned manner in order to avoid that the plate tears or is damaged, resulting in transport problems requiring an operator intervention.
The object of embodiments of the invention is to provide a punching station for arranging one or more penetration elements in or through an edge portion, typically a portion of the leading edge, of a relief plate precursor (P) or for arranging one or more perforations in an edge portion of a relief plate precursor in an improved manner with less risk of misalignment.
According to a first aspect of the invention, there is provided a punching station for arranging one or more penetration elements in or through an edge portion, typically a portion of the leading edge, of a relief plate precursor (P) or for arranging one or more perforations in an edge portion of a relief plate precursor. The punching station is intended to couple the edge portion directly to a transport bar provided with the one or more penetration elements, or is intended to arrange perforations or holes in the edge portion, whereupon a transport bar may be coupled to the perforated edge portion in a later step. The punching station comprises a punching means, an abutment means, a detection means, and a signalling means. The punching means comprises one or more penetration elements or perforating elements and is configured for arranging the one or more penetration elements or perforating elements through or in an edge portion of the relief plate precursor. The abutment means is aligned with the punching means and configured for forming an abutment for the edge of the relief plate precursor. The detection means is configured to detect at two or more locations along the abutment means whether the edge portion of the relief plate precursor is correctly positioned against the abutment means. The signalling means is configured to communicate a signal in function of the detection by the detection means.
By detecting at two or more locations along the abutment means whether the edge portion of the relief plate precursor is correctly positioned against the abutment means, it can be determined whether the entire edge portion is correctly positioned in a position ready for punching. By further including signalling means to communicate a signal based on the detection of the detection means, this signal can be used to decide whether or not to operate the punching means. The punching means may be configured to be manually operated or to be automatically operated. For example, the punching means may be automatically activated to perform a punching action when the signal indicates that the positioning of the edge portion is correct. By ensuring that the punching is correct it can be ensured that the relief plate precursor is attached correctly to a transport bar, so that tearing of the relief plate precursor or other damage of the relief plate precursor is avoided. Also, when the transport bar with the coupled relief plate precursor is transported through a machine for treatment of the precursor, a correct punching contributes to a good alignment of relief plate precursor whilst being transported through the machine.
Preferably, the signalling means is configured to communicate the signal to the punching means. For example, the punching means is configured such that the punching action is triggered automatically upon receipt of a signal from the signalling means indicating a correct positioning of the edge portion of the relief plate precursor. In another example, the punching means comprises a locking mechanism configured to allow punching action when the locking mechanism is in an unlocked state and the prevent a punching action when the locking mechanism is in an locked state. The punching means may then be configured such that the locking mechanism is put from a locked state into an unlocked state when receiving a signal from the signalling means indicating a correct positioning of the edge portion of the relief plate precursor, and back in a locked state after the punching action has been performed.
According to an exemplary embodiment, the punching station further comprises a signaling interface or an operator interface, and the signaling means is configured to communicate the signal to the signaling interface and/or operator interface. The signaling or operator interface may then be configured to generate an output based on said signal which can be sensed by an operator. The output may be e.g. a visual output or an audio output. For example, the signalling interface may include a light or a screen for indicating, e.g. with a colour or message or symbol, whether the edge portion of a relief plate precursor is correctly positioned. For example, a green light may indicate a correct positioning and a red light may indicate an incorrect positioning. Such an embodiment may be useful e.g. when the punching is done manually as it indicates to the operator whether the relief plate precursor is correctly positioned.
According to an exemplary embodiment, the abutment means comprises at least a first and a second abutment part which is movably arranged, such that when the edge portion is correctly positioned at the first location the first abutment part is in a first position and when it is not correctly positioned it is in a second position, and such that when the edge portion is correctly positioned at the second location the second abutment part is in a first position and when it is not correctly positioned it is in a second position. For example, the first and the second abutment part may be pivotable between the first and the second position. The detections means may then comprise a first and a second detector configured to detect a position of the first and the second abutment part, respectively.
The detection means may comprise any one of the following: an optical detection means, a proximity detection means, a pressure detection means, an electrical detection means, a magnetic detection means, a mechanical detection means, a ferrous/non-ferrous metal detection means, or a combination thereof. Examples of suitable detection means include a proximity switch, a photo-sensor, a mechanical switch, a magnetic switch, a camera, etc. In exemplary embodiments the detections means comprise a first and a second detector to perform a detection at the first and the second location, respectively. However, certain detection means such as a camera could look both at the first and the second location, either sequentially or simultaneously.
According to an exemplary embodiment, the abutment means comprises a plurality of alignment pins arranged in a row such that they can extend along the edge portion of the relief plate precursor. The advantage of using pins is that they can easily extend through a transport bar by providing the transport bar with a corresponding plurality of recesses or holes or channels. However, the abutment means may also comprise a wall portion. In such an embodiment the transport bar could be provided with a slit through which the wall portion may extend. One or more first pins of the plurality of pins may be associated with the first abutment part, and one or more second pins of the plurality of pins may be associated with the second abutment part. For example, the first pins may be fixed in a first pivotable carrier of the first abutment part, and the second pins may be fixed in a second pivotable carrier of the second abutment part. In order to limit and guide the movement of the first and second abutment parts, the alignment pins may extend through holes of a fixed guidance plate.
Preferably, the penetration elements are arranged on a transport bar, and the punching station is configured to receive the transport bar in a position aligned with the abutment means.
According to an exemplary embodiment, the punching means comprises a drive means configured to arrange the one or more penetration elements or perforating elements through or in an edge portion of the relief plate precursor. The drive means may be e.g. a hammer arranged movably such that it can be engaged against the edge portion of the relief plate precursor in order to arrange the one or more penetration elements or perforating elements through or in an edge portion of the relief plate precursor. The hammer may be provided with one or more holes corresponding with the one or more penetration elements or perforation elements. The transport bar may be arranged to be positioned with the one or more penetration elements on one side of the edge portion, and the hammer may be arranged to engage the other side of the edge portion.
More preferably, each penetration element has a sharp tip or edge capable of causing a penetrating action in the material of the relief plate precursor, and the punching station is configured to cause a penetration by the at least one penetration element at least partially into or through an unperforated area near an edge of a relief plate precursor. In that manner, the penetration elements are pushed in the material of the relief plate precursor without generating waste. The penetration elements can be made from any hard material which can penetrate into or through the plate precursor material. It can be made from metals or alloys, ceramics, polymers, glass, or combinations thereof. Preferably they are made from metals or alloys. Each penetration element comprises a penetration portion having a length, seen in a penetration direction, between 1 mm and 20 mm. Preferably, the penetration portion has a maximum dimension, seen in a direction perpendicular on the penetration direction, which is smaller than 5 mm, more preferably smaller than 3 mm. For example, when the penetration portion has a round cross section, the diameter is preferably smaller than 5 mm, more preferably smaller than 3 mm.
According to an exemplary embodiment, the abutment means is arranged in a movable manner, such that it can be moved away when the punching means is activated. Alternatively, the hammer may be provided with holes for receiving a portion of the abutment means.
According to an exemplary embodiment, the first and the second location along the abutment means correspond with a location of a left and right side of the middle of the edge portion of the relief plate precursor, respectively. In that manner an accurate detection can be performed.
According to another aspect of the invention, there is provided an apparatus for treating a relief plate precursor comprising a transport system, a punching station according to any one of the embodiments described above, and a treatment compartment. The transport system is provided with at least one, preferably at least two transport bars. The punching station is configured for coupling an edge of a relief plate precursor to a transport bar of the at least one transport bar. The treatment compartment is configured for treating the relief plate precursor.
Preferably, the transport system is configured for transporting the relief plate precursor such that a leading edge of the relief plate precursor touches the abutment means, and such that the signalling means triggers the punching means.
Optionally, the apparatus further comprises a decoupling station configured to decouple the relief plate precursor from the transport bar, wherein the transport system is configured to move the transport bar from an outlet side of the treatment compartment through a discharge zone to the decoupling station such that the relief plate precursor can be discharged in the discharge zone after being decoupled from the transport bar.
Optionally, the apparatus further comprises a removal means configured to remove a treated relief plate precursor after being decoupled from the transport bar in the decoupling station.
Optionally, the transport system comprises a forward transport mechanism configured to transport the transport bar with the coupled relief plate precursor at least from an inlet side to an outlet side of the treatment compartment, and from the outlet side to the decoupling station.
Optionally, the transport system further comprises a bar coupling means configured to couple the transport bar with coupled relief plate precursor to the forward transport mechanism.
Optionally, the transport system comprises a backward transport mechanism configured to transport the transport bar from the decoupling station back to the coupling station.
Optionally, the apparatus further comprises a control unit configured to control the transport system, such that the at least two transport bars move simultaneously through the apparatus, wherein optionally the signalling means may be part of the control unit.
The length of the transport bar may be from 100 mm to 10000 mm.
The treatment compartment may comprise any one of the following: flat or cylindrical brushes, pumps, spraying means, sensors, filters, rinsing means, motors, gears, heating means, cooling means, rollers, belts, webs, or combinations thereof.
The transport system may comprise any one of the following: one or more belts, one or more chains, one or more lead screws, a linear motor, magnetic means, electromagnetic means, clamping means, vacuum means, or combinations thereof.
According to yet another aspect of the invention, there is provided a punching method for arranging one or more penetration elements in or through an edge portion of a relief plate precursor or for arranging one or more perforations in an edge portion of a relief plate precursor, said relief plate precursor preferably comprising a substrate layer and at least one photosensitive layer (optionally an integral mask layer), said punching method being performed in a punching station and comprising the steps of:
According to an exemplary embodiment, the one or more penetration elements are attached to a transport bar, and the method further comprises the steps of
According to an exemplary embodiment, the transport bar is moved in a closed loop from the punching station through the treatment zone to the decoupling station and back to the coupling station.
According to an exemplary embodiment, the at least two transport bars are being transported simultaneously in the treatment apparatus.
According to an exemplary embodiment, the transport speed through the treatment compartment is different form the transport speed of the transport bar moving back to the coupling station.
According to an exemplary embodiment, the treatment in the treatment compartment is selected from the group comprising washing, brushing, rinsing, spraying, drying, irradiating, developing, heating, cooling, removing of material, treating with gases or liquids, sanding, cutting, treating with electromagnetic waves, and combinations thereof.
According to an exemplary embodiment, the treatment in the treatment compartment is a heat treatment resulting in a liquefied part of relief plate precursor followed by contacting the liquefied part with a moving acceptor material, such as a web, a non woven material, or a foil to which molten material adheres, and continuously removing the liquefied part with the acceptor material.
According to an exemplary embodiment, the method further comprises the step of performing a post-treatment on the relief plate precursor, said post-treatment being selected from the group comprising washing, brushing, rinsing, spraying, drying, irradiating, developing, heating, cooling, removing of material, treating with gases or liquids, sanding, cutting, treating with electromagnetic waves and combinations thereof.
According to an exemplary embodiment, the method further comprises the step of performing a pre-treatment on the relief plate precursor, said pre-treatment being selected from the group comprising: cutting, ablation, exposure to electromagnetic radiation, and combinations thereof.
The accompanying drawings are used to illustrate presently preferred non limiting exemplary embodiments of the apparatus and method of the present invention. The above and other advantages of the features and objects of the invention will become more apparent and the invention will be better understood from the following detailed description when read in conjunction with the accompanying drawings, in which:
The apparatus 1000 comprises a transport system 210, 220, 230 with at least one, preferably at least two, and even more preferably at least three transport bars 100 intended to be coupled to a relief plate precursor P. For example, four transport bars 100 may be provided to the transport system 210, 220, 230 as illustrated in
The apparatus 1000 comprises a punching station 300 configured for coupling a relief plate precursor P to a transport bar 100, a treatment compartment 400 configured for treating the relief plate precursor whilst the transport bar 100 to which the relief plate precursor P is coupled, is moved through the treatment compartment 400, and a plate decoupling station 500 configured for decoupling the treated relief plate precursor P from the transport bar 100. The transport system 210, 220, 230 is configured to automatically move each transport bar 100, after being coupled to a relief plate precursor P in the punching station 300, from the punching station 300 through the treatment station 400 to the plate decoupling station 500, and, after being decoupled from a treated relief plate precursor P, from the plate decoupling station 500 back to the punching station 300, such that the transport bar 100 moves in a closed loop through the apparatus 1000. In the illustrated example of
In a preferred embodiment, each transport bar 100 is provided with a plurality of penetration elements 110 (here in the form of pins or rods), and the punching station 300 is configured to engage the plurality of penetration elements 110 in an area near the leading edge 3 of the relief plate precursor P. In
The punching station 300 is configured for arranging the plurality of penetration elements 110 in an edge portion E of the relief plate precursor P. The punching station 300 comprises a punching means 10 comprising the plurality of penetration elements 110 and a drive means such as a hammer (not shown) configured to arrange one or more penetration elements 110 in an edge portion of the relief plate precursor P. The punching station 300 further comprises an abutment means 20 aligned with the punching means 10 and configured for forming an abutment for the edge 3 of the relief plate precursor P. The punching station 300 also comprises a detection means 30 configured to detect at two or more locations along the abutment means 20 whether the edge portion E of the relief plate precursor is correctly positioned against the abutment means 20, and a signaling means 40 configured to communicate a signal in function of the detection by the detection means 30. Preferably, the signaling means 40 is configured to communicate the signal to the punching means 10, e.g. in order to automatically trigger the punching means 10 and in particular the drive means of the punching means 10 so that one or more penetration elements 110 are arranged in an edge portion E of the relief plate precursor P.
The treatment compartment 400 has an inlet side 410 and an outlet side 420. A transport bar 100 with a coupled relief plate precursor P is moved through the treatment compartment 400 from the inlet side 410 to the outlet side 420, wherein the transport bar 100 moves in the forward transport direction Tf. Between the outlet side 420 of the treatment compartment 400 and the plate decoupling station 500, there is provided a plate discharge zone 600. A relief plate precursor P is pulled by the transport system fully out of the treatment compartment 400 in the plate discharge zone 600 before being decoupled from the transport bar 100 in the decoupling station 500. In that way, when the relief plate precursor P is decoupled from the transport bar 100, the relief plate precursor P can be discharged in the plate discharge zone 600. At the bottom of the plate discharge zone 600 there may be provided a removal means configured to remove a treated relief plate precursor P after being decoupled from the transport bar 100 in the plate decoupling station 500. In the illustrated embodiment, the removal means 700 is a trolley configured for receiving the treated relief plate precursor P in the plate discharge zone 600, and for being moved out of the plate discharge zone 600, such that it can be easily transported away of the plate discharge zone. For example, if the apparatus 1000 is a washer, an operator may transport the washed relief plate precursor P to a dryer in order to dry the washed relief plate precursor. In other non illustrated embodiments, the removal means 700 may be a carrier, a robot, a moving belt, at least one rotating drum, etc. Also such devices can be configured to move a treated relief plate precursor P out of the plate discharge zone 600 after being decoupled in the plate decoupling station 500.
In the embodiment of
The first forward transport mechanism 210 may comprise a first lead screw, and the first end 101 of the transport bar 100 may be provided with a first coupling portion 121 configured to be coupled to the first lead screw 210, see
The transport system further comprises a backward transport mechanism 230 configured to transport the transport bar 100 from the plate decoupling station 500 back to the punching station 300. In the illustrated embodiment of
In
As illustrated in
As shown in
The abutment means 20 comprises a plurality of alignment pins 25 arranged in a row such that they can extend along the edge portion E of the relief plate precursor. Each abutment part 20a, 20b may comprise one or more alignment pins 25. In the example of
The detections means 30 comprises a first and a second detector 30a, 30b configured to detect a position of the first and the second abutment part 20a, 20b, respectively. The detection means may comprise any one of the following: an optical detection means, a pressure detection means, an electrical detection means, a mechanical detection means, or a combination thereof. In the illustrated example the first and second detectors 30a, 30b may be e.g. proximity sensors.
The penetration elements 110 are arranged on a transport bar 100, and the punching station 300 is configured to receive the transport bar 100 in a position aligned with the abutment means 20, see
Preferably, the first and the second location along the abutment means 20 correspond with a location of a left and right side of the middle of the edge portion of the relief plate precursor, respectively. In the illustrated example this is realised by having the abutment parts 20a, 20b on a left and right side of the middle, cf.
The transport bar 100 is provided with a first coupling portion 121 and a second coupling portion 122 at the first end 101 and the second end 102. In this case the coupling portion 121 is configured with coupling means to be used in combination with a lead screw.
It is noted that according to another exemplary embodiment, the apparatus 1000 of
Now a description of an exemplary embodiment of the punching station 300 and the steps taking place in the punching station 300 will be described with reference to
It is noted that other transport bars and hammer tools exist in which the invention is applicable. For example
It is noted that the shape of the penetration elements 110 may vary and the shape may be e.g. any one of the following: a tube, a blade, a needle, or a combinations thereof. Preferably, each penetration element 110 comprises a penetration portion 112 (see
As illustrated in
A relief plate precursor generally comprises a support layer made of a first material and an additional layer made of a second material which is different from said first material. The support layer may be a flexible metal, a natural or artificial polymer, paper or combinations thereof. Preferably the support layer is a flexible metal or polymer film or sheet. In case of a flexible metal, the support layer could comprise a thin film, a sieve like structure, a mesh like structure, a woven or non-woven structure or a combination thereof. Steel, copper, nickel or aluminium sheets are preferred and may be about 50 to 1000 μm thick. In case of a polymer film, the film is dimensionally stable but bendable and may be made for example from polyalkylenes, polyesters, polyethylene terephthalate, polybutylene terephthalate, polyamides and polycarbonates, polymers reinforced with woven, nonwoven or layered fibres (e.g. glass fibres, Carbon fibres, polymer fibres) or combinations thereof. Preferably polyethylene and polyester foils are used and their thickness may be in the range of about 100 to 300 μm, preferably in the range of 100 to 200 μm. A relief plate precursor may carry an additional layer. For example, the additional layer may be any one of the following: a direct engravable layer (e.g. by laser), a solvent or water developable layer, a thermally developable layer, a photosensitive layer, a combination of a photosensitive layer and a mask layer. Optionally there may be provided one or more further additional layers on top of additional layer. Such one or more further additional layers may comprise a cover layer at the top of all other layers which is removed before the imageable layer is imaged. The one or more additional layers may comprise a relief layer, and an anti-halation layer between the support layer and the relief layer or at a side of the support layer which is opposite of the relief layer. The one or more additional layers may comprise a relief layer, an imageable layer, and one or more barrier layers between the relief layer and the imageable layer which prevent diffusion of oxygen. Between the different layers described above one or more adhesion layers may be located which ensure proper adhesion of the different layers.
Whilst the principles of the invention have been set out above in connection with specific embodiments, it is to be understood that this description is merely made by way of example and not as a limitation of the scope of protection which is determined by the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2023988 | Oct 2019 | NL | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2020/078203 | 10/8/2020 | WO |
