This application claims the priority, under 35 U.S.C. §119, of German Patent Application DE 10 2010 054 706.9, filed Dec. 16, 2010; the prior application is herewith incorporated by reference in its entirety.
The present invention relates to a method and a device for coating printing material using a web of foil that contacts the printing material at least temporarily and is brought together with the printing material after the latter has been coated with a functional coating such as glue or a varnish.
Many methods and devices for enhancing printed products have become known in the prior art. The enhancement process may be carried out within a printing press (i.e. in-line) or outside the printing press (i.e. off-line). The enhancement measures may be taken before or after the printing operation.
Two known finishing operations are cold-foil coating of a printing material and the creation of structures such as holograms or diffractive structures on the surface of the printing material.
Cold-foil coating can be performed within a sheet-fed machine, in particular in an in-line process in a sheet-fed printing press. For that purpose, a printing material that is yet unprinted or one that has already been printed receives a layer of glue, in particular in areas depending on an image to be applied, in a first printing unit. The sheet that has received the glue may then be fed to a transfer unit in which it is passed through a transfer nip together with a web of foil. In cold-foil stamping, the web of foil is generally formed of a carrier layer and a transfer layer, which is detached from the transfer foil and transferred to the printing material in the transfer nip. The printing material is guided through the transfer nip on an impression cylinder for that purpose. If the printing material is a sheet, it is held on the impression cylinder. The transfer nip is formed by a transfer cylinder and the impression cylinder. Foil-guiding elements guide the transfer foil, which is formed of the transfer layer and the carrier layer, through the transfer nip together with the sheet. At least in the transfer nip, the web of foil is guided together with the sheet on the impression cylinder, in that case in functional terms by the transfer cylinder. The transfer layer is detached from the carrier and is transferred to the printing material under pressure in the areas that are coated with glue on the printing material. The printing material that has been coated in that way can then undergo further printing operations in downstream printing units of the printing press.
In another known enhancement process using a foil, a structure, in particular a hologram or a diffractive structure, is applied to the surface of the printing material. For that purpose, a functional coating, in particular a layer of varnish, is applied to the printing material in a first printing unit or varnishing unit. The printing material that has received the varnish is then fed to a finishing unit provided in the printing press. If the printing material is a sheet, it is guided on the impression cylinder of the finishing unit and potentially held by grippers. In that process too, a foil, in that case in particular a hologram foil, is guided along the impression cylinder at least temporarily together with the printing material. The web of foil has a side that faces the printing material and has a fine structure that becomes submerged into the layer of varnish that has not yet polymerized on the printing material and may thus create an embossing in the layer of varnish on the printing material without affecting the printing material itself. Thus, a microstructure may be embossed into the varnish to provide a glossy, holographic or hologram-like visual effect to the human eye. That process of embossing a non-polymerized layer of varnish as far as possible without embossing the printing material that lies underneath, is also known as UV casting. In general, the varnish is hardened while it is still in contact with the foil. The hardening is achieved by using UV varnish and a UV drier above the web of foil. For that purpose, the web of foil needs to be transparent and must be guided on the impression cylinder together with the printing material over a longer distance to be able to dry the varnish using a UV drier while the foil is being pressed onto the varnish. A suitable device for that process is disclosed in German Published Patent Application DE 10 2006 021 069 A1, corresponding to U.S. Patent Application Publication No. US 2006/0254445.
In the case of cold-foil transfer, there are likewise a device and a method in which the foil wraps around the impression cylinder over a longer distance and at a wrap angle α relative to the impression cylinder, to be guided together with the sheet on the impression cylinder during an extended period of time. German Published Patent Application DE 10 2009 002 810 A1, corresponding to International Publication No. WO 2009/138335 A1, discloses the use of a cylinder that forms a pressure nip as a foil-guiding element and provides another guide element, which is substantially engaged with the impression cylinder, at a distance from the first cylinder to guide the foil over the impression cylinder. A drier for drying the glue is provided in the region between the two guide cylinders.
In both devices that guide the foil along the impression cylinder to create an embossing in the layer of varnish on one hand or to deposit the transfer foil on the printing material on the other hand, a provision may be made for at least one of the two guide rollers to be disengaged from the surface of the impression cylinder in a substantially vertical direction. That may be useful, for instance, to avoid a collision with grippers for guiding the sheet on the impression cylinder.
It is possible to avoid the grippers by using the known devices. However, those devices require complex configurations that may influence the tension of the foil. Moreover, the devices described above are static in terms of the detachment behavior of the foil from the printing material or sheet. They do not take into consideration that different foils, different printing materials, or different types of varnish or glue may require different detachment behavior.
It is accordingly an object of the invention to provide a method and a device for changing the condition of a web of foil, which overcome the hereinafore-mentioned disadvantages and at least counteract the difficulties of the heretofore-known methods and devices of this general type.
With the foregoing and other objects in view there is provided, in accordance with the invention, a method for coating a printing material using a web of foil. The method comprises applying a coating of glue, varnish or another functional layer to the printing material, feeding a web of foil from a foil supply to an area of engagement using foil-guiding elements, engaging the web of foil temporarily with the printing material in the area of engagement while guiding the printing material on a counter-surface, preferably of an impression cylinder, changing a path of the web of foil relative to the counter-surface at least from a first condition to a second condition using the foil-guiding elements to guide the web of foil, and implementing the change of condition by changing at least one condition of at least one of the foil-guiding elements to switch the web of foil from a first to a second condition, the change of condition of the at least one foil-guiding element being different from a disengagement of the at least one foil-guiding element from the counter-surface.
With the objects of the invention in view, there is also provided a device for coating a printing material. The device comprises at least one coating unit for coating the printing material with a functional substrate, an area of engagement, disposed downstream of the at least one coating unit in a transport direction of the printing material, for temporarily engaging a web of foil with the printing material, a counter-surface, preferably of an impression cylinder, for guiding the printing material during engagement with the web of foil, a guide device including foil-guiding elements for guiding the web of foil in vicinity of the counter-surface, and a switching element associated with at least one of the foil-guiding elements and configured to be switched for causing a change of condition of the at least one foil-guiding element, the change of condition being different than a disengagement of the at least one foil-guiding element from the counter-surface, and the switching of the switching element causing the web of foil to change from a first condition to a second condition.
Therefore, in accordance with the invention, the method includes the steps of applying glue or a layer of varnish to a printing material and guiding the printing material and a web of foil in an area of engagement on a counter-surface, which is preferably an impression cylinder. Alternatively, the printing material may be coated using other functional material to create a functional layer. The other functional material may, for instance, be a layer of ink or a layer of a conductive material or a primer or the like.
The aforementioned counter-surface is preferably formed by an impression cylinder, and the foil and the printing material are jointly fed to a first nip. The first nip is formed by a first guide roller and the impression cylinder. The first guide roller may, in particular, be a blanket cylinder of a printing unit or an imaging cylinder of a coating unit of a printing press. In order to provide a larger area of engagement, a second foil-guiding element in the form of a deflection roller is provided. This deflection roller is engaged with the impression cylinder at a location downstream of the first nip. The sheet itself is guided by a gripper on the impression cylinder. Due to the two guide rollers provided in the circumferential region of the impression cylinder the foil is guided around the impression cylinder together with the sheet at a defined angle of engagement.
In order to harden the glue or to polymerize a varnish, a UV drier may be provided, in particular between the two guide rollers.
In order to feed the web of foil to the area of engagement, foil-guiding elements are provided to guide the web of foil itself to the area of engagement from a foil supply, for instance a foil-supply reel.
In addition, a provision is made to change the path of the web of foil relative to the respective counter-surface or impression cylinder, from a first condition to a second condition, preferably in the vicinity of the area of engagement. This may be necessary, for example, to disengage the web of foil from the impression cylinder when the grippers pass underneath the area of engagement. Preferably, a change of condition alternatively or additionally results in a different angle of detachment of the web of foil from the printing material, so as to be able to control the detachment behavior of the varnish from a foil, in particular a hologram foil, or of a carrier foil from a transfer layer on the printing material.
This change of condition of the web of foil may, in particular, be caused by at least one of the foil-guiding elements for guiding the web of foil. For this purpose, a change of condition of the foil-guiding element(s), which is different than a disengagement of the foil-guiding element from the counter-surface, is envisaged. As a result of such different changes of condition, it is in particular possible to implement different foil paths to influence the detachment behavior of the foil from the underlying functional layer.
In accordance with the invention, the device includes guide devices having foil-guiding elements for guiding the web of foil at least in the region of the counter-surface. In addition, a suitable coating unit for coating the printing material with a functional substance such as varnish or glue is provided upstream of the area of engagement as viewed in the direction of transport of the printing material. This coating unit may be a self-contained inking or varnishing unit of a printing press. Moreover, at least one foil-guiding element is assigned a switching member for causing corresponding changes of condition of the foil-guiding element which are different from a disengagement of the foil-guiding element from the counter-surface. In order to achieve a corresponding change of condition of the foil-guiding element for the purpose of changing the web of foil from a first condition to a second condition, the switching member is switchable in a manner corresponding to the change of condition of the foil-guiding element.
The changes of condition of the foil-guiding elements, which are different from a disengagement of the foil-guiding element from the counter-surface, may be one change of condition out of a group including pivoting about an interior or exterior geometrical pivot axis and a change of a pneumatic condition.
Thus, in accordance with one embodiment of the device of the invention, a change of the pneumatic condition may be caused by a pneumatically activatable guide element. In accordance with a further development of the device of the invention, this guide element may include suction-air openings and/or compressed-air openings to receive or expel air. If the web of foil is to be disengaged from the respective counter-surface or impression cylinder, the detachment of the web of foil from the counter-surface may at least be assisted by providing suction air to the suction openings of the pneumatically activatable guide element. An engagement of the web of foil with the impression cylinder, in particular to generate a predefined force, may additionally or alternatively be assisted by the provision of compressed air that is pressed through the compressed-air openings of the pneumatically activatable guide element.
In accordance with an additional or alternative embodiment of the invention, the change of condition of the foil may reside in a change of the angle of detachment of the foil relative to the counter-surface, i.e. the impression cylinder, or relative to the printing material itself. In accordance with the method of the invention, this change of condition may be achieved by changing the surface area of the foil-guiding element that is in interaction with the counter-surface in the region of the detachment of the web of foil from the counter-surface. This may be attained on one hand by pivoting the foil-guiding element, which is preferably a guide roller, about an external geometrical pivot axis to substantially exclusively achieve a circumferential adjustment of the foil-guiding element, i.e. the guide roller. This pivoting movement to a different circumferential position causes the foil-guiding area about the impression cylinder to change and an angle of detachment of the foil to vary at least if there is a stationary second guide roller or guide element outside the area of engagement. For this purpose, the geometrical pivot axis is preferably located inside the impression cylinder.
In accordance with an alternative embodiment of the device of the invention, the foil-guiding element has an internal geometrical pivot axis about which the guide element is pivotable. In this case, the guide-element itself has a surface profile that provides different effective surfaces for guidingly interacting with the foil as a function of the pivoting condition. The path of the foil in the region of the location of detachment of the foil from the printing material differs in accordance with the different surface areas that interact with the foil. Thus, a different angle of detachment of the foil can be achieved as a function of the pivoting condition.
In order to reduce friction between the foil and the foil-guiding elements, holes can be provided in the adjustable and in the profiled foil-guiding elements. Air may exit through these holes to form an air cushion between the web of foil and the foil-guiding element. These holes may, in particular, have a microstructure to provide an air cushion that is as uniform as possible.
A suitable device for pivoting the foil-guiding element about an external geometrical pivot axis is provided to ensure radial pivotability of the foil-guiding element. In this context, a provision is made for the radial distance between the guide element and the counter-surface to remain substantially unchanged.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a method and a device for changing the condition of a web of foil, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now in detail to the figures of the drawings, which disclose exemplary embodiments of the method and device that do not limit the invention in any way and may provide additional features, and first, particularly, to
A sheet 4 is guided into the application unit 2 from a (non-illustrated) feeder and potentially further printing units 18. The application unit 2 includes a supply of glue 5, from which glue is supplied to an inking unit 3 to be applied to a plate cylinder 6 carrying a printing plate. The glue is applied to a blanket cylinder 7 by the plate cylinder in accordance with the image on the printing plate and is then applied to the sheet 4 in an indirect printing process. The sheet 4 is held on an impression cylinder 8 by grippers. In an alternative embodiment, a varnishing unit may be used to transfer the glue. The glue may be applied either in areas as defined by the image, for instance using a varnishing blanket that has cut-outs, or across the entire area in a varnishing unit.
Having passed the application unit 2 and received a glue image, the sheet 4 continues to be guided through the printing press 1 in a direction of transport 9. The sheet 4 passes a transfer nip 13 in the transfer unit 10. The sheet 4 is guided through the transfer nip 13 together with a cold foil 11. In the process, a transfer layer of the transfer foil 11 is transferred, potentially under the influence of force, to the areas of the sheet 4 that have received the glue.
For this purpose, guide elements 15, in this embodiment constructed as rollers, guide the cold foil 11 from a supply reel 14 into the transfer nip 13, which is formed by an impression cylinder 8 and a transfer cylinder 12 that is a blanket cylinder of a printing unit of the printing press 1. Once the cold foil 11 and the sheet 4 have passed the transfer nip 13 together, a foil-guiding element 15 and a second foil-guiding element 19 guide the transfer foil 11, which still carries areas of the transfer layer that have not been transferred, to a collecting reel 16. The sheet 4, which has now received the transfer layer, continues to be moved through the printing press to the downstream printing unit 18 in the direction of transport 9. It may pass through further printing units or devices for the further processing of printed products in the printing press 1.
In order to obtain a firm bonding between the transfer layer of the transfer foil 11 and the sheet 4, an area of engagement 50 is provided on the impression cylinder 8. This area of engagement 50 directly follows the transfer nip 13 and extends across an area on the surface of the impression cylinder 8 up to the second foil-guiding element 19, which detaches the foil from the sheet 4 to guide it to the collecting reel over the foil-guiding elements 15. The area of engagement 50 is assigned a UV drier 17, which acts on the glue through the cold foil 11 to activate and dry the glue that has been applied to the sheet. In the illustrated embodiment, the glue that is being used is a UV glue that can be dried by the UV drier 17. As an alternative, the glue may be a type of glue that is activated or dried, for instance polymerized, in the infrared range or other ranges of the electromagnetic spectrum. If other types of glue are used, different types of driers may be provided.
As described above with reference to
In contrast to the guide system for guiding the cold foil 11 in
In the hologram unit that is constructed as shown in
If the sheet 4 is held on the impression cylinder 8 by non-illustrated grippers, parts of the grippers may protrude beyond the surface of the impression cylinder 8 and may thus come into contact with the hologram foil 51 and potentially damage the surface of the latter. Since the hologram foil 51 may potentially be reused, in an alternative embodiment, the second and third foil-guiding elements 19, 20 may be disposed or mounted in such a way as to be able to be disengaged from the impression cylinder 8 to allow the grippers to pass instead of being disposed in a fixed radial position relative to the impression cylinder 8. The path of the hologram foil 51 and the position of the second and third foil-guiding elements 19, 20 is illustrated in dashed lines for this embodiment. In general, the foil-guiding elements 19 and 20 may also be engaged and disengaged in a corresponding way to place the hologram or cold-foil unit out of operation. If this is the case, the foil-guiding elements 19, 20 are moved into a stand-by position.
The embodiments shown in
In addition to the options shown herein of pivoting the second foil-guiding element 19 about an internal or an external geometrical pivot axis, the second foil-guiding element 19 may be disposed or mounted in such a way as to able to be disengaged as described with reference to
A change of condition of the foil 11, 51, in particular to disengage the foil 11, 51 from the surface of the impression cylinder 8, is illustrated in
An alternative embodiment of this configuration is shown in
Number | Date | Country | Kind |
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10 2010 054 706.9 | Dec 2010 | DE | national |