EP4028261A1

EP4028261A1 - Method and device for print finishing

Info

Publication number: EP4028261A1
Application number: EP20771457.7A
Authority: EP
Inventors: Georg Barth; André PANITZKE
Original assignee: KAMA GmbH
Current assignee: KAMA GmbH
Priority date: 2019-09-09
Filing date: 2020-08-28
Publication date: 2022-07-20
Anticipated expiration: 2040-08-28
Also published as: EP4028261C0; IL291132A; EP4028261B1; JP2022547924A; JP7446411B2; DE102019124105A1; WO2021047922A1

Abstract

The invention relates to improved methods and devices for print finishing, in particular for film transfer. The proposed device for print finishing comprises a transport device for moving a printed material along a transport path, a printing device for applying a radiation-curing plastic onto the printed material in a first section of the transport path, a film supplying device for supplying transfer film to a surface of the printed material in a second section of the transport path, and an irradiation device for curing the radiation-curing plastic in the second section of the transport path, which comprises at least one radiation source.

Description

Process and device for print finishing

The invention relates to improved methods and devices for print finishing.

Print finishing refers to a change in the surface of a substrate such as paper, cardboard, etc. through an additional coating. This gives the paper either a certain gloss, a structure or predefined effects that it does not have in its original, unprocessed form. Print finishing results in a change in the paper surface that makes the printed product as a whole more durable, on the one hand, by protecting it against wear, and on the other, by enhancing its appearance or touching it, or contributes to the sale of the products or services shown therein.

Finishing processes can be based on coating, joining, reshaping or separating the printing material. The processes in which the finishing is carried out by joining include lamination, lamination and film transfer. Foil transfer comprises finishing processes in which transfer layers are detached from a carrier foil and transferred to the printing material. This group of processes includes hot foil stamping, the

Cold foil transfer and a foil transfer to toner implemented in the context of digital printing. In addition to the aesthetic enhancement of a product, special Films (hologram films) can also be used to protect products and documents.

With hot foil stamping, under the effect of pressure, temperature and contact time, transfer layers of a stamping foil are transferred to the material with the help of an embossing stamp, which at the same time undergoes a permanent change in shape. Hot foil stamping takes place as plan stamping with a tool or relief stamping with a die and male mold. Either flat dies or embossing rollers, which are heated for the film transfer, are used as embossing tools. The temperature depends on the stamping foil used, the printing material and the type of machine and is between 80 ... 220 ° C.

The stamping foil consists of several layers. One or more transfer layers are either applied directly to a carrier film made of polyester, or the transfer layers are applied to a separating layer located on the carrier film, which melts under the action of heat and thus releases the transfer layers. The transfer layers comprise an optically effective layer and an adhesive layer (reactivatable adhesive). The adhesive layer provides a permanent and smudge-proof connection between the optically effective layer and the printing material. Color pigments, metal pigments and plastics can be used for the optically effective layer, which leads to very different visual effects.

With cold foil transfer, similar visual effects are achieved as with hot foil stamping, but without material deformation. By transferring a metallized Plastic _S chicht which is peeled from a carrier film and optionally subsequent overprinting can wide variety of metallic effects can be achieved.

In known processes, cold foil finishing is implemented, for example, with two additional printing units in an offset printing machine. In the first printing unit, a special adhesive is applied to the substrate using a standard printing forme. Since the characteristics of offset printing come into play, small raster elements and fine line widths can be transferred. A second printing unit is equipped with a film transfer device. The film is fed from the unwinding station into the printing gap between the blanket cylinder and the printing cylinder and brought into contact with the printing material. The film consists of several layers that are located on a carrier film. The color is provided by an aluminum layer and a protective lacquer layer, the coloring of which influences the color impression. The transfer layers on the substrate remain chicht by adhesion of an adhesive layer with the printed adhesive _S adhere. The carrier film is then wound up again.

The visual effect of cold foils is similar to that of stamping foils. However, there is no haptic effect because there is no deformation or noticeable surface change.

Cold foils are used in the production of various print products, for example in label printing, on high-quality packaging or in commercial printing. The fact that the finishing can be done inline in the printing machine and, compared to other types of finishing, does not have to produce any special tools, brings a cost advantage. However, two additional printing units and the film transfer station are required for the cold foil transfer.

One object of the present invention is to further develop and improve the known methods and devices for print finishing, in particular for cold foil transfer.

For this purpose, a process for print finishing is proposed, in which a printing material and a transfer film with a transfer layer are provided, the printing material is moved along a transport path at a transport speed, and a radiation-curing plastic is applied to the printing material during the movement of the printing material in a first section of the transport path is applied, after the application of the radiation-curing plastic in a second section of the transport path, the printing material is irradiated, while at the same time the transfer film is pressed onto the printing material and moved with it along the transport path, and when leaving the second section of the transport path, the transfer film is removed from the printing material becomes.

In the previously known methods of cold foil transfer, adhesives are used which are already tacky when they are applied to the printing material and therefore easily peel off the transfer layer from the transfer foil when the carrier foil is removed from the printing material. In the method according to the invention, a Radiation-curing plastic used as an adhesive, which is initially in the form of a resin, ie in liquid or pasty form and has no or virtually no adhesive strength. Only when this resin is irradiated with radiation of a specific wavelength does it become sticky and then harden. In this way, the transfer layer is peeled off from the transfer film in the areas in which the surface of the printing material has the resin of the radiation-curing plastic, while the transfer layer remains on the transfer film in the other areas. This has significant advantages. For example, nozzles of a printing device that is used to apply the resin to the printing material can no longer clog because the resin applied to the printing material is not irradiated until after printing.

In one embodiment of the method it is provided that the printing material is moved horizontally and the transfer film is guided in the second area of the transport path around a partial circumference of a pressure roller that is pressed onto the printing material. This has advantages in particular for the print finishing of printing materials in the form of individual sheets - in contrast to the roll-to-roll process. Viewed in the transport direction, the printing substrate and the transfer film only touch each other in a very short area according to the invention, so that a relative displacement due to transport routes of different lengths cannot have a negative effect on the result of the finishing. For the same reason, it can advantageously be further provided in the proposed method that the pressure roller rotates with a Peripheral speed is moved, which is equal to the transport speed of the printing material.

It can also be particularly advantageously provided that the pressure roller is provided as a radiation-permeable hollow body and a radiation source is provided in the pressure roller. For a high-quality result, it makes sense anyway that the transfer film is pressed onto the printing material. The irradiation can either take place beforehand, so that the hardening process of the resin begins while the pressure roller is acting, or afterwards. If, however, the pressure roller is a radiation-permeable hollow body in which the radiation source is arranged, then the pressing of the film onto the printing material and the curing of the resin of the radiation-curing plastic coincide, and the action of the radiation occurs while the pressure roller is being pressed through the light-permeable hollow body.

In a further embodiment of the proposed method, it can be provided that the pressure roller is pressed onto the transport path when a printing material is moved underneath it and is raised when no printing material is moved underneath it. In this way, a paper jam, which can arise as a result of the collision of the printing material with the pressure roller that is pressed onto the transport path, can be avoided.

The object is also achieved by a device for print finishing, which comprises: a transport device for moving a printing material along a transport path, a printing device for Application of a radiation-curing plastic to the printing material in a first section of the transport path, a film feed device for feeding transfer film to a surface of the printing material in a second section of the transport path, and a

Irradiation device for curing the radiation-curing plastic in the second section of the transport path, which comprises at least one radiation source.

In this case, the transport device can have, for example, a belt conveyor on which the printing material is transported in a lying position. Advantageously, the

Transport device on a suction belt conveyor on which the printing material is held by means of negative pressure. The suction belt conveyor can for example have a perforated conveyor belt guided around deflection rollers, a so-called suction box being arranged between the deflection rollers, in the interior of which a vacuum is generated by means of a pump.

The film feed device can, for example, have at least one decoiler and one reel-up, as well as a pressure roller arranged between them, around which the transfer film is guided and which is pressed onto the printing material.

It can further be provided that the pressure roller can be moved back and forth between a lower position in which it presses on the transport path and an upper position in which it is lifted off the transport path. This makes it possible for the pressure roller to be pressed onto the transport path when a printing material is moved underneath it and to be raised when no printing material is moved underneath it. This can a paper jam, which can occur due to the collision of the printing material with the pressure roller pressed on the transport path, is avoided.

In a further embodiment it can be provided that between the uncoiler and the pressure roller and / or between

Pressure roller and reel-up, at least one tension roller for producing a constant web tension is arranged in the transfer film.

It can also be particularly advantageously provided that the pressure roller is designed as a radiation-permeable hollow body and the at least one radiation source is arranged in the pressure roller. The pressing of the film onto the substrate and the curing of the resin of the radiation-curing plastic coincide, and the action of the radiation takes place during the

Pressing the pressure roller through the translucent hollow body.

In a further embodiment of the proposed device it can be provided that the irradiation device in addition to the at least one

Radiation source comprises at least one movably arranged diaphragm for directing the beam generated by the radiation source. This screen can, for example, comprise a hollow cylindrical body with a slit-shaped screen opening which is arranged inside the pressure roller so as to be rotatable about its longitudinal axis.

In the case of process variants in which the radiation-hardening plastic used is plastic that can be hardened by IR radiation, it is provided on the device side that the at least a radiation source emits IR radiation.

In the case of method variants in which the radiation-hardening plastic used is plastic that can be hardened by UV radiation, provision is made on the device side for the at least one radiation source to emit UV radiation.

The invention is explained in more detail below using an exemplary embodiment and an associated figure which shows a device according to the invention.

At the beginning of a device according to the invention there is a sheet feeder 11 and at its end there is a sheet delivery 12.

A transport device 2 for moving a printing material 1 along a transport path, the beginning and end of which are each indicated by a horizontal arrow, is arranged between the sheet feeder 11 and the sheet delivery 12.

The transport device 2 has a suction belt conveyor 21 on which the printing material 1 is held by means of negative pressure. The suction belt conveyor 21 has a perforated conveyor belt guided around deflection rollers, a suction box being arranged between the deflection rollers, in the interior of which a vacuum is generated by means of a pump 22.

Above the transport device 2, a printing device 3 for applying a radiation-curing plastic to the printing material 1 is arranged in a first section of the transport path. The printing device 3 is designed in the manner of an inkjet printer, in which instead of a printing ink, a resin of a radiation-curing plastic is applied to the surface of the printing material 1, while the printing material 1 is moved by the transport device 2 under the printing device 3. By triggering the binding reaction, the adhesive is activated in order to achieve dimensional stability of the printed image (so-called "pinning").

Downstream of the printing device 3, in a second section of the transport path, also above the transport device 2, a film feed device 4 for feeding transfer film to a surface of the printing material 1 is arranged. The film feed device 4 comprises a decoiler 41, a reel 43 and a pressure roller 42 arranged between the decoiler 41 and the reel 43. The transfer foil 6 is guided around the pressure roller 42 and pressed onto the printing material 1. Between the uncoiler 41 and the pressure roller 42 and between the pressure roller 42 and the reel 43 there is an arrangement of two tensioning rollers 44 coupled to one another, which are used to produce a constant web tension in the transfer film 6.

The pressure roller 42 is by means of a yoke 45 and a pneumatic cylinder 46 engaging the yoke 45 between a lower position, in which the pressure roller 42 presses on the transport path, and an upper position, in which the pressure roller 42 is lifted from the transport path, back and forth moveable.

The device further comprises an irradiation device 5 with a UV lamp as the radiation source 51 for curing the radiation-curing Plastic. The pressure roller 42 is designed as a radiation-permeable hollow body and the UV lamp 51 is arranged in the pressure roller 42. The irradiation device 5 also has a movably arranged diaphragm 52 for directing the from the

Radiation source 51 includes the generated beam, which is designed as a hollow cylindrical body with a slot-shaped aperture opening, which is rotatable inside the pressure roller 42 about the longitudinal axis of the pressure roller 42.

Process and device for print finishing

List of reference symbols

I substrate

II sheet feeder

12 sheet delivery 2 transport device

21 Suction Belt Conveyors

22 pump

3 print setup

4 film feed device 41 decoiler

42 pressure roller

43 reel

44 Tension roller

45 yoke 46 pneumatic cylinder

5 irradiation facility

51 Radiation source

52 aperture

6 transfer film

Claims

Process and device for print finishing

Claims

1. Process for print finishing in which

• a printing material (1) and a transfer film (6) with a transfer layer are provided,

• the substrate (1) is moved along a transport path at a transport speed,

• During the movement of the printing material (1) in a first section of the transport path, a radiation-curing plastic is applied to the printing material (1),

• after the application of the radiation-curing plastic in a second section of the transport path, the printing material (1) is irradiated while at the same time the transfer film (6) is pressed onto the printing material (1) and moved with it along the transport path, and

• when leaving the second section of the transport path, the transfer film (6) is removed from the printing material (1).

2. The method according to claim 1, wherein the printing material (1) is moved horizontally and the transfer film (6) in the second region of the transport path by one Part of the circumference of a pressure roller (42) is guided, which is pressed onto the printing material (1).

3. The method according to claim 2, wherein the pressure roller (42) is moved rotating at a peripheral speed which is equal to the transport speed of the printing material (1).

4. The method according to claim 2 or 3, in which the pressure roller (42) is provided as a radiation-permeable hollow body and a radiation source (51) is provided in the pressure roller (42).

5. The method according to any one of claims 2 to 4, in which the pressure roller (42), when a printing material (1) is moved underneath, is pressed onto the transport path and, when no printing material (1) is moved underneath, is raised.

6. A device for print finishing, comprising

• a transport device (2) for moving a printing material (1) along a transport path,

• a printing device (3) for applying a radiation-curing plastic to the printing material (1) in a first section of the transport path,

A film feed device (4) for feeding transfer film (6) to a surface of the printing material (1) in a second section of the transport path, and

• an irradiation device (5) for curing the radiation-curing plastic in the second section of the transport path, the at least one Radiation source (51) comprises.

7. The device according to claim 6, wherein the transport device (2) has a suction belt conveyor (21) on which the printing material (1) is held by means of negative pressure.

8. Apparatus according to claim 6 or 7, in which the film feed device (4) has at least one decoiler

(41) and a reel (43) as well as a pressure roller (42) arranged between them, around which the transfer film (6) is guided and which is pressed onto the printing material (1).

9. Apparatus according to claim 8, wherein the pressure roller

(42) can be moved back and forth between a lower position in which it presses on the transport path and an upper position in which it is lifted off the transport path.

10. The device according to claim 8 or 9, wherein between the uncoiler (41) and the pressure roller (42) and / or between the pressure roller (42) and the reel (43) at least one tension roller (44) for producing a constant web tension in the transfer film (6 ) is arranged.

11. Device according to one of claims 6 to 10, in which the pressure roller (42) is designed as a radiation-permeable hollow body and the at least one radiation source (51) is arranged in the pressure roller (42).

12. Device according to one of claims 6 to 11, wherein the irradiation device (5) in addition to the at least a radiation source (51) comprises at least one movably arranged diaphragm (52) for directing the beam generated by the radiation source (51).

13. The device according to claim 11 and 12, wherein the diaphragm (52) comprises a hollow cylindrical body with a slit-shaped diaphragm opening which is rotatably arranged in the interior of the pressure roller (42) about its longitudinal axis.

14. Device according to one of claims 6 to 13, in which the radiation-curing plastic is curable by IR radiation and the at least one radiation source (51) emits IR radiation.

15. Device according to one of claims 6 to 13, in which the radiation-curing plastic is curable by UV radiation and the at least one radiation source

(51) Emits UV radiation.