EP1878987A2 - Drying device for handling a print substrate surface in a processing machine - Google Patents

Abstract

The device (10) comprises a reflector (12) arranged at front side (13) of an irradiation unit (11). The reflector has a dichroitic layer (22) and an infrared absorbing layer (17) arranged at the rear side (14) of the reflector. The adherent infrared absorbing layer connected with the dichroitic layer is arranged at the cooling element.

Description

The invention relates to a drying device for the treatment of a printing substrate in a processing machine according to the preamble of claim 1. As a processing machines are particularly suitable rotary printing machines and coating machines for the processing of substrates.

In processing machines, it is known to use drying devices for drying UV (ultraviolet) -curing printing inks and / or coatings, which as radiation unit have at least one UV light source, such as mercury vapor lamps or UV-emitting light-emitting diodes.

A dryer device of this kind is designed as an irradiation device DE 102 43 577 A1 known. The dryer device comprises a (over the format width) stretched long arranged, annular UV emitter and a partially curved over its circumference arranged reflector. At the beam exit surface, an additional reflector for the purpose of deflecting the UV radiation is arranged, which is adjustable in its inclination. The reflector surfaces may have a dichroic coating.
Opposite the radiation exit surface, a radiation absorber for receiving in the off state of the UV lamp not directed to a workpiece radiation can be arranged. In a further embodiment, the additionally arranged reflector can function to some extent as a replacement of the radiation absorber. As is known, such reflector surfaces are executed with high gloss. The disadvantage here is the relatively complicated design of the dryer device.

The object of the invention is to improve a drying device of the type mentioned above such that the proportion of radiant energy emitted by a radiation unit having a wavelength in the infrared (IR radiation) is reduced from the radiation energy directed to the surface of the printing material by simple means ,
The problem is solved by the training features of claim 1. Further developments will become apparent from the dependent claims.

A first advantage of the invention is that in the dryer device, the proportion of the IR radiation from the otherwise on the under UV radiation curing ink and / or curing lacquer and / or curing adhesive (UV ink, UV lacquer, UV adhesive) provided material of directed radiation is noticeably reduced. As a result, the proportion of UV radiation is improved as useful radiation and reduces the previously caused by the IR-Ahteil the radiation heat input into the substrate or in adjacent components of the dryer or the processing machine. Furthermore, the risk of overheating of the printing material is noticeably reduced by reducing the unwanted portion of the IR radiation.

A second advantage is that, by reducing the heat input, the UV printing ink applied to the printing substrate before the drying process and / or the UV lacquer and / or UV adhesive harden more gently and yet solidify immediately. This also contributes to the improvement of the printing / lacquer quality (color brilliance, gloss, scratch resistance, adhesion, etc.).

The invention is not limited to UV-curable inks or coatings. Rather, a UV-curable adhesive may be previously applied to the substrate surface, which can then pre-cure and / or cure by means of the drying device according to the invention. A Such application is, for example, in existing multi-layer substrates, merging multiple layers to a substrate or the embossing foil, in which imaging layers of a transfer film on the substrate can be applied, feasible.

Fig. 1

eine Rotationsdruckmaschine mit den relevanten Komponenten zugeordneten Trocknereinrichtungen,

Fig. 2

eine Trocknereinrichtung in erster Ausbildung,

Fig. 3

eine Trocknereinrichtung in zweiter Ausbildung,

Fig. 4

eine Reflektorausbildung gem. Fig. 2,

Fig. 5

eine Reflektorausbildung gem. Fi. 3,

Fig. 6

eine Weiterbildung gem. Fig. 5.

The invention will be explained in more detail using an exemplary embodiment. Here are shown schematically:

Fig. 1

a rotary printing machine with the relevant components associated drying equipment,

Fig. 2

a drying device in the first embodiment,

Fig. 3

a dryer device in a second embodiment,

Fig. 4

a reflector training gem. 2,

Fig. 5

a reflector training gem. Fi. 3,

Fig. 6

a training gem. Fig. 5.

A rotary printing machine for the processing of sheet-shaped substrates 19 (sheet material) comprises a plurality of printing units I, II, at least one coating unit III and a boom IV. Each printing unit I, II has a form cylinder carrying a printing form 4. The form cylinder 4 is at least one inking unit and at Demand associated with a dampening unit (not shown). In this case, the printing plate is inked by means of applicator rollers, especially inking rollers, with a medium in the form of ink and wetted using a dampening unit by means of at least one applicator roller, especially at least one dampening roller, with a medium in the form of dampening solution. Alternatively includes a coating unit III a printing forme (including blanket) carrying the form of cylinder 5 (painting cylinder 5), which is associated with a metering 6, wherein the printing plate by means of an applicator roll, especially with a screened enamel applicator roller and a chambered doctor blade, is wetted with a medium in the form of paint.

1, a printing unit I, II designed as a plate cylinder form cylinder 4 and a form cylinder 4 adjacent arranged blanket cylinder 3, wherein the blanket cylinder 3 with a sheet-shaped substrate 19 in the conveying direction 7 transporting sheet guiding cylinder 1, especially a pressure cylinder, cooperates , The form cylinder 5 of the coating unit III is also a sheet guiding cylinder 1, especially a printing cylinder assigned.

For the transport of the sheet-shaped printing material 19 in the conveying direction 7, at least one sheet guiding cylinder is arranged as a transfer cylinder 2 between the sheet guiding cylinders / printing cylinders 1. If necessary, a sheet guiding cylinder 8 can be arranged as a turning device between the sheet guiding cylinders 1 of the printing units I, II and / or coating units III. The turning device 8 shown is designed as Eintrommelwendung on the principle of trailing edge application. Alternatively, other turning devices can be used.
The sheet guiding cylinders 1, 2 and 8 have per se known sheet holding devices 20, such as gripper systems on.
In the present example, the coating unit III in the conveying direction 7 is a boom IV with a take-off device 9 and rotating conveyor systems with sheet holding devices 20 for the purpose of filing the sheet-shaped substrates 19 downstream of a stack.

In the conveying direction 7 after the pressure zones (formed by blanket cylinder 3 and sheet guiding cylinder 1) of the printing units I, II and / or after the painting (formed by forme cylinder 5 and sheet guiding cylinder 1) of the Lackwerke III each have a dryer 10 for supplying radiant energy to with Printed UV ink and or varnished with UV varnish, alternatively with a UV adhesive provided substrate 19 is arranged.
If required, at least one drying device 10 can also be arranged in the boom (FIG. 1) and / or in a horizontal boom region (not shown) in the boom IV.

Each drying device 10 comprises at least one radiation unit 11 extending over the format width of the printing material 19, in particular a UV radiation unit. The drying device 10 further comprises at least one over the format width in a partial circumference curved reflector 12 as a reflector mirror. In the present example, two reflectors 12 with respect to the line of symmetry are arranged in mirror image to each other and directed to the substrate 19.
Such a reflector 12 has a radiation exit region 21 which is open in the direction of the printing material 19 to be dried and is in operative connection with a cooling element 15 on its rear side 14, which is remote from the printing material 19 or from the radiation unit 11.
The cooling element 15 preferably has a plurality of cooling channels 16 through which a cooling fluid, for example water, can flow. Alternatively, such a cooling element 15 may have a plurality of cooling fins and / or cooling channels 16.

A curved reflector 12 comprises a dichroic layer 22, which is arranged on its front side 13 facing the radiation unit 11. On a rear side 14 of the dichroic layer 22 forming the reflector 12, ie facing away from the radiation unit 11, the reflector 12 has a first IR (infrared) absorber layer 17 (FIGS. 2, 4).
In a preferred embodiment, the first IR absorber layer 17 is preferably adhesively bonded to the dichroic layer 22. In this case, the reflector 12 formed with the dichroic layer 22 and the first IR absorber layer 17 can form a one-part structural unit with the cooling element 15. For this purpose, the first IR absorber layer 17 connected to the front side with the dichroic layer 22 is adhered to the back of the cooling element 15 (FIG. 4). Alternatively, the first IR absorber layer 17 (as a reflector 12) connected to the dichroic layer 22 may become detachable be arranged on the cooling element 15.
The dichroic layer 22 is preferably sputtered on the front side 13 of the first IR absorber layer 17 arranged on the cooling element 15.

In a further embodiment, the reflector 12 comprises a substrate 23, for example a preferably metallic reflector sheet, which carries on the front side 13 the adhesively bonded first absorber layer 17 connected to the dichroic layer 22. In a further development, the substrate 23 can carry a second IR absorber layer 18 which is adhesively arranged on the rear side. Preferably, this reflector 12 (in both embodiments) is arranged detachably on the cooling element 15. In one embodiment, the second IR absorber layer 18 of the reflector 12 is assigned directly adjacent to the cooling element 15.
In a further development, this reflector 12 is arranged detachably on the cooling element 15. The cooling element 15 carries a third IR absorber layer 25, which is adhesively fixed thereto, and the second IR absorber layer 18 arranged on the reflector 12 is assigned to the third IR absorber layer 25 immediately adjacent thereto. Preferably, the dichroic layer 22 is sputtered on the front side 13 of the reflector 12 (or of the substrate 23).

In a first embodiment, the first IR absorber layer 17 is adhesively secured to the rear side 14 of the dichroic layer 22, which in turn is adhesively bonded to the substrate 23. At the rear of the substrate 23, a second IR absorber layer 18 is arranged (Fig. 3, 5, 6).
Such a reflector 12, especially its second IR absorber layer 18, the cooling element 15 is associated adjacent. The reflector 12 formed with dichroic layer 22, first IR absorber layer 17, substrate 23 and second IR absorber layer 18, detachably arranged on the cooling element 15 and the cooling element 15 can form a two-part structural unit. In this case, the second IR absorber layer 18 and the cooling element 15 are arranged in a contact gap 24 at a slight distance from one another or preferably adjacent to each other in direct surface contact (FIG. 5).

In a second embodiment, the first IR absorber layer 17 is adhesively secured to the rear side 14 of the dichroic layer 22, which in turn is adhesively bonded to the substrate 23. At the rear of the substrate 23, a second IR absorber layer 18 is arranged (Fig. 3, 5, 6).

Such a reflector 12, which is detachably arranged on the cooling element 15, especially its second IR absorber layer 18, has a third IR absorber layer 25 immediately adjacent to it, which is adhesively fixed to the cooling element 15 (FIG. 6). The reflector 12 formed with dichroic layer 22, first IR absorber layer 17, substrate 23 and second IR absorber layer 18, detachably arranged on cooling element 15 and cooling element 15 with third IR absorber layer 25 can form a two-part structural unit. In this case, the second IR absorber layer 18 and the third IR absorber layer 25 (on the cooling element 15) are arranged adjacent to one another in a contact gap 24 at a slight distance from one another or preferably in direct surface contact (FIG. 6).

In order to improve the absorption of the heat radiation (IR radiation) at the reflector 12 or cooling element 15, the first and / or second and / or third IR absorber layer 17, 18, 25 is preferably blackened. As a result, in particular the IR radiation can be completely absorbed.
In one embodiment, the first and / or second and / or third IR absorber layer 17, 18, 25 may be formed of a heat-resistant, blackened ink layer.
In a further embodiment, the first and / or second and / or third IR absorber layer 17, 18, 25 may be formed from a blackened anodization layer.
In a further embodiment, the first and / or second and / or third IR absorber layer 17, 18, 25 may be formed from black chrome.

The mode of action is as follows. As indicated in FIG. 2, the radiant unit 11 emits a radiation energy which, inter alia, contains wavelengths in the infrared (IR radiation) and in particular in the ultraviolet (UV radiation). From the radiation unit 11, the radiation energy directly or indirectly to the substrate 19 (with UV-curable ink, UV-curable varnish or UV-curable adhesive or other UV-curable materials).
The directed against the reflector 12 radiant energy (UV and IR radiation) is divided by the dichroic layer 22 on the reflector 12 by the UV radiation is deflected there and directed to the substrate 19 and the IR radiation, the dichroic layer 22nd (As a reflector 12) happens, is absorbed by the first absorber layer 17 and delivered to the cooling element 15. By means of cooling fluid and / or cooling ribs, the heat input introduced into the cooling element 15 by the IR radiation can be dissipated (FIG. 4).

In the embodiments of FIG. 3, 5, 6 directed against the reflector 12 radiant energy (UV and IR radiation) is divided by the dichroic layer 22 by the UV radiation is deflected there and directed to the substrate 19 and by the IR radiation passes through the dichroic layer 22 (as a reflector 12), is picked up by the first absorber layer 17, passes through the substrate 23 and is absorbed by the second absorber layer 18.

In the first embodiment, the second absorber layer 18 is assigned directly to the cooling element 15. From the second absorber layer 18, the IR radiation passes through the contact gap 24 and is delivered to or absorbed by the cooling element 15 (FIG. 5). By means of cooling fluid and / or cooling ribs, the heat introduced into the cooling element 15 by the IR radiation can be removed from the drying device 10.

In the second embodiment, the second absorber layer 18 is immediately associated with the third IR absorber layer 25 on the cooling element 15. From the second absorber layer 18, the IR radiation passes through the contact gap 24 and is taken up by the third IR absorber layer 25 and discharged from it to the cooling element 15 (FIG. 6). By means of cooling fluid and / or cooling ribs, the heat introduced into the cooling element 15 by the IR radiation can be removed from the drying device 10.

LIST OF REFERENCE NUMBERS

01 -

Sheet guiding cylinder (impression cylinder)

02 -

Sheet guiding cylinder (transfer cylinder)

03 -

Blanket cylinder

04 -

Form cylinder (plate cylinder)

05 -

Form cylinder (painting cylinder)

06 -

dosing

07 -

conveying direction

08 -

Sheet guiding cylinder (turning device)

09 -

removal device

10 -

drying device

11 -

radiation unit

12 -

reflector

13 -

front

14 -

back

15 -

cooling element

16 -

cooling channel

17 -

first IR absorber layer

18 -

second IR absorber layer

19 -

substrate

20 -

Sheet holder

21 -

Radiation exit area

22 -

dichroic layer

23 -

substratum

24 -

contact gap

25 -

third IR absorber layer

I -

first printing unit

II -

second printing unit

III -

coating unit

IV -

boom

Claims (17)

Drying device for the treatment of a printing surface in a processing machine, with a over the format width of the printing material extending radiation unit, which is assigned over a partial circumference at least one curved reflector with a dichroic layer, the reflector has an open in the direction of the substrate to be dried radiation exit region and the reflector on its rear side facing away from the printing material is in operative connection with a cooling element,
characterized,
comprises that the reflector (12) at one of the radiation unit (11) facing the front side (13) disposed dichroic layer (22) and on the rear side (14) arranged first IR absorber coating (17). Drying device according to claim 1,
characterized,
is arranged that the first IR absorber coating (17) adherent to the dichroic layer (22). Drying device according to claim 1 or 2,
characterized,
in that the first IR absorber layer (17) connected to the dichroic layer (22) is adhesively secured to the cooling element (15). Drying device according to claim 1,
characterized,
in that the first IR absorber layer (17) connected to the dichroic layer (22) is detachably arranged on the cooling element (15). Drying device according to claim 4,
characterized,
in that the reflector (12) has a substrate (23) which carries on the front side (13) the adhesively bonded first IR absorber layer (17) connected to the dichroic layer (22). Drying device according to claim 5,
characterized,
in that the reflector (12) has a substrate (23) which carries on the front side (13) the first IR absorber layer (17) which is adhesively bonded to the dichroic layer (22) and on the rear side a second, adherently arranged IR absorber layer (18) bears. Drying device according to claim 6,
characterized,
in that the reflector (12) is detachably arranged on the cooling element (15) and the second IR absorber layer (18) of the reflector (12) is assigned directly adjacent to the cooling element (15). Drying device according to claim 6,
characterized,
in that the reflector (12) is detachably arranged on the cooling element (15) and the second IR absorber layer (18) of the reflector (12) is associated with a third IR absorber layer (25) which is firmly adhered to the cooling element (15). Drying device according to one of the preceding claims,
characterized,
that the first and / or second and / or third IR absorber layer (17, 18, 25) are blackened. Drying device according to one of the preceding claims,
characterized,
in that the first and / or second and / or third IR absorber layers (17, 18, 25) are formed from a heat-resistant, blackened color layer. Drying device according to one of the preceding claims,
characterized,
in that the first and / or second and / or third IR absorber layers (17, 18, 25) are formed from a blackened anodization layer. Drying device according to one of the preceding claims,
characterized,
that the first and / or second and / or third IR absorber coating (17, 18, 25) are formed from black chromium. Drying device according to claim 3,
characterized,
with that the dichroic layer (22) and the first IR absorber coating (17) formed reflector (12) to the cooling element (15) is a one-piece structural unit. Drying device according to claim 4,
characterized,
in that the reflector (12) formed with the dichroic layer (22) and the first IR absorber layer (17) and the cooling element (15) form a two-part structural unit. Drying device according to claim 5,
characterized,
in that the reflector (12) formed with dichroic layer (22), first IR absorber layer (17) and substrate (23) forms a two-part with the cooling element (15) Building unit forms. Drying device according to claim 6,
characterized,
with that the dichroic layer (22), the first IR absorber coating (17), substrate (23) and second IR absorber layer (18) formed reflector (12) form a two-piece unit with the cooling element (15). Drying device according to claim 6,
characterized,
in that the reflector (12) formed with the dichroic layer (22), the first IR absorber layer (17), the substrate (23) and the second IR absorber layer (18) has a cooling element (15) carrying a third IR absorber layer (25) Form two-piece unit.

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