NL1002379C2 - Printable foil. - Google Patents

Description

Printable foil

The invention relates to an ink-printable film, comprising an ink-penetrable and ink-holding porous layer, for example an open, fibrous layer of paper. Such a foil is known and can for instance be printed with liquid ink using an ink-jet printer. The porous layer receives ink on its side, hereinafter referred to as the outside, during a printing operation. Among other things, this ink penetrates the porous layer through capillary action. This penetration can take place relatively quickly, but it takes a relatively long time before the outer surface to which the ink has been supplied is so dry that the foil thus printed can be covered by a transparent layer, for example 15 of PET or PVC, to be adhered thereto. must be adhered to it on the top surface, for example by means of a pressure-sensitive adhesive, such as an acrylate.

Generally, there is a desire among users to maximize the color intensity of prints, which can greatly enhance the brightness and vividness of the images. For this, it is necessary that an ink-jet printer be set to supply relatively large amounts of ink per unit area to the film. This results in various drawbacks.

First of all, the effective drying period, as described above, is even longer.

Furthermore, there is a risk, in particular with the relatively thin foils, that the foil will locally swell and thus a somewhat irregular waveform will arise. Due to such a waveform, in deviation from the optimally flat structure, the distances between the ink nozzles of the ink-jet printer and the film will no longer be constant, but will vary.

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As a result, the shapes of the areas to which ink is supplied by a nozzle will vary. It will be understood that this adversely affects the image quality.

A further drawback of the use of relatively large amounts of ink per unit area is that the ink penetrated into the porous layer has a lateral distribution and exceeds the nominal limits of a printing zone. This is referred to as "bleeding" and gives rise to an essential blurring of sharp contours and the mixing of colors of adjacent printing zones.

The invention now provides a foil of the type mentioned in the preamble, which is characterized by a layer of ink-impermeable material, which layer closes the porous layer and is penetrated in that layer over a certain distance via the pores present therein. ink-impermeable layer is provided on that (inner) side of the porous layer, which is turned away from the (outer) side, to which ink is supplied during a printing operation.

The ink-impermeable layer gives the porous layer an increased dimensional stability, whereby the said spheres or waves are considerably reduced.

Due to the fact that the ink-impermeable layer has penetrated some depth into the porous layer and thus closes the pores present therein with a more or less irregular pattern, surprisingly in practice the phenomenon referred to as "bleeding" appears to be completely harmless. proportions. One could imagine that the ink-impermeable layer, due to the penetration of the pores into the pores, will exhibit a structure, which will be described as a number of mountain peaks and ridges, which descend together or define bowls in which an ink is trapped and can no longer migrate sideways. With emphasis 1002379 it is noted that this description is only an attempt to gain speculative insight into the physical effects underlying the observed improvements of the invention.

A particular embodiment has the special feature that the said material is an adhesive.

Such an embodiment can very easily combine two functions with each other, namely that of an ink-impermeable layer and an adhesive layer for adhering a printed foil to another layer.

A specific embodiment of the foil according to the invention has the special feature that the said material is applied in liquid form and subsequently dried or cured.

For example, use can be made of a liquid in which a solvent, for example water, is present which can be brought to evaporation. More component materials can also be used, which can be cured. Yet another embodiment is that in which the ink impermeable layer is applied as a foil and then brought to penetration of the porous layer by temporary temperature increase.

A preferred embodiment, which achieves to an even greater extent that the outer surface of the foil dries very quickly effectively, so that, for example, a covering foil can be adhered to it, has the special feature that on the outside of the porous layer 30 a covering layer for received from externally supplied ink.

An even increased resistance to boiling and waves is realized in an embodiment in which a carrier layer is adhered to the outside of the ink-impermeable layer.

This last embodiment can advantageously have the feature that an adhesive layer is applied to the outside of the carrier layer. This adhesive layer can be of 1002379 4 thermally activatable or pressure sensitive type. In the latter case, it will generally be necessary to use the protective foil, which must be removed prior to the use of the adhesive layer.

The said porous layer can for instance consist of paper or paper-like material based on natural fibers and / or synthetic fibers.

A specific embodiment has the special feature that the ink-impermeable layer is added to the porous layer by lamination or coextrusion.

The inks commonly used in ink-jet printers often contain additives, which can act, for example, as a lubricant. In particular, these lubricants prevent good adhesion of the porous layer with an adhesive layer. This problem particularly arises with heat-activatable glues such as PE, EVA and the like.

The prior art foil has been found to necessitate a long drying time of the ink.

If a user strokes the printed surface relatively shortly after the printing process, streaks on the printed surface cannot be avoided. The foil according to the invention dries immediately after the printing operation, in the sense that the swiping over the outer surface has no adverse effect on the printing quality.

The invention will now be elucidated with reference to the annexed drawings. Herein: figure 1 shows a schematic side view of a coextrusion device for manufacturing a foil according to the invention; figure 2 shows a partly broken away partial perspective view of the foil according to the invention; figure 3 shows a partly broken away perspective view of the foil according to figure 2; 1002379 Figure 4 shows a view corresponding with figure 2 of a variant; and figure 5 shows a view corresponding with figure 3 of the variant according to figure 4.

Figure 1 shows a coextrusion device 1 for manufacturing a laminate foil according to the invention. A web of paper 3 is unwound from a roll of paper 2 by transport rollers 4. The paper foil web 3 is further conveyed on a conveyor belt 5. Via an extruder 6, an adhesive layer 7 is applied to the paper 3 / followed by a layer of carrier material 8 which is delivered by an extruder 9. Thus three layers are superposed on top of each other, which are combined in a joining station 10. , in which, for example, by applying some pressure the combination is effected.

Figure 2 shows the film 11 emerging from the joining station 10. Attention is drawn to the fact that the film 11 has been turned over relative to the configuration shown in figure 1. The porous layer of paper 3 can be printed with a pattern 12. This pattern, consisting of ink, is taken up by the porous paper 3 and is transported downwards, inter alia, by capillary suction.

Figure 3 shows that the paper 3 is penetrated by the ink, and also that the adhesive layer 7 has also penetrated locally into the paper layer 3 and has formed a pattern there such that the ink cannot migrate substantially laterally. The drawn structures are completely speculative and only serve to determine the idea somewhat. It is clear that the adhesive layer closed at the bottom is optionally adhered to the polypropylene carrier via a separate adhesive layer. Figure 3 further shows very diagrammatically that the adhesive layer 7 at the top side has, as it were, a one-sided porosity, so it can absorb ink, but mainly prevents the lateral migration of ink.

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Figure 4 shows an embodiment in which an ink-receiving layer 13 is located above the paper layer.

In particular, the latter structure ensures that the ink 5 supplied to the foil 14 penetrates effectively into the porous paper layer 3.

For the record, attention is drawn to the fact that the proportions given in the drawing do not correspond to reality and that the different layers are not shown in the correct thickness ratios. Furthermore, the spatial structure of the finished adhesive layer 7 is shown only on the basis of speculation, without this being intended as a physical explanation in a limiting sense.

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Claims (7)

An ink-printable film, comprising an ink-permeable and ink-holding porous layer, for example an open, fibrous layer of paper, characterized by a layer of ink-impermeable material, which layer closes the porous layer and in that layer over a A certain distance has been penetrated through the pores present therein, which ink-impermeable layer is applied to that (inner) side of the porous layer, which is turned away from the (outer) side, to which ink is supplied during a printing operation. Film according to claim 1, characterized in that said material is an adhesive. Film according to claim 1, characterized in. 15 that said material is applied in liquid form and subsequently dried or cured. Film according to claim 1, characterized in that a covering layer for receiving ink supplied from the outside is provided on the outside of the porous layer. Film according to claim 1, characterized in that a carrier layer is adhered to the outside of the ink-impermeable layer. Foil according to claim 5, characterized in that. That an adhesive layer is applied to the outside of the carrier layer. Film according to claim 1, characterized in that the ink-impermeable layer is added to the porous layer by lamination or coextrusion. 1002379