EP3313670A1 - Method and device for transferring a decorative segment of an embossing film - Google Patents

Abstract

The invention relates to a method for transferring a decorative segment (3d) of an embossing film (3) onto a substrate (2) by means of an embossing stamp (6), wherein the embossing film (3) comprises a carrier film (31) and a transfer layer (33) arranged on the carrier film (31). The method comprises the following steps: a) providing the embossing film (3); b) embossing or pressing at least one compression segment (8v) spaced apart from the edge of the decorative segment (3d) into the transfer layer (33); c) embossing the decorative segment (3d) onto the substrate (2); d) removing the remaining embossing film (3r) from the substrate (2), which has been embossed with the decorative segment (3d). The invention further relates to a device for performing the method.

Description

 Method and device for transferring a decorative section of a stamping foil

The invention relates to a method and a device for transferring a decorative section of a stamping foil onto a substrate.

In the application of embossing foils, the paint package especially strong crosslinking paint systems, for example, UV-crosslinking paint systems and / or paint systems with high film thickness, d. H. With a thickness greater than 5 μιτι the transfer layer without carrier film included, it is very difficult to produce a clean separation edge in the embossing. In addition, the separation of the film composite in these cases does not take place at the edge of the application tool but in an undefined position. Due to the strong cross-linking, the formation of comparatively long or very long polymer chains occurs in the lacquers, as a result of which the physical properties of the lacquers are increased

Properties of the paints are influenced accordingly. Depending on the hardness of a highly crosslinked paint, for example, a comparatively Hard and brittle paint when embossing Undefined break, where paint flakes of different sizes may arise as unwanted contamination. For example, a comparatively soft and elastic lacquer can not or only incompletely break when embossing or tear undefined, so that in the worst case, no separation edge is formed. In the case of imprints of this type, stray remnants of the transfer layer formed as a paint package normally form, the aforementioned so-called flakes, which in the further processing of the embossed substrate lead to contamination of the machines and thus to increased cleaning effort. In extreme cases, these flakes can significantly increase the production output.

Flakes are understood to be parts of the transfer layer which have been detached from the carrier film and which have not been applied to the substrate. The flakes hang, without adhering to the substrate, to the adhering to the substrate parts of a decorative portion applied to the substrate and can there uncontrollably either hang or tear in the further processing process and thereby corresponding disturbances in the processing of the embossing film and / or the substrate cause. Flakes can be very small, especially in the micrometer range and thus e.g. be dusty, but also comparatively large, especially in the range of several millimeters or even centimeters in at least one direction of expansion.

The object of the present invention is to provide an improved process that has the advantages of a stable stamping foil with the clean

Separation of the decorative sections of the carrier film interconnects.

According to the invention, this object is achieved with the subject matter of claim 1. It is a method for transferring a decorative portion of a Embossing film proposed on a substrate by means of a stamping die, wherein the embossing film comprises a carrier film and a transfer layer arranged on the carrier film, wherein it is proposed that the method comprises the following steps:

a) providing the stamping foil;

b) embossing or pressing in at least one of the edges of the

 Decor section spaced compression section in the

 Transfer layer;

c) embossing the decorative section on the substrate;

d) detachment of the rest embossing foil from the impressed with the decor portion substrate.

The inventive method has the advantage that by forming, that is, the mechanical pressing or impressing the

Compression section in the transfer layer a defined breaking edge is formed without damaging the carrier film. By doing

Compression section, the layers of the transfer layer are mechanically loaded so that this can form a predetermined breaking point at a defined position, which breaks easily in a bending stress. The

Bending stress is in particular by the subsequent detachment of the

Carrier film exerted in a certain separation angle relative to the substrate of the applied decorative portion.

The thus achievable clean separation between decor section and

Rest embossing film during the transfer or during the transfer of the transfer layer from the carrier film as a decor portion on the substrate is advantageous in any type of application, ie the embossing or application to the substrate. This includes an unregistered and a registered application. In a non-registered application of the decorative portion is applied virtually endlessly without respect to the relative position between the substrate and decorative portion of the carrier layer on the substrate, transferred or transferred, that embossed. In a registered application, the decorative portion is applied in a defined relative position to the substrate or transferred or transferred to this, for example, a previously applied, eg

printed decor in accordance, i. into the register to the

To get decor section. Thus, e.g. complementary partial decors of printed decor and embossed decor are produced, wherein between these partial decors a clean separation of the decorative section is advantageous, in particular even necessary.

Register or register or register accuracy or register accuracy is a positional accuracy of two or more elements and / or layers, in particular the substrate and the stamping foil and / or the decorative section to each other to understand. In this case, the register accuracy should move within a predetermined tolerance and be as small as possible.

At the same time, register accuracy of multiple elements and / or layers to each other is an important feature in order to increase process reliability. The positionally accurate positioning can in particular by means of sensor, preferably optically detectable registration marks or

Register marks take place. These register marks or register marks can either represent special separate elements or regions or layers or themselves be part of the elements or regions or layers to be positioned.

Under Restprägefolie is not the decor section of the stamping foil

comprehensive part of the stamping foil or a portion of this part understood. It can be provided that in method step b) a pressing pressure is applied which is greater than the embossing pressure formed in method step c).

The ratio of the pressing pressure to the embossing pressure may be in a range of 1: 1 to 1: 10000.

It can further be provided that the pressing pressure is applied in a line-shaped section or at least piece-wise line-shaped section. For example, this section may be elongated straight, but also serrated or wavy. The section may have an open shape, in particular as the line shapes mentioned, or alternatively also a closed contour, for example in circular, elliptical, triangular or

Polygonal shape, especially in star shape. The shape of the section determines at least partially the transmitted to the substrate form of the

Decor section.

Thus, for example, an embossing foil formed as a strip can be processed such that pieces of the likewise strip-shaped transfer layer are applied to the substrate as a decorative section and a pressing force applied in a line-shaped manner defines the frontal outer edge of the applied decorative section. Thus, for example, an embossing foil formed as a surface section can be processed such that partial area portions thereof, in particular so-called smaller patches, are applied to the substrate as a decorative section and a For example, with a closed contour applied pressing pressure defines the peripheral outer edge of the applied decorative portion as a patch.

The width of the line-shaped portion may be in a range from 0.02 mm to 1 mm, in particular from 0.02 mm to 0.2 mm.

In an advantageous embodiment it can be provided that the distance of the at least one compression section from the edge of the decorative section is in a range of 0 mm to 2 mm. The extension of the decorative section corresponds to the extent of the embossing surface of the stamping die.

The object of the invention is further achieved by the subject matter of claim 7. It is an embossing device for transferring a decorative portion of a stamping foil on a substrate by means of a stamping die with a

Embossed surface is proposed, wherein the embossing film comprises a carrier film and arranged on the carrier film transfer layer, wherein it is proposed that in at least one edge portion of the embossing surface on the

Embossing punch is arranged in front of the edge of the embossing surface, a folding element, whose lower end face is formed as a pressing surface.

The embossing device according to the invention has the advantage that a through the pressing surface of the folding element in the transfer layer

Compression formed, that is mechanically pressed or stamped without damaging the carrier film. By doing

Compression section, the layers of the transfer layer are mechanically loaded so that this can form a predetermined breaking point at a defined position, which breaks easily in a bending stress. The

Bending stress is in particular by the subsequent detachment of the Carrier film in a certain peel over the substrate exerted by the applied on the substrate decorative portion.

It can be provided that the pressing surface is formed as a linear spherical rounded shape. The crowned design has the advantage that the pressing surface does not act as a cutting edge and thus causes no indentation of the carrier film and thus does not damage the carrier film or otherwise mechanically weakens it. The width of the pressing surface may be in a range from 0.02 mm to 1 mm, in particular from 0.02 mm to 0.2 mm. The width is the effective width of the pressing surface, i. the width of the effective cross section.

The folding element may be integrally connected to the die or, alternatively, be present as a separate component which is attached to the die.

It may further be provided that the pressing surface is aligned with the embossing surface.

Alternatively it can be provided that the pressing surface is arranged with a projection parallel to the embossing surface or in the vertical direction closer to the stamping foil than the embossing surface. The pressing surface should not protrude more than 50% of the thickness of the carrier film in order to avoid damage to the carrier film with certainty. In particular, supernatants of

In particular, 10% to 20% of the thickness of the carrier film sufficient to clean separation with minimal mechanical stress To achieve carrier film.

Furthermore, it is also possible that the projection of the pressing surface with respect to the embossing surface is also larger, in particular 50% to 1000%, preferably 50% to 700%, of the thickness of the carrier film. This supports a clean separation of transfer layers, which have a high mechanical stability.

Thus, experiments have surprisingly shown that even those larger

Supernatants of the pressing surface relative to the embossing surface are possible without damaging the carrier film in such a way that it can no longer fulfill its function. Thus, in such experiments, the supernatant was about 50% to about 1000%, preferably about 50% to about 700% of the thickness of the carrier film. The carrier film was made of PET in these experiments. The width of the pressing surface was about 0.01 mm to about 0.10 mm, preferably about 0.02 mm to about 0.05 mm. In these experiments, the distance between the pressing surface and the embossing surface was about 0 mm, that is, the pressing surface and the embossing surface are arranged directly adjacent without any distance therebetween. The carrier film may have a thickness of 10 μιτι to 50 μιτι. Experiments have shown that the carrier film should not fall below a certain thickness, in particular 10 μm, because the mechanical stress of the

Carrier film through the press surface otherwise could lead to tearing of the film in their further processing.

The carrier film may consist of a single film layer or, alternatively, consist of a laminate of different or the same films. The distance between the pressing surface and the embossing surface may be in a range of 0 mm to 2 mm. This small distance affects the appearance of the transferred decorative section as little as possible. In the case that the pressing surface is aligned with the embossing surface, the distance between the pressing surface and the embossing surface is about 0.1 mm to 2 mm. This distance is advantageous so that an alternating load on the embossing foil by the adjacent arrangement of embossing surface, distance and pressing surface acts and thereby can form a predetermined breaking point in the layers of the transfer layer in a particularly advantageous manner. The embossing foil can expand upwards in particular in the distance, whereas the embossing foil is pressed down under the embossing surface and the pressing surface.

In the case that the pressing surface is arranged with a projection relative to the embossing surface in the direction of the stamping foil, can be dispensed with a distance entirely, because then the pressing surface during lowering of the

Embossing stamp acts on the embossing film separately for a certain time on the stamping foil and the embossing foil in the areas adjacent to the pressing surface can escape the impressions and for this no separate distance must be necessary. Optionally, however, a distance in addition to the supernatant may also be provided in this case.

It is also possible, below the substrate, that is to say on the side of the substrate facing away from the pressing surface and the embossing surface, at least in the area of the pressing surface acting on the substrate, to form a base element

to arrange. This underlying element has in particular a thickness of about 0.5 μηη to 200 μητι, preferably from about 0.5 μηη to 100 μηη and can the effect of

Strengthen pressing surface on the substrate so that the substrate between pressing surface and base element slightly more compressed or

is compressed. As a result, the emergence of a predetermined breaking point can be promoted even better.

The base element is preferably made of a material with similar

Properties such as the substrate, for example made of paper or plastic. The base element may also be made of metal or metal alloys or silicone.

The base element can be a single element or can be composed of several superimposed elements, so that an accurate and sensitive adjustment of the total thickness of

 Underlay element can be made by means of these individual elements, each with a small thickness. Such a single element, for example, 0.5 μιτι to 50 μιτι, in particular 5 μιτι to 35 μιτι be thick. The appearance of the transferred decorative section is also determined by the nature of the substrate, in particular its surface roughness. The pressing surface acts together with the substrate as a counter-pressure element. The lower the surface roughness of the substrate, the more defined is this interaction and the more precisely can the separation of the transferred decoration section take place.

It can be provided that the distance by means of a between the

Folding element and the stamper arranged spacer element adjustable is. The spacer may be, for example, a spacer plate or a spacer. It is also possible to have several

Stack spacers to each other to be able to adjust the distance sensitively.

Alternatively, it can be provided that the distance is adjustable by means of an adjusting device arranged between the folding element and the stamping die. For example, may be provided as adjusting a screw with a fine thread.

It can be provided that the pressing surface is designed to be vertically adjustable. This design can be particularly in trial operation or for

Adaptation to different qualities of the stamping foil are used.

The folding element may have elongated holes, which are penetrated by fastening screws, wherein the pressing surface arranged on the folding element is vertically adjustable after loosening the fastening screws. to

Depth adjustment, for example, one or more spacers between a straightening plate and the embossing surface are arranged and then the folding element can be lowered so that the pressing surface rests flush on the straightening plate. The flush edition can be checked, for example, with the light gap method. After putting on the

Fixing screws can be removed or the spacer plates and the die to be inserted into the embossing station. Alternatively, it can be provided that the pressing surface is designed to be vertically adjustable by means of an adjusting device arranged between the folding element and the stamping die. The adjusting device can be designed as a helical gear. Because of the desired sensitive adjustment in the micrometer range, it is advantageous to provide a differential screw gear whose output travel through the

Difference of the thread pitches of the two cooperating screws is determined.

It can also be provided that the adjusting device is designed as a cam gear. As a cam gear can advantageously as a

Exzentergetriebe be provided whose eccentricity the maximum

Adjustment determined.

In a further embodiment it can be provided that the folding element and the embossing punch are integrally formed. The one-piece design can preferably be provided to form a folding element, which encloses the entire embossing surface, or to provide a stamp intended for use in the series.

It can be provided that the distance between the pressing surface and the embossing surface is formed as a groove. The groove can be introduced, for example, by laser machining with high accuracy.

The invention will now be explained in more detail with reference to exemplary embodiments. Show it 1 shows a first embodiment of the embossing device in a first working position in a schematic representation.

FIG. 2 shows the embossing device in FIG. 1 in a second working position; FIG.

Fig. 3 shows a detail III in Fig. 2 in an enlarged schematic

 Presentation;

4 shows an embossing stamp of a second embodiment of the

 Embossing device in a schematic sectional view;

5 shows an embossing stamp of a third embodiment of the

 Embossing device in a schematic sectional view; 6 shows an embossing stamp of a fourth embodiment of the

 Embossing device in a schematic sectional view;

Fig. 7 is a side view VII in Fig. 6;

8 shows an embossing stamp of a fifth embodiment of the

 Embossing device in a schematic sectional view; Fig. 9 shows an embodiment of the structure of a stamping foil in

 schematic representation.

Figs. 1 and 2 show a first embodiment of the embossing device 1 according to the invention in a schematic representation.

In the embodiment shown, the embossing device 1 is designed as a stroke embossing device and for the roll-to-roll process, in which both a substrate 2 to be embossed and an embossing film 3 are provided on supply rolls 4. The stamping foil 3 comprises a carrier foil 31, a release layer 32, a transfer layer 33 and an adhesive layer 34 (see FIG. 3). The construction of the embossing foil 3 is described in detail below in FIG. 9. The stamping foil 3 and the substrate 2 are fed to a stamping station 5 with a vertically movable die 6, wherein the substrate 2 rests with its underside on a stamping pad 7 in the stamping station 5. The stamping foil 3 rests with its adhesive layer 34 on the upper side of the substrate 2. Alternatively (not shown), the embossing die can also be designed as a rolling embossing wheel or as a curved embossing die that rolls over its curvature.

The die 6 has facing the embossing pad 7 at its

Front side of a heated embossing surface 6p, wherein the dimensions of the embossing surface 6p defines the dimensions of a of the embossing film 3 to be transferred to the substrate decorative section 3d. At the embossing surface 6p is at least in one section, a folding element 8 with a from the edge of

Embossing surface 6p spaced line-shaped pressing surface 8p arranged (see Fig. 3). The pressing surface 8p is formed as a spherical surface. The distance a of the pressing surface 8p from the edge of the embossing surface 6p is about 0.1 mm to 0.2 mm. The pressing surface 8p preferably aligns with the embossing surface 6p in a plane parallel to the embossing foil and to the substrate, ie it is not opposite the embossing surface 6p in the direction of the embossing foil. However, it is also possible that the pressing surface 8p projects beyond the embossing surface 6p up to a maximum of 50% of the thickness of the carrier film 31 downwards (in the direction of the embossing film).

The embossing punch 6 is arranged at a distance from the embossing foil 3 and the substrate 2 in a first working position (FIG. 1). In a second working position (FIG. 2), the embossing stamp 6 is on the

Embossing film 3 and the substrate 2 is lowered and brings the stamping film 3 to form an embossing pressure p _p on the substrate 2. The heated

Embossing surface 6p of the embossing die 6 activates the adhesive layer 34 of the embossing foil 3 in the region of the embossing surface 6p and connects there the embossing foil 3 in the region of the decor section 3d with the substrate 2. At the same time the embossing foil 3 is pressed together in the region of the pressing surface 8p, forming a pressing pressure Pk. wherein material of the stamping foil 3 is displaced laterally of the pressing surface 8p. As a result of the pressing pressure Pk, the layers of the embossing foil 3 arranged below the carrier foil 31 are in a band-shaped manner

Compression section 8v mechanically loaded. These layers are predominantly paint coatings. In the case of a pressing surface 8p aligned with the embossing surface 6p and spaced from the embossing surface 6p, the lacquer layers are deformed differently in a small space by the applied mechanical stress in the region of the pressing surface 8p and the simultaneous relief in the region of the distance between embossing surface 6p and pressing surface 8p. in that a predetermined breaking point forms in the area of the compression section 8v, which breaks at the bending stress caused by the removal of the carrier film.

In case of a relative to the embossing surface 6p preceding pressing surface 8p during the application of the die 6 on the embossing foil 3 and the substrate 2 in the region of the pressing surface 8p a comparatively high pressing pressure p _k exerted on the embossing foil 3 and the substrate 2, so that local by this strong mechanical stress in the paint layers of the compression section 8v is generated or pressed / stamped as predetermined breaking point, in the by the Pulling the carrier film 31 caused bending stress breaks. Seen over time, first the pressing surface 8p touches the stamping foil 3 and dips into the stamping foil 3 comparatively deeply without damaging it. After that, the die 6 then contacts the die

Embossing foil 3 and fixes or embossed the decorative portion 3d on the substrate. 2

After embossing the embossing punch 6 is raised and brought back into the first working position (Fig .1). The carrier film 31 is guided downstream of the embossing station 5 via a deflection roller 10. The carrier film 31 is subtracted from the transfer layer 33 behind the deflection roller 10 and a

Rest embossing film 3r, comprising the carrier film 31, remaining residues of the transfer layer 33 and the adhesive layer 34, a first take-up reel 9 fed. The detachment of the carrier film 31 is supported by the release layer 32. The embossed substrate 2 is fed to a second winding roller 9.

For the transport of the substrate 2 and the stamping foil 3 are

Transport roller pairs 1 1 provided.

The folding element 8 is in the first shown in Fig. 1 to 3

Embodiment formed integrally with the die 6. To form a distance a between the pressing surface 8p and the edge of the embossing surface 6p, a groove-shaped recess is provided. The puncture shown in cross-section in FIGS. 1 to 3 can be configured, for example, elongated in a straight line, but also serrated or wavy, in a plan view, not shown here. The puncture can in plan view an open shape,

in particular as the mentioned line forms, or alternatively also a have closed contour, for example in a circular, elliptical, triangular or polygonal shape, in particular in star shape.

In the second embodiment shown in FIG. 4, the

Embossing punch 6 has a rectangular embossing surface 6p, wherein on two opposite sides of the embossing punch 6 each one

Folding element 8 is arranged, the pressing surface 8p parallel to the

adjacent edge of the embossing surface 6p extends. The pressing surface 8p of the

Folding element 8 is aligned with the embossing surface 6p of the embossing stamp. 6

The folding elements 8 and the die 6 are connected to each other by fastening screws 12 which engage in threaded holes of the die 6. The distance a of the pressing edge 8k from the edge of the embossing surface 6p is determined by the thickness of a spacer plate 13 which is arranged between the folding element 8 and the embossing punch 6. It is also possible to provide a stack of a plurality of thin spacer plates instead of a spacer plate in order to be able to adjust the distance a sensitively.

The illustrated in Fig. 5 third embodiment is carried out as described above, with the difference that in the folding element 8 elongated holes are provided by the fastening screws 12th

are penetrated, and that the distance a of the pressing edge 6k is defined by the edge of the embossing surface 6p by spacers 14 instead of a spacer plate.

The slots allow a depth adjustment of the pressing surface 8p of the Folding element 8 relative to the embossing surface 6p. For depth adjustment, for example, a spacer plate between a straightening plate and the embossing surface 6p are arranged and then the folding elements 8 are lowered so that the pressing surfaces 8p rest flush on the straightening plate. The flush edition can be checked, for example, with the light gap method. After tightening the fastening screws 12, the spacer plate can be removed and the embossing die 6 are inserted into the embossing station 5.

6 and 7 show a fourth embodiment in which the distance a of the pressing edge 8k from the edge of the embossing surface 6p by the formation of the folding element 8 with a recessed press surface 8p is not adjustable.

As in the embodiment described in Fig. 5 is a

Depth adjustment of the pressing surface 8p of the folding element 8 provided relative to the embossing surface 6p. The depth adjustment is realized by a helical gear 15, which includes a set screw 15s and a dial 15e. The adjusting screw 15s is formed with a fine thread. The adjusting screw 15s is rigidly connected to the upper end portion of the folding member 8 and engages in a threaded hole of the setting wheel 15e. The dial 15e may have a scale to the adjustment of the helical gear 15th

to reproduce.

The stamper 6 has a protruding upper end portion in which the helical gear 15 is arranged. The set screw 15s is supported in a through-hole vertically penetrating the upper end portion. The dial 15e is arranged in a horizontal slot-shaped receptacle of the upper end portion of the die 6 and thereby not axially displaceable.

To fix the folding element 8 to the embossing punch 6, fastening screws 12 are provided as described in FIG. 5, which pass through elongate holes of the folding element 8.

The illustrated in Fig. 8 fifth embodiment differs from the embodiment shown in Fig. 7 in that the

Depth adjustment of the pressing surface 8p a Doppelschraubgetriebe 16 is provided, which comprises a first screw 16s and a second screw 26t formed with different pitches, the first screw 16s is adjustable from the outside and into a vertical threaded hole of a protruding upper end portion of the die 6th engages, and the second adjusting screw 16t engages in a central threaded hole of the first adjusting screw 16s and with the upper

End portion of the folding element 8 is rigidly connected. The smaller the difference between the thread pitches of the two setscrews 16s and 16t, the more sensitive is the adjustment of the vertical adjustment path of the pressing surface 8p. Fig. 9 shows the layered structure of one in the invention

Embossing device 1 used stamping foil 3, wherein the schematic

Representation approximately the thickness ratios of the stamping foil 3 reproduces.

The carrier film 31 is formed in this embodiment as a PET film with a layer thickness of 19 μιτι.

The release layer arranged between the carrier film 31 and the transfer layer 33 is a lacquer layer having a thickness of 0.5 μm to 1 μm. The transfer layer 33 has the following layers, which are each formed from a lacquer: a protective layer 331 of a UV-crosslinked acrylate having a thickness of 1 μm to 10 μm,

 a decorative layer 332 of an acrylate, of PVC or a mixture thereof with dyes and / or color pigments having a thickness of 0.5 μm to 50 μm, in particular 0.5 μm to 30 μm,

 a stabilization layer 333 of a UV-crosslinked acrylate having a thickness of 1 μm to 10 μm,

The thickness of the transfer layer 33 is thus between 5.5 μιτι and 70 μιτι. The adhesive layer 34 is the one described above

 Embodiments to a hot melt adhesive layer, which is thermally activated. The adhesive layer 34 is made of PVC with a layer thickness of 1 μιτι to 10 μιτι. But it is also possible to use a cold adhesive layer by means of

energy-rich radiation is activated.

In the testing of the proposed embossing device 1, the following parameters have been proven.

The embossing temperature is in a range of 80 ° C to 250 ° C, preferably in a range of 100 ° C to 200 ° C, depending on the embossing station 5 and the substrate. 2

The embossing pressure is in a range of 1 kN / cm ² to 10 kN / cm ² . The embossing time is in a range of 1 ms to 1000 ms, in particular in a range of 1 ms and 500 ms.

LIST OF REFERENCE NUMBERS

1 stamping

 2 substrate

 3 stamping foil

 3d decor section

 3r rest embossing foil

 4 supply roll

 5 embossing station

 6 stamps

 6p embossing surface

 7 embossing pad

 8 folding element

 8k press edge

 8p pressing area

 8v compression section

9 first and second take-up reel

10 pulley

 1 1 transport roller pair

 12 fixing screw

 13 spacer plate

 14 spacer

 15 helical gear

 15e dial

 15s set screw

 16 double screw gear

16s first set screw 16t second set screw

 31 carrier film

 32 peel layer

 33 transfer position

 34 adhesive layer

 331 protective layer

 332 decorative layer

 333 stabilization layer

a distance of the pressing edge 8k from the edge of the embossing surface 6p

PP embossing

 Pk pressing pressure

Claims

claims

1. A method for transferring a decorative section (3d) of an embossing film (3) onto a substrate (2) by means of an embossing stamp (6), wherein the stamping film (3) comprises a carrier film (31) and a transfer layer (31) arranged on the carrier film (31). 33),

 characterized,

 the method comprises the following steps:

 a) providing the stamping foil (3);

 b) embossing or pressing in at least one of the edges of the

 Decor portion (3d) spaced compression portion (8v) in the transfer layer (33);

 c) embossing the decorative section (3d) on the substrate (2);

d) detachment of the rest stamping foil (3r) from the substrate (2) impressed with the decor section (3d). Method according to claim 1,

characterized,

that a pressing pressure p _k is applied in process step b) that is greater than that in method step c) formed embossing pressure p is _p.

Method according to claim 2,

characterized,

the ratio of the pressing pressure Pk to the embossing pressure p _{p is} in a range of 1: 1 to 1: 10000.

Method according to claim 2 or 3,

characterized,

that the pressing pressure p _{k is applied} in a line-shaped section or at least piece-wise line-shaped section,

wherein the line-shaped or at least piecewise linear

Section is in particular straight, jagged or wavy or has a closed contour, in particular in a circular, elliptical, triangular, polygonal or star shape.

Method according to claim 4,

characterized,

in that the width of the line-shaped section is in a range from 0.02 mm to 1 mm, in particular from 0.02 mm to 0.2 mm.

Method according to one of the preceding claims,

characterized,

the distance between the at least one compression section (8v) from the edge of the decorative section (3d) is in a range of 0 mm to 2 mm.

Embossing device (1) for transferring a decorative section (3d) of an embossing film (3) onto a substrate (2) by means of an embossing stamp (6) with an embossing surface (6p), wherein the embossing film (3) comprises a carrier film (31) and one on the Carrier sheet (31) arranged transfer layer (33),

 characterized,

 in that at least one edge section of the embossing surface (6p) on the embossing punch (6) is arranged in front of the edge of the embossing surface (6p) a folding element (8) whose lower end face is formed as a pressing surface (8p).

Embossing device according to claim 7,

 characterized,

 that the pressing surface (8p) as a linear spherical surface

 is trained.

Embossing device according to claim 7 or 8,

 characterized,

 in that the width of the pressing surface (8p) is in a range from 0.02 mm to 1 mm, in particular from 0.02 mm to 0.2 mm.

10. Embossing device according to one of claims 7 to 9,

 characterized,

the pressing surface (8p) is aligned with the embossing surface (6p).

11. Embossing device according to one of claims 7 to 10, characterized

 that the pressing surface (8p) with a projection parallel to the

 Embossing surface (6p) is arranged.

12. embossing device according to claim 7 to 11,

 characterized,

 in that the distance (a) between the pressing surface (8p) and the embossing surface (6p) is in a range of 0 mm to 2 mm, in particular in a range of 0.1 mm to 2 mm.

13. embossing device according to claim 12,

 characterized,

 that the distance (a) is adjustable by means of a spacer element (13; 14) arranged between the folding element (8) and the stamping die (6).

Embossing device according to claim 12,

 characterized,

 that the distance (a) is adjustable by means of an adjusting device arranged between the folding element (8) and the stamping die (6).

15. Embossing device according to one of claims 7 to 14,

 characterized,

 the pressing surface (8p) is designed to be vertically adjustable.

16. embossing device according to claim 15,

characterized, that the folding element (8) has slots which are of

 Fixing screws (12) are penetrated, wherein the at the

 Folding element (8) arranged pressing surface (8p) after the release of the fastening screws (12) is vertically adjustable.

17. Embossing device according to claim 15 or 16,

 characterized,

 the pressing surface (8p) is designed to be vertically adjustable by means of an adjusting device arranged between the folding element (8) and the stamping die (6).

18. Embossing device according to claim 17,

 characterized,

 in that the adjusting device is designed as a helical gear (15, 16).

19. Embossing device according to claim 17,

 characterized,

 that the adjusting device is designed as a cam gear. 20. Embossing device according to claim 7,

 characterized,

 that the folding element (8) and the stamper (6) in one piece

 are formed. 21. embossing device according to claim 20,

 characterized,

that the distance (a) between the pressing surface (8p) and the embossing surface (6p) is formed as a groove.

Embossing device according to one of claims 7 to 21,

characterized,

a sub-laying element is arranged below the substrate at least in the area of the pressing surface acting on the substrate.