DE19947425A1 - Formation of surface with color dependent on viewing angle, is achieved by parallel flux of e.g. liquid droplets coloring only one side of relief texture on surface - Google Patents

Abstract

The surface (3) is based on a material (4) having a relief structure. This is placed in a directed flux of colored material, comprising e.g. particles (6), all moving parallel to each other. They can only reach and color specific regions of the surface (3)

Description

The invention relates to a method for producing surfaces, whose color impression depends on the viewer's perspective.

Find surfaces whose color changes depending on the viewing angle diverse applications as external surfaces of various products. Such surfaces are popular on bags, clothing and sports equipment as well as on Packaging to draw consumers' attention.

Because the production of such surfaces requires a high level of technological effort, and because the effect can be checked easily and without tools, viewing angle-dependent Color-variable areas also as authenticity features on valuable products, documents or banknotes use.

Surfaces with an angle-dependent color impression can be based on the Light diffraction / interference (holograms, gratings, coatings, mica sheets), the Light polarization (liquid crystals), light refraction (lenticular pattern over color samples) or based on the shading of color areas.

Depending on light diffraction and interference, angle-dependent, color-variable areas are required elaborate technologies and only work under special lighting conditions. The production of lenticular surfaces is also complex. The color change one special surface are difficult to reproduce. Since the lenticular grid must be open, such surfaces are also sensitive to mechanical and chemical Stress.

Liquid crystals are sensitive and can only be applied to surfaces with difficulty.

The geometric shadowing of color areas is the simplest of all methods for Realization of surfaces with angle-dependent color impression. For example, if the Wave crests of a wavy surface of color A with a color B is printed, the top view color of the surface is the mixed color of the colors A. (Wave valleys) and B (wave crests). On the other hand, if you look obliquely at the wave structure the wave crests cover the wave valleys so that the surface appears in color B. This effect is used for graphic corrugated paper, the crests of which are marked with a Ink roller are inked.

Multi-color changes can be realized by the two opposite Flanks of all wave crests are colored differently. So can be from the in both directions perpendicular to the flanks of the waves, completely different Generate color impressions.

However, the exact manufacture of a relief surface colored in this way fails because it there is no printing process with which the sides of a profile are printed with color can. Therefore, you can only try to start with a flat surface to print the corresponding pattern and then this surface in the relief shape the correct frequency, amplitude and phase. Because the relief for practical Applications should not be deeper than a few hundred microns, the forming process must approximately 100 microns relative to the printed image. This accuracy can especially with complex materials such as paper. An example this is the Kipp color change feature on the German 100 DM banknote. The Examination of various 100 DM banknotes shows that the envelope changes from blue to white color of the "100 DM" area in the right stripe of the front, depending on Banknote is made at different angles.  

The invention describes a method for reproducible and economical Production of surfaces with an angle-dependent color impression based on the Shading of individual color areas of a relief. The procedure does not require Synchronization between relief shaping and partial area coloring and therefore provides clear Color changes even at low relief depths and on complex materials such as Papers and cardboards. Shallow relief depths enable the surfaces to be realized on thin materials that can also be processed in web form and thus significantly expand the Area of application of the surfaces in the graphic and packaging industry, as well as Authenticity feature.

Because surfaces with an angle-dependent color impression based on shading of individual color areas of a relief are sealed with a protective layer. high stability of the surface against environmental influences can be achieved become.

According to the invention ( Fig. 1) the flanks 1 and 2 of a relief-shaped surface 3 of a material 4 from the streams 5 and 9 ( Fig. 2, 3) of the differently colored substances 6 and 10 , which as particles or dye (toner) particles may be present, colored. Color (toner) particles are available with diameters between 0.5 µm and 10 µm and can be directed vertically onto the flanks of the relief 3 , for example by their weight or with electric fields ( FIG. 7), where they are applied to a self-adhesive coating on the relief surface 3 stick or can be melted with heat. In the preferred embodiment of the invention, however, dye droplets are used as colored substances 6 and 10 , which are produced with atomizers 12 or ink-jet print heads 18 . Atomizers known from air humidification technology on the basis of high-frequency excited nozzle constructions provide droplets with diameters between 1 µm and 10 µm, with which the flanks can be colored even the finest reliefs 3 , for example sawtooth reliefs with a depth 11 of 100 µm. Ink-jet print heads with several hundred individual nozzles 19 and a continuous stream of droplets are known from ink-jet printer technology.

Behind the atomizer head 12 , a parallel droplet stream can be generated from the originally divergent droplet stream 14 with an arrangement of diaphragms 15 , 16 which colors a flank of the relief at a suitable angle 26 between stream 17 and relief material 4 ( Fig. 4). The covering of the relief surface with the dye can be promoted by means of coatings known from the inkjet paper industry, for the continuous absorption of the droplets and for the protection of the dyes.

The area of the surface 3 whose relief flanks are to be colored can be determined by a mask in the beam path of the droplet stream. If the droplet flow is directed perpendicularly onto the relief 3 , regions are created with color that is independent of the viewing angle ( FIG. 8).

The relief flanks can also be coated continuously by moving the material 4 relative to the droplet stream 17 , 20 , preferably with the droplet source 12 , 18 stationary.

This movement can take place across ( Fig. 6) or along ( Fig. 7) the relief lines. As the web moves along the relief lines, the droplet streams in the preferred embodiment of the invention fall in succession from top to bottom in the web direction, the web being tilted into the corresponding angles 26 , 27 ( FIG. 7) for each coloration.

During movement of the web transversely (Fig. 6) to the relief lines (Fig. 6), the direction of movement so 24 should be selected 25 that the colored fabrics 6, 10 viewed in the coordinate system of the relief, from the edge remove that should not be hit by the dye in question.

The directional movement 5 , 9 , 21 of the micrometer-sized dye droplets or color (toner) particles 6 , 10 , 20 can be disturbed by the slightest air turbulence, as can be caused, for example, by the movement of the relief material 4 . It must therefore be avoided that air is entrained on the surface 3 of the relief and that air turbulence occurs in the dye stream. The safest way to avoid this is to evacuate the area in question. Even a slight overpressure in the area of the dye streams prevents turbulence of the dye streams due to an air layer moving with the web. The area of the dye streams should also be protected from air movement by a housing 33 .

The finished coated relief can then be protected with a transparent coating 22 . Graphic information (pictures or text) can be printed over this protective layer or as a protective layer.

LIST OF DESIGNATIONS

1

Part of the surface

3rd

in the color of the fabrics

6

2nd

Part of the surface

3rd

in the color of the fabrics

10th

3rd

Surface of the relief-shaped material

4th

4th

Material with a relief-shaped surface

3rd

5

directed stream of colored substances moving parallel to each other

6

6

colored fabrics

1

I particles or droplets / form the current

5

7

in the color of the fabrics

5

colored areas of 3

8th

in the color of the fabrics

10th

colored areas of 3

9

directed stream of colored substances moving parallel to each other

10th

10th

colored fabrics

2nd

/ Particles or droplets I form the current

9

11

Relief depth of the material

4th

12th

Atomizers for the fabrics

6

13

Atomizers for the fabrics

10th

14

conical flow of colored fabrics

15

Entrance panel

16

Outlet aperture

17th

parallel flow of colored fabrics

18th

Single nozzle matrix

19th

19th

Individual nozzles

20th

parallel flow of single droplets

21

Direction of

20th

22

Protective cover

23

Relative movement between the stream

17th

and the relief-shaped material

4th

24th

Direction of movement of the relief-shaped material across the relief lines along the source

12th

25th

Direction of movement of the relief-shaped material across the relief lines along the source

13

26

Tilt angle of the relief-shaped material relative to the direction of flow of the colored substances from source

12th

27

Tilt angle of the relief-shaped material relative to the direction of flow of the colored substances from source

13

28

colored relief flank

1

29

colored relief flank

2nd

30th

Tilt angle of the relief-shaped material relative to the flow direction of the colored Fabrics

31

31

Flow direction of the colored substances

32

area with a single color regardless of the viewing direction

33

mechanical limitation of the flow area of the colored substances

Claims (18)

1) Method for producing a surface 3 consisting of a relief with differently colored partial areas 1 , 2 , the color impression of which depends on the viewer's perspective, characterized in that a relief-shaped material 4 is arranged in a directional stream 5 of colored materials 6 moving parallel to one another is that they only reach and color certain surface areas 7 of the surface 3 . 2) Method according to claim 1, characterized in that the method step according to claim 1 is repeated with a coming from a different direction, directed stream 9 of mutually parallel colored substances 10 moving. 3) Method according to claim 1 or 2, characterized in that thin, flexible materials 4 , such as papers and films can be equipped with a surface according to claim 1 by:

• a) the relief depths 11 selected less than 300 microns and
• b) colored materials 6 , 10 with diameters smaller than 100 μ are used to color the relief.

4) Method according to claim 1 or 2, characterized in that the colored substances 6 , 10 are dye droplets. 5) Method according to claim 3 or 4, characterized in that a level-free drying and adhesion of the dye droplets 6 , 10 on the relief surface 3 by:

• a) electrical discharges, chemical substances and / or mechanical processes and / or
• b) a coating of the surface 3 with suitable layers which bind the dye droplets and / or
• c) the admixture of substances (wetting agents) which change the surface energy of the dye droplets into the dye of the dye droplets 6 , 10 is achieved.

6) Method according to claim 1 or 2, characterized in that the colored substances 6 , 10 are solid dye particles. 7) Method according to claim 6 or 3, characterized in that the adhesion of the dye particles 6 , 10 on the relief surface 3 by:

• a) coating the surface with a self-adhesive material
• b) the fusion of the dye particles with the surface
• c) is achieved.

8) Method according to claim 4, characterized in that the dye droplets 6 , 10 by atomizing liquid dyes in an atomizer 12 , 13 with:

• a) nozzles excited by vibrations
• b) nozzles excited by ultrasound
• c) are produced by dyes atomized with compressed air.

9) Method according to claim 8, characterized in that the conical stream of dye droplets formed during atomization is converted into a parallel stream in that:

• a) the initially conical stream 14 of the dye droplets 6 , 10 is converted into a parallel stream 17 by an inlet orifice 15 and an outlet orifice 16 and / or
• b) the dye droplets are electrically charged and guided along a linear electric field.

10) Method according to claim 4, characterized in that the dye droplets 6 , 10 with diameters smaller than 100µ through a matrix 18 of individual nozzles 19 are emitted as a parallel stream 20 in the direction of the relief surface 3 , the droplet sequence 20 through :

• a) mechanical excitation of the individual nozzles 19 (piezoelectric jet)
• b) thermal ejection of the dye droplets from individual nozzles 19 (bubble jet)
• c) electrostatic extraction of the dye droplets from individual nozzles 19 (electrostatic jet) is generated.

11) Method according to the preceding claims, characterized in that the relief-shaped material 4 which has been coated with colors 6 , 10 is provided with a protective coating 22 . 12) Method according to claim 1, characterized in that the source 12 , 13 , 18 of the colored material flows and the relief-shaped material 4 rest relative to each other and a region of the material corresponding to the current cross section 16 is partially colored. 13) Method according to claim 1, characterized in that by means of a mask in the stream of colored substances 6 , 10 , the region of the material 4 to be partially colored is defined. 14) Method according to claim 1, characterized in that the source of the stream 17 of the colored substances 6 , 10 and the relief-shaped material 4 are moved 23 relative to each other, it being possible to continuously partially color larger areas of the material. 15) Method according to claim 14, characterized in that the relief-shaped material 4 is moved 24 , 25 transversely to its relief lines past fixed sources 12 , 13 of the colored substances 6 , 10 , so that relative to different tilt angles 26 , 27 of the material to the direction of movement 17 of the colored fabrics, differently colored relief flanks 28 , 29 arise. 16) Method according to claim 14, characterized in that the relief-shaped material 4 is moved past their respective relief lines in succession past individual fixed sources 12 , 18 of the colored substances 6 , 10 , with different tilt angles 26 , 27 of the material 4 relative to the Direction of movement of the colored fabrics 6 , 10 , differently colored relief flanks 28 , 29 arise. 17) The method according to claim 1, characterized in that by setting a suitable tilt angle 30 of the relief-shaped material 4 relative to the direction of movement of the colored fabrics 31 , areas 32 are formed on the material in which the flanks of the relief remain monochrome and therefore not from the viewing angle of the The viewer's dependent color impression is created. 18) Method according to claim 14, characterized in that deviations from the parallel, straight trajectory of the colored substances by air entrained by the moving material 4 or by turbulence in the ambient air are eliminated:

• a) that air turbulence caused by the ambient air is eliminated by mechanical limitation 33 of the flow area of the colored substances and / or
• b) that air is evacuated from the flow area of the colored substances