DE19754776A1 - Security marking system e.g. to prevent fraud, counterfeiting and pilfering - Google Patents

Abstract

One or more jets (1-4) apply a continuous stream of dye to a relatively moving surface. The jets are combined into an array (6) so the jets or array can be moved in synchronism with the moving product (5). The dye stream can be interrupted to apply lines of defined length, and several jets (1,2) can be interrupted in their flows in synchronism to give a series of single segments on the product. The dye flows can be interrupted by diverting these into a collector, using this to interrupt and then release the flow at certain positions. The flow can be passed through a ring electrode and so electrically charged for deflection by plates in synchronism with the moving product. Additional security dyes can be embedded in the dye flows.

Description

The invention relates to a method and devices for manufacturing of graphic security features. As is well known, the term is used "Security feature" means the components of a product the job of which is Authenticity of this product, for example a spare part, a drug, a branded item or information carrier (ID, passport, certificate, Proof of admission ticket, bank note, CD, video tape). By making Counterfeiting of such products creates significant economic, health-related and damage to the image of the companies, organizations or countries concerned. Security features should be such that they are as inseparable as possible Form a unit with the product to be secured, are easy to check and one require the greatest possible effort in the production of counterfeits.

There are a variety of security features that can be difficult counterfeit mechanical, electrical, magnetic, chemical, biological or distinguish optical properties. Examples are stickers with predetermined breaking points, Radio frequency labels, encodings in magnetic strips, chemical Recognition reactions on stickers or documents, biological markers, Holograms, watermarks and micro perforations.

Graphic security features are security features that are usually complex printing technology applied to products. The security against counterfeiting of such features is based on the difficulty the graphic appearance of the printed features with one for counterfeiters reproduce reasonable effort. Such graphical security features are, for example, graphic prints produced in intaglio printing or simultaneous printing Samples, portraits or illustrations on banknotes, stamps, tickets and Personal documents.  

The advantages of graphic security features are that they can be checked quickly with the naked eye or with simple aids, as well as the low cost at high Pads. Graphics produced in intaglio printing, for example, are easy to use feel because of their characteristic relief structure or because of Check tilting effects with different incidence of light while printing simultaneously manufactured patterns can be checked with a magnifying glass.

Therefore, graphic security features are very important.

Disadvantages of graphic security features are the high unique Installation costs for the security printing process, as well as the missing Possibility to change the printed image for short runs inexpensively or even to design document-specific, d. H. each document with a different one Print information, such as with continuous coding.

Color changes in the direction of the printing web or the printing sheet can in the known printing methods for graphic security features only by partial Coloring a printing plate or by printing several different colored printing plates can be achieved. This multiplies the cost of the Printing press. In addition, when printing together several are differently colored Printing plates have limited accuracy, which makes it difficult finest line segments in different colors to print precisely, butt to butt.

The smallest is due to the mechanical demands on the printing plates achievable line width in most security printing processes to 20-50 µm limited. Such line widths can be counterfeited with simpler printing processes reproduce.

Another disadvantage of the known manufacturing processes for graphic Security features are that only flat, flat and flexible products with such Procedures against counterfeiting can be secured. For example, a Compact Disc with the well-known security printing methods not with one graphic security feature.

In addition, some security printing processes such as that arise Steel intaglio printing, large amounts of ink and alkali waste.

The invention has for its object the disadvantages described in the Production of graphic security features through a simple, inexpensive fix versatile and environmentally friendly process.

Because the reproduction of fine graphic structures with high accuracy the The basis of graphic security features is an improved procedure meet at least the same requirements for the quality of graphic structures.

According to the invention the object is achieved in that from a nozzle or Array of multiple nozzles leak continuous streams of dye that are on the Precipitate the surface of the product moving relative to the nozzles.

With small nozzle openings, the finest lines on the product to be protected. Since the inventive method requires no contact between a printing plate and the product suitable control of the nozzles even non-flat products with the Security feature.

Due to the fixed positions of the nozzles relative to each other in one Nozzle array, an exact spacing of the lines can be maintained. Color, line width and position of the lines or line groups can be changed by Modulation of the composition of the dye stream, the nozzle position or by Deflection of the dye flows can be varied at any time and synchronously with the product.

For example, product-specific codes can be generated. The process offers a high level of security against counterfeiting because of its fine nozzles Line widths from 5 µm can be realized along their extension defines the color and the line width change. Such structures cannot be reproduced with known printing processes. The method according to the invention is environmentally friendly, because there are no color drops.

The nozzles and valves can be inexpensively used in circuit manufacturing produce known methods of microstructure technology.  

Embodiments of the invention are the subject of the dependent claims.

By synchronizing the nozzle or nozzle array position with the movement of the Different graphic line structures can be realized in the product.

Similarly, the color of the lines in certain areas of the Product vary by adding different dyes to the nozzles the movement of the product is synchronized. Coupled with the possibility Line structures in line widths from a few micrometers in a variety of The result is colors that can be kept in color reservoirs A wide variety of options Highly forgery-proof graphic structures to manufacture. The finest lines also have the advantage of legibility underlying data, for example the personal data of a value document not to be affected and this information nevertheless against falsification to secure.

In order to produce guilloche-like lines, you can use one relative to the product instead of one moving nozzle also deflects the dye flow of a fixed nozzle become. Such distractions can be as specified in the dependent claims, implement mechanically or electrically. In the case of an electrical distraction the advantage that no mechanically moving parts are required.

Many products to be protected against counterfeiting have a complex shape or have difficult surface conditions. In this case, it makes sense to use the graphic structures according to the invention initially towards an intermediate carrier apply as described in a subclaim. For example, the Graphic applied to a transfer film and then by hot transfer process the product can be sealed. Further subclaims indicate procedures such as a quick and clean switching on and off of the dye flows can be used to create line segments.

In the following the invention with reference to drawings the some Embodiments show explained. Here go from the drawings and their Description of further features and advantages of the invention essential to the invention forth.  

Show it

Fig. 1 schematically shows a device for producing a graphic security feature consisting of colored, straight lines

Fig. 2 schematically shows a device for producing colored, curved line structures

Fig. 3 is a process for the preparation schematically precisely positioned relative to one another, colored, curved line structures

Fig. 4 schematically a method for producing precisely positioned relative to each other more colorful, rectangular line structures

Fig. 5 diagrammatically a process for the preparation of segment-shaped line structures

Fig. 6 schematically shows a method for producing color-nested, segment-shaped line structures

Fig. 7 schematically shows a device for switching the dye flow on and off the product

Fig. 8 shows another embodiment schematically a device for switching on and off in dye flow at the product

Fig. 9 a device for the electrically controllable deflection schematically the dye stream for the realization of curved lines

Fig. 10 schematically shows a further embodiment of an apparatus for controllable deflection of the dye stream with the aid of a gas stream for the realization of curved lines

Fig. 11 schematically a device for the realization of color changes along a line.

Referring to FIG. 1, four nozzles 1-4 are combined to form a nozzle array 6.. The individual nozzles are supplied with flowable, differently colored dyes, which are emitted onto the product 5 as dye jets 1 a - 4 a. The movement of the product 5 shown as 7 or the movement of the array 6 shown as 8 or both movements 7 and 8 result in linear graphic structures 1 i- 4 i on the product.

With a nozzle diameter of 10 µm and a dye pump pressure of 4 MPa, for example, a dye jet of 9 µm diameter and a flow rate of about 50 m / sec is produced at the outlet of the nozzle. If, for example, a film or a paper web is transported under the nozzle array at this speed, approximately 10 µm wide, differently colored lines result ( 1 i- 4 i). At lower speeds the lines widen accordingly.

Fig. 2 show how j by a periodic movement 12, 13 of individual nozzles 27, 28 overlapping curved line structures 1, 2, j, can be realized for example in two different colors. The movement 12 , 13 of the nozzles can take place, for example, via numerically controlled letter motors, linear motors, piezo adjustment elements or similar drives.

In the Fig. 3 shows the nozzle array a curved line group (1 k 4 k) can be generated as in a transverse periodic movement 8 6. The spacing of the lines relative to one another is constant due to the arrangement of the nozzles in an array.

The Fig. 4 indicate an example of how a nozzle array 6 that periodically reciprocating around the center 11 in a reciprocating movement, linear structures 1 l 4 can be realized l.

The Fig. 5 show how can be realized b by switching off and switching on of the dye stream 1 a 1 line segments. The length of the segments can be regulated via the switching time of the dye flow and the relative speed between nozzle 1 and product 5 .

Fig. 6 shows how the axis of which is located by the connection of the nozzles 1 and 2 to an array 6 in the direction of movement of the product 7, intermittent line segments 2 b and 1 c, for example, be embodied in various colors. Depending on the synchronization of the switching on and switching off times of the nozzles 1 and 2 , the line segments 2 b and 1 c abut one another exactly, overlap one another or are separated from one another by spaces. Such lines consisting of differently colored segments can only be simulated with great effort with a small line width using printing processes, because the printing plates colored in the different segment colors always have an offset in relation to the color separation already on the product during the successive color transfer to the product.

In order to be able to implement rapid switch-on and switch-off processes for the dye streams, the device in FIG. 7 provides for deflecting the dye jet 1 a with a gas stream 14 in the direction 1 d in which it is kept away from the product 5 by a collecting container 15 . The dye can be returned to the reservoir 17 via a return line 16 .

Another dye flow circuit diagram is shown in FIG. 8. Here, the collecting container 15 is moved 18 into the dye jet 1 a and thereby the supply of the dye to the product 5 is interrupted.

Of course, the dye feed 29 to the nozzle 1 can also be switched directly via a valve 30 .

Fig. 10 shows how the point of impact of a dye jet 1 a can be varied without moving the nozzle 1 . In this embodiment it is provided to use a conductive dye which is charged with a voltage between the nozzle 1 and a ring electrode 10 . The charged dye stream can then be deflected with the baffle plates 9 in a new direction 1 e.

Similarly, a deflection by gas flows is also possible. Fig. 14 shows how the gas flows 14, 14 a a stream of dye 1 in the directions 1 f and 1 g deflect a. The lines that appear on the product 5 are offset from one another in accordance with the strength of the deflection.

The Fig. 11, finally, show how line groups may be implemented with color changes. A line segment is shown in FIG. 11 a, which has arisen from the fact that a dye 19 is passed to the nozzle 1 via a dye feed regulator 23 . Analogously, dye 20 flows via a dye feed regulator 24 to the nozzle 2. If the dye feed regulators 23 and 24 are brought into the position shown in FIG. 11b at the same time, dye 19 flows into nozzle 2 and dye 20 into nozzle 1. The line segments 1 i, 2 i exchange their color. The process can be repeated any number of times.

By continuously mixing two or more dyes, the Also change the color of a line continuously along the line. When such lines are applied to the product in different directions graphic structures are created, which in principle cannot be rotated Printing process, d. H. with printing processes based on the ink transfer from cylinders based, can be reproduced.  

Reference list

1-4

Dye nozzles

1

a-

4th

a Dye streams from the dye nozzles

1-4

1

b from the dye stream

1

a created line with the length

25th

and the line thickness

26

1

c from the dye stream

1

a created line with a defined length

1

d in the collecting container

15

deflected dye flow

1

a

1

e by deflection electrodes

9

deflected dye flow

1

a

1

f, g by gas flow

14

or

14

a deflected dye streams

1

a

1

i-

4th

i from the dye streams

1-4

created lines

1

j-

2nd

j nested, curvilinear from the nozzles

27

and

28

printed Line pattern in color

1

(

1

j) and

2nd

(

2nd

j)

1

k-

4th

k Colored, curved line structures positioned exactly relative to each other

1

l-

4th

l Colored, angular line structures positioned exactly relative to each other

5

product

6

Dye nozzle array

7

Direction of movement of the product

8th

Direction of movement of the dye nozzle array

9

Deflection electrodes

10th

Ring electrode

11

Pivotal point of the dye nozzle array

6

12th

Direction of movement of dye nozzle

1

13

Direction of movement of dye nozzle

2nd

14

,

14

a Gas flows to deflect the dye flow

15

Dye stream catcher

16

Dye flow feedback

17th

Dye reservoir

18th

Direction of movement of the dye flow collector

15

19th

Dye A

20th

Dye B

23

Dye feed regulator for dye nozzle

1

24th

Dye feed regulator for dye nozzle

2nd

25th

Length of the line segment

1

b

26

Line thickness of the line segment

1

b

27

jet

1

28

jet

2nd

29

Dye supply to the nozzle

1

30th

Valve

Claims (23)

1. The method and device for producing graphic security features, characterized in that a continuous dye stream emerges from at least one nozzle, which is reflected on the surface of a product moving relative to this nozzle. 2. Device according to claim 1, characterized in that several such nozzles ( 1-4 ) are combined to form at least one array ( 6 ). 3. The method and device according to claim 1, characterized in that the individual nozzles ( 1-4 ) of the nozzle array ( 6 ) and / or the nozzle arrays ( 6 ) and / or the product ( 5 ) move relative to the manufacturing device. 4. The method according to claim 3, characterized in that the movement of the individual nozzles ( 14 ) of the array ( 6 ) and / or the nozzle array ( 6 ) with the movement of the product ( 5 ) is synchronized. 5. The method according to claim 1, characterized in that by interrupting the dye stream ( 1 a), lines ( 1 b) with a defined length ( 25 ) on the product ( 5 ) are applied. 6. The method and device according to claim 5, characterized in that a plurality of nozzles ( 1 , 2 ) by a synchronized interruption of the dye streams ( 1 a, 2 a) generate individual segments ( 1 c, 2 b) of a continuous line on a product. 7. The method and device according to claim 5, characterized in that the interruption of the dye streams ( 1 a) is realized by deflecting the dye streams in one direction ( 1 d) in a collecting device ( 15 ). 8. The method and device according to claim 5, characterized in that the connection and disconnection of individual dye streams ( 1 a) by a movement ( 18 ) of the collecting device ( 15 ) is realized with a fixed dye stream such that the collecting device ( 15 ) the dye stream interrupts or releases at a certain position. 9. The method and device according to claim 1, characterized in that the direction of a color stream ( 1 a) is varied by

• - The dye stream is electrically charged by a ring electrode ( 10 ) and
• - Is deflected in the direction ( 1 e) in synchronism with the movement of the product ( 5 ) by electrically charged baffle plates ( 9 ).

10. The method and device according to claim 1, characterized in that the direction of a color stream ( 1 a) is varied by the color stream is deflected by a gas stream ( 14 , 14 a) in one direction ( 1 f, g). 11. The method according to claim 1, characterized in that the line thickness ( 26 ) of the line reflected on the product varies. 12. The method according to claim 11, characterized in that the line thickness of the line which is deposited on the product is varied by varying the relative speed between the dye flow rate and the product movement speed ( 7 ). 13. The method according to claim 11, characterized in that the line thickness of the line reflected by the modulation of the product Nozzle diameter is varied. 14. The method according to claim 1, characterized in that the color of at least one dye stream ( 1 a) along the line reflected on the product changes continuously or discontinuously. 15. The method according to claim 14, characterized in that the color of at least one dye stream ( 1 a) changes synchronously with the relative movement between the nozzle and the substrate. 16. The apparatus according to claim 14, characterized in that the color of a dye stream ( 1 a) is changed by switching the dye reservoir supplying the nozzle with a switch ( 23 ). 17. The method according to claim 14, characterized in that the color of the dye stream ( 1 a) is varied by continuously changing the mixing ratio of at least two dye streams. 18. The method according to claim 1, characterized in that the on the Product applied graphic security features a drying process run through. 19. The method according to claim 1, characterized in that the on the Product applied graphic security features go through a process, through the adhesion of the lines with thermal or chemical processes the product surface is improved. 20. The method according to claim 1, characterized in that the on the Product applied graphic security features with a protective layer be covered. 21. The method according to claim 1, characterized in that the graphic security features are applied to non-planar products by a constant distance control of the nozzle arrays ( 6 ) and the product ( 5 ) is ensured by a constant distance control. 22. The method according to claim 1, characterized in that in the dye streams ( 1 a- 4 a) additional security feature substances or particles are embedded. 23. The method according to any one of the preceding claims, characterized in that that the graphic security feature is applied to an intermediate carrier and from there to the product.