DE19826800A1 - Special paper for securities and banknotes etc. - Google Patents

Abstract

In the production of a special paper, with electrically conductive characteristic matter as proof of origin, the conductive material is of pigments and/or transparent polymers. They are added to the machine vat by a dosing system (17,19) for a homogenous mix with the paper material and/or spread homogeneously or in part over the paper web surface. The added conductive material is a dispersion and/or suspension applied to the paper web surface by a droplet tube (17) for a partial distribution in continuous or interrupted lines, or by a controlled dosing unit (17,19) with continuous or intermittent working. The conductive additives can be added to the machine vat, to be stirred into a homogenous mixture with the paper material during pulp preparation, to be fed to the fourdrinier section of the paper making machine as a homogenous pulp for the special paper. With conductive pigments, they are moved in a continuous circuit through the supply container (26) by pumps (20), for delivery to the paper web by a dosing unit (19). The conductive material can be transferred to the paper web by watermark embossing rollers wholly or partially at the watermark image die. The additives have an electrical conductivity or other physical values and/or chemical characteristics for authentication by a multiple scanning action. Independent claims are also included for: (1) A scanning system to test the authenticity of the paper. The sensor to monitor the electrical conductivity has a number of scanning channels activated by an optical, magnetic and/or electromechanical sensors. Preferred Features: The capacitative scanning sensor extends over the whole width of the paper sheet. The sensor is structured to reduce the scatter coupling and give a narrow difference between the conductivities of adjacent test zones which can be measured. The sensor channels are controlled so that, on the first scan, the channels with even numbers are used, and in each alternate scan, channels with odd numbers are in force, with a scanning frequency of pref. 200 kHz. The gap between the sensor electrodes and the receiver electrodes can be altered according to the test structures and the test plane. The electrically conductive additives have a particular reaction in the optical spectrum range, as a reference value for the electrical conductivity in a double test action. A roller or sliding rail retainer holds the paper sheet flat while being carried through the test apparatus. The sensor electrodes can be on two planes to the paper sheet, with a functional electrode side over the paper and the other functional electrode side under the paper sheet under scrutiny. (2) A paper making machine with a number of scanner sensors over the whole width of the paper web to monitor the maintenance of production parameters. Preferred Features: A control circuit is after the sensor array, to determine the feed of additives to the pulp or the web surface.

Description

The invention relates to electrically conductive security features for securities, Banknotes and documents in the paper making process different technological processes are introduced.

Special papers are known, which identification features for Protection against counterfeiting. These are used during the Integrated paper manufacturing process. For example, they become light active Feature substances incorporated. Some light-active feature substances are on the market today available so that counterfeiters are able to use these already known Recreate security features. There are e.g. B. Security features in UV Adjusted spectral range. These reenactments have a significant impact on counterfeit protection.

Furthermore, there are optical features in the form of watermarks Papers introduced. The watermark is currently becoming insignificant adjusted. Known counterfeits relate to the printing of the papers with representations similar to watermarks. However, these are with aids or recognizable in transmitted light or in the UV range.  

Another way of securing paper is to integrate Security threads or security tapes. These security threads, Security tapes are generally electrically conductive. The security threads or Security tapes mainly consist of a metallized film, which partially demetallized with letters or numbers or symbols, or punched out were. These additional features are designed as optical features and serve as optical security and as a technological hurdle for the counterfeiter. The threads themselves are detected using known capacitive sensors. Here is the electrical conductivity for a specific section of the thread measured. This is the determination of the presence. These security threads are currently being reproduced by counterfeiters.

These re-enactments are made by applying hot adhesive film or by Apply metallic inks. For the viewer quickly These reenactments are difficult to detect in banknote transactions. Also are such reenactments for the ATMs are not always detectable. Highly sensitive capacitive sensors can operate within small measurement tolerances however, detect some of these counterfeits.

The object of the invention is the electrically conductive security threads or electrically conductive security tapes as user-active security features, an additional reference test and or as independent test zones using Integration of electrically conductive feature substances within the paper and Testing the same, using known capacitive scanner sensors.  

The invention is described below with reference to the drawings Exemplary embodiments explained and described in more detail. The drawings and features to be extracted from the description can be found in others Embodiments of the invention individually for themselves or for several in any Combination, find application.

Fig. 1 Fourdrinier wire ( 1 ) of a paper machine with shown method of partial integration of the feature substance in line form or in sections of a line.

Fig. 2 rotary screen of a paper machine with shown method of partial integration of the feature substance in line form or in sections of a line.

Fig. 3 rotary screen ( 2 ) of a paper machine with subsequent watermark embossing roller ( 5 ), which takes over the change in consistency and thus the change in electrical conductivity.

Fig. 3a signal image of a sheet material with homogeneously incorporated of feature substance and then embossed watermark.

Fig. 4 rotary screen ( 2 ) of a paper machine with stock ( 4 ) for homogeneous integration of the feature substance.

Fig. 5 Fourdrinier wire ( 1 ) of a paper machine with a headbox ( 3 ) for homogeneous integration of the feature substance.

Fig. 6 signal image when slipping on the sensor of a banknote with homogeneous feature substance equipment ( 6 ) and security thread ( 15 ).

Fig. 7 signal pattern when slipping over a banknote with a homogeneous feature material ( 6 ) and watermark ( 9 ).

Fig. 7a signal linkage of the arranged sensors.

Fig. 8 representation of the watermark embossing roller ( 5 ) with feature substance supply ( 7 ).

FIG. 8a image signal of an electrically conductive water mark in conventional paper.

Fig. 9 partial feature substance application, feature substance integration in, on the paper web.

Fig. 10 signal images of the partial feature substance detection.

Feature substances with electrical conductivity usually consist of solids, like pigments in rod form or irregular form. Furthermore, are electrical Conductive polymers known in different designs.

The presence of these different manifestations enables a variety of technological possibilities for the integration of the feature substance in the paper.

In this embodiment, the production of special paper with electrically conductive pigments is shown as a feature substance. The paper stock is mixed with the feature stock in the machine chest ( 8 ) and kept under constant stirring as a homogeneous suspension. For solid feature pigments, 10% of the paper solids content is preferably used as the addition amount. This proportionate amount can vary depending on the type of detection.

When using electrically conductive polymers there is the advantage that a good Compatibility with other materials exists. The integration into the paper stock is much more straightforward than with solid materials because of the electrically conductive polymers also occur as a dispersion. The required concentration almost allows one transparent electrically conductive marking.

The detection of homogeneously introduced feature substances ( 6 ) is realized by means of capacitive sensors ( 11 ). Only the presence of the characteristic can be verified here.

If this homogeneous version is used as a reference feature for the electrically conductive security thread, it is necessary that a feature substance with a conductivity of greater or less than 35% of the conductivity of the security thread is used. The scanner sensor ( 11 ) thus detects the surface of the test object for the homogeneous nature and, as a reference, the presence of a security thread with predetermined electrical conductivity properties.

In Fig. 6 it is shown how the sheet material passes the sensor ( 11 ) and the electrical signal is generated at the sensor.

The sheet material first passes through optical sensors ( 13 ) which activate the capacitive scanner sensor ( 11 ).

The homogeneously introduced feature substance ( 6 ) now generates a signal image ( 23 ) in the time sequence 1-3 , at time 4 the security thread ( 15 ) slips over the capacitive scanner sensor ( 11 ). A significantly larger signal is produced with the security thread, since in this case the security thread has a higher conductivity than the printed feature substance. In the time sequence 5-7 , the same signal picture as in the time sequence 1-3 is generated. The signal images are compared and evaluated using a controller.

In a second example ( Fig. VII) a further possibility of homogeneous feature integration ( 6 ) in the paper stock is shown. Here, further coding is achieved by changing the material density ( 9 ).

The technological process is until the formation of the paper web with the first Embodiment identical. The paper web is further processed by embossing watermarks.

The watermarking process is carried out by mechanical processing of the paper web. An impression is made on the paper web by means of embossing roller ( 5 ). This embossing roller consists of a carrier roller with attached embossing segments ( 25 ). These embossed segments correspond to the pictorial representation of the watermark. The impression of the embossing segments ( 25 ) on the paper web corresponds to the pictorial representation on the embossing roller. Such a mechanical partial treatment of the paper web causes a change in consistency in the area of the watermark ( 9 ) with an electrically conductive structure ( 9 ) typical of the impression. This change in the electrical conductivity in the stamping area corresponds to the pictorial representation of the stamping segment ( 25 ).

If the sheet material produced in this way is then passed over a capacitive scanner sensor ( 11 ), a signal image ( 23 ) for the embossing area ( 9 ) is obtained in accordance with the visual representation and the scanner resolution.

FIG. 7 shows how a banknote in landscape format passes the scanner sensor ( 11 ) and how the signal image ( 23 ) is created when the sheet material is slipped over with homogeneously introduced feature substance ( 6 ) and the watermark ( 9 ) subsequently generated. In the illustration, optical sensors ( 13 ) activate the capacitive scanner sensor ( 11 ). When the sheet material is slipped over the sensor, a uniform signal image is created on channels 1 , 2 , 6 , 8 , 9 , 10 over the period of the banknote presence. A signal image is generated on the scanner channels 3 , 4 , 5 in accordance with the partial material change and the associated change in the partial electrical conductivity.

If barium sulfate is used as a feature substance, additional coding is achieved in the optical range, because this substance is infrared absorbing. The sensor arrangement of the capacitive scanner sensor is now combined with an optical scanner sensor. FIG. 7 shows how the arrangement of both sensors is realized.

A third embodiment represents a version of the production of partial Characteristic substance test zones.

After the conventional paper web has been formed, a watermark ( 24 ) is generated by means of embossing rollers. During this watermark generation, the feature substance pigments or the feature substance as a dispersion are transferred to the paper web. This process is shown in FIG .

A feature transfer roller ( 7 ) is fed with feature substance by a storage container ( 16 ). This feature substance transport roller in turn runs against the embossing roller ( 5 ), the feature substance being transferred to the embossing segment ( 25 ) as. Since the circumference of the embossing roller corresponds to the distance of the watermarks ( 24 ) from one another, it is possible to produce these electrically conductive watermarks ( 24 ) on the endless web.

The formation of the signal image on the scanner sensor ( 11 ) is shown in Fig. VIIIa.

A fourth example shows how partial feature substance application to the paper web is realized by means of a drip device or by means of outlet pipes ( 17 ), which are positioned exactly above the paper web path.

Fig. 1 and 2 illustrate how by means of a targeted, multiple arranged electronically controlled metering device (17/19) is a partial feature substance order feature substance integration into the paper web takes place. On the one hand, line-shaped ( 14 a) can be applied, on the other hand discontinuous linen-shaped ( 14 b) or spot ( 14 c) can be applied. This gives you partial feature zones when cutting the paper web into sheet material. These can run over the entire sheet width or sheet length or can be present in sections in the sheet width or sheet length. The width of the lines or line sections is adapted to the scanner resolution. The width is preferably 2 mm. In Fig. 10, the signal images for the examination of continuous and discontinuous characteristic lines are shown in the sheet material. Optical sensors ( 13 ) activate the scanner sensor ( 11 ) when the sheet material is slipped on. If the feature strip reaches the sensor, the signal pattern 14 aa, 14 bb or 14 cc is produced. The same signal images are also created in line-shaped or discontinuous line application by swiping on the paper web.

Reference list

1

Fourdrinier sieve

2nd

Circular sieve

3rd

Headbox

4th

Headbox

5

Watermark embossing roller

6

homogeneous mercury substance in paper

7

Feature transfer roller

8th

Machine chest

9

electrically conductive test zone watermark

10th

optical scanner sensor

11

capacitive scanner sensor

12th

optical measurement curve, measured on the measurement channels of the opt. Scanners

13

optical sensors to activate the capacitive scanner sensor

14

partial test zones

15

electrically conductive security thread

16

Feature storage container

17th

Outlet pipe

18th

Control section for outlet pipe

19th

automatic valve for discharge pipe dosing device in connection with

17th

20th

Feature cycle pump

21

Sensor channel straight numbering

22

Sensor channel odd numbering

23

Capacitive scanner sensor trace

24th

electrically conductive watermark through feature substance transfer

25th

Embossing segment

26

Storage container for feature substance for partial transfer

27

Pressure roller

Claims (18)

1. A method for integration of electrically conductive feature substances in specialty papers for documents, securities and bank notes is characterized in that the feature substance in the form of pigments and or of transparent polymers is that partially through metering device (17/19), or by the addition of the feature substance are introduced homogeneously into the paper stock in the machine chest ( 8 ) and or are coated homogeneously or partially on the paper web surface. 2. The method for integrating electrically conductive feature substances in special papers for documents, securities and banknotes is characterized in that the feature substance is applied continuously and or discontinuously to the paper web for partial feature substance distribution in line form as a dispersion and or suspension by means of drip tubes ( 17 ). 3. A method for the integration of electrically conductive feature substances in specialty papers for documents, securities and bank notes is characterized in that the feature substance as a dispersion or suspension by means of controlled metering device (17/19) continuously (14 a) and or intermittently (b 14, c) is applied to the paper web. 4. A method for integrating electrically conductive feature substances in special papers for documents, securities and banknotes is characterized in that the feature substance is introduced as a dispersion into the machine chest ( 8 ) and mixed homogeneously with the paper stock, so that a special paper with homogeneous material is mixed on the wire section Characteristic properties arise. 5. A method for integrating electrically conductive feature substances in special papers for documents, securities and banknotes is characterized in that the feature substance in the form of pigments in a storage container ( 26 ) and associated pipe system is kept in circulation by pumps ( 20 ) and by means of a metering device ( 19 ) reaches the paper web. 6. Process for the integration of electrically conductive feature substances in This makes special papers for documents, securities and banknotes characterized in that the feature pigments as additives in the Stock preparation is added. 7. The method for integrating electrically conductive feature substances in special papers for documents, securities and banknotes is characterized in that the feature substance is transferred to watermark embossing rollers ( 5 ). During the embossing process, these watermark embossing rollers partially transfer the feature substance onto the paper web, as an image of the embossing stamp, or parts of the image of the embossing stamp. 8. Procedure for testing electrically conductive feature substances in This makes special papers for documents, securities and banknotes characterized in that the feature substance according to its data of the electrical Conductivity and or other physical quantities and or chemical Properties to achieve a multiple test is detected. 9. Procedure for testing the electrically conductive feature substances in special papers for documents, securities and banknotes is characterized in that the Feature substance is partially or homogeneously coated on the paper web. 10. Use of a test procedure for testing electrically conductive characteristic substances in sheet material is characterized in that the sensor for detecting the electrical conductivity consists of a variety of scanner channels, by means of optical, magnetic and or mechanical - electrical sensors activated becomes. 11. Use of a capacitive test method for testing electrically conductive feature substances in sheet material is characterized in that the capacitive scanner sensor ( 11 ) is formed over the entire width of the sheet material. 12. Test methods for testing electrically conductive feature substances in the sheet material are characterized in that the scanner sensor is designed to reduce the leakage coupling and thus small differences in the electrical conductivity of adjacent test zones of the printed image can be measured by controlling the sensor channels ( 21 , 22 ). is carried out in such a way that the channels with even numbering ( 21 ) take place in the first scanning process and the channels with odd numbering ( 22 ) take place in every second scanning process. The scanning frequency is preferably 200 kHz. 13. Test methods for testing electrically conductive feature substances in sheet material characterized in that the distance between the transmitting electrodes and Reception electrode switchable according to the test structures and test level is. 14. Test methods for testing electrically conductive feature substances in sheet material characterized in that the electrically conductive feature substance has its own Has reaction in the optical spectral range. These optical properties are used as a reference value for electrical conductivity as a double test of this Feature used.   15. The arrangement of the scanner sensor to the sheet material to be checked is thereby characterized that him to optimize the sheet transport opposite a hold-down in the form of a roller or a slide rail is arranged. 16. The arrangement of the scanner sensor to the sheet material to be checked is thereby characterized in that the sensor electrodes in two levels to the sheet material are arranged. This means that a functional electrode side above the Sheet material is arranged and the other functional side below the sheet material is arranged. 17. The arrangement of the scanner sensors for checking the paper web for production quality on the paper machine is characterized in that a large number of scanner sensors ( 11 ) are arranged over the entire width of the paper web in order to check compliance with the production parameters. 18. The arrangement of the scanner sensors for checking the paper web Production quality on the paper machine is characterized in that the Arrangement according to claim 17, a control circuit for regulating the feature substance addition is downstream.