DE1292912B - Securities testing device - Google Patents

Description

The invention relates to a security validation device with a device to be examined Security from one side illuminating radiation source and on the opposite Side of the security arranged radiation-sensitive cells to determine the Intensity of the transmitted radiation.

To test paper webs or sheets of paper for defects, it is known to irradiate the sheets with a light source as they pass through a test station - and to scan the reflected light with a photocell. When faults occur, there is a jump in the output current of the photocell, with the help of which a control mechanism is actuated, which guides the faulty sheet via a transport switch to a reject pile, while the sheets found to be good are directed to a good pile. However, it is not possible to use such a simple device, which only responds to irregularities in an otherwise uniformly barking surface, to check the authenticity of banknotes with a complicated structure in terms of color and pattern.

There are also devices for sorting beans are known at where the beans are individually illuminated and guided past two photo cells, with the help of which the light reflected from each bean is determined. At a of these known devices, one photocell is a green feed, the other Photocell is preceded by a red filter, so that the intensity of these two color components is converted into electrical signals which the deflection electrodes of a cathode ray tube are fed. The screen of this tube is covered with a mask, which only releases a certain area, which is a certain range of colors as well corresponds to the beans to be found. Another photocell is arranged in front of the mask, which is only illuminated when the light spot of the electron beam is Tube is located within the good area. If the device is faulty in its color Bean out of this area and is thus covered by the mask, so becomes the photocell in front of the mask is not illuminated, and in this case you changed output current causes the bean in question to be excreted. These extremely complicated known device is only able to check whether a certain color range can be determined by two basic colors with regard to its mean color value of an object to be tested is adhered to. An exam the correctness of different color schemes arranged in a certain way and brightness ranges, as required for checking banknotes, however, it is not possible with this complex arrangement either.

For sorting coins of different denominations according to their size, a sorting device is known in which the coin channel through which the coins pass individually is changed by inserting certain slide panels, the cutout size of which corresponds to a certain type of coin, and thus for the one to be sorted Coin size is set. In this way, similar to the effect of a sieve, unsorted coins can be separated in several passes according to their size and thus their value. However, this known device, which only sorts according to size, is not able to determine coins of other currencies or counterfeit coins which correspond in size to one of the coin types defined as well. A transfer of this principle for checking bank notes would be completely pointless as any pieces of paper, which coincide only in size with a common bill would be adopted as gül- term currency.

Finally, a device is known for checking banknotes, in which the bank note to be checked is compared with a standard bank note, by scanning both banknotes simultaneously with the help of synchronously guided light beams the reflected light is measured with photocells in both cases, whose output signals are the same in the case of a valid bank note being checked. If there are deviations in the output signals, the bank note entered will be deemed invalid rejected. However, the synchronous guidance of the two scanning beams requires a considerable effort in terms of the precision of the mechanics deflecting the light beams. If both sides of the banknote are to be checked, the A second checking process is required on the reverse side, in which of course the standard banknote must also be turned over. In addition, this allows purely according to the reflection principle working device does not control the paper quality of the banknote, so that so also counterfeit banknotes, the imprint of which is copied with some skill is, however, printed on the wrong paper, are accepted as genuine.

In another known bank note, the banknote to be examined is contacted with the negative of a standard banknote and checked visually to cover deviations in this way to exhaust. Since the mirror mechanism, with the help of which this optical coverage is brought about, cannot be adjusted so precisely in the long term and, moreover, the position of the bank note to be checked cannot be determined so precisely to fractions of a millimeter that the desired optical coverage is exactly achieved, so To ensure that the covering surface has exactly the same brightness at all points, the known device uses a complicated movement mechanism which causes the negative and the illumination lens system to oscillate continuously so that practically averaged values are checked. Although the transparency of the bill and thus the paper quality is also recorded in this test device, the complex and wear-and-tear oscillation mechanism results in a relatively high price for this device.

The object of the invention is to create a Security checking device, which with a relatively simple structure, high operational reliability and virtually no wear and tear, a comprehensive review of securities, viz on the mutual pattern and the quality of the paper material in one operation permitted. Despite the test within a narrow tolerance range, operation should of the device.

According to the invention, this task is also carried out with a security checking device a radiation source illuminating the security to be examined from one side and radiation-sensitive arranged on the opposite side of the security Cells for determining the intensity of the transmitted radiation by detaching that the cells are interconnected to form groups, each of which is a particular one Intensity limit is assigned, and that the individual groups with one when reaching the top Limit at least one group, appealing, an acceptance of the security preventive lock are connected.

The division of the cells into groups enables different color coverage areas to be checked separately. The mean value of the ink coverage of each of these areas must not fall below a certain value, i. H. the color coverage must not be too weak if the security is to be found to be good.

The cells can be interconnected to form such groups that the correspond to respective areas of different color saturation. You can use the Select the number of groups according to the complexity of the color pattern. the The spatial delimitation of the different cell groups depends on the shape of the different saturation ranges. Has been used for checking banknotes For example, it has been shown that three different groups of cells are sufficient to deal with sufficient Security to determine the validity of a banknote.

So are with an execution form for the examination of dollar bills three different groups of cells for three different permeability areas accordingly arranged in the colors black, green and white of the banknote.

Leave for checking other banknotes, securities or documents the cell groups in a simple way to form groups of other spatial Toggle shape. The scope of application of the device according to the invention is thus very large versatile.

To further increase the security when recognizing the validity of a bank note can be the group of cells assigned to the areas of high permeability to a further one, if a lower limit value of the permeability is not reached these areas responsive lock be switchable. This results in a additional criterion for the authenticity check that not only validates the Maximum values of three different permeability ranges dependent on, makes, rather introduces a further limit value for one of these ranges, above which the determined permeability of this area must be. If it was difficult If three different limit values have to be observed in the case of a forgery, then the imitation becomes of a security is made considerably more difficult by this additional criterion, because the admissibility range, which is only determined by two limit values, is the can be chosen quite narrow, extremely difficult to adhere to in an imitation is. Especially when it comes to recognizing the use of the wrong type of paper, whose deviations from the original paper are precisely in the area of increased permeability noticeable, a significantly improved accuracy.

The locks can be designed in an expedient manner as relays, the contacts of which are inserted in series in züi interrupting lines. The contacts of the relay responding to the upper limit value can be designed as normally closed contacts, whereas the contacts of the relay responding to the lower limit value can be designed as normally open contacts. Such relays can be controlled in a simple manner by the cells of the associated group, which cells, for example, are designed as photocells, so that the C desired contact actuations are triggered. 22 To control the timing of the test program, the device according to the invention can have a time control device, for example in the form of a switching motor, which carries out various contact switching when executing a revolution and in this way allows the individual phases of the test to run automatically Test device are described in the following description with reference to the representations of an exemplary embodiment. It shows F i g. 1 shows a side view of the opened device according to the invention, FIG. FIG. 2 shows a partially broken plan view of the mechanical part of the device according to FIG. 1, Fig. 3 shows a side section along the line 3-3 according to FIG. 2, Fig. 4 shows a section along the line 4-4 according to FIG . 2, fig. 5 shows a section along the line 5-5 according to FIG. 2, Fig. 6 is a view from below and FIG. 7 shows an electrical circuit diagram of the device according to FIGS. 1 to 6.

When examining a security, this is used to determine its double-sided imprint and its material transilluminated4 so that with the help of the Cells the amount of transmitted through various selected sections of the paper Rays is measured. The cells control certain processes within the device. The cells are interconnected according to the pattern of the security to be checked, so that this pattern does not apply to other papers. Similarly, can a pattern for use on papers with certain groups of letters or Signs, for example checks, tear-offs, entry or travel tickets, paper, plastic Od. Like., As long as the base material is at least a certain Degree of light transmission.

The paper or means of payment 20 to be checked is arranged within an opening 22 which extends transversely to a carriage or drawer 24 and which has dimensions such that it receives the means of payment in a flat position. The slide plate 24 is guided by the side guides 26 and 28 to move its flat top 30 on a table 32 , it can be moved from a rest position ( solid line in FIG. 2) to a call position (dashed line in FIG . 2). be moved.

In the test position, the paper is brought between a light source 32 and a plurality of light-sensitive cells 34 which are arranged in groups such that they lie beneath selected parts of the paper which are differently transparent. For example, the cells located under parts printed with green ink are indicated by 34 g and the cells arranged below parts printed with black ink indicated by 34 b. The parts with high light transmission that are not printed underneath are marked with 34 w.

In order to allow the light to impinge on the parts of the paper or currency overlying the cells 34, the flap 36, which is moved into the opening 22 receiving the currency, is equipped with windows 38 which are aligned with the cells.

The slide plate 24 is locked in the test position for the duration of the light test by means of a pawl finger 40 on the end of a crank lever 42, which can swing back and forth about its joint 44 between a locking and unlocking position. In the dashed lines in FIG. 2, the finger 40 is advanced forward into the path of a block 46 which is fixedly attached to the underside of the slide plate 24 in order to prevent the return of the slide plate to the normal position. In the in F i g. 3 Unriegelungsstel-Jung, shown with solid lines, the pawl finger is outside the path of the block 46 in order to enable automatic return movements of the slide plate into the starting position with the aid of the spring 48. One end 50 of the springs is attached to the table while the other end is attached at 52 to a pin 54 which is integral with wall 56 which is part of the frame attached to the top of the table and extending over the test section is. Buffers 58 attached to the table extend into the path of the slide plate in order to keep the latter in the rest position, while in the test position they abut against other buffers 60 which are also attached to the table.

The slide plate and the flap are provided with slots 62 and 64, respectively, which extend longitudinally across the central part of the opening in alignment approximately with the central part of the paper or currency 20 which is located therein in the test position. The table top also has a similar slot 66 which is aligned with the slots 62 and 64 when the carriage plate is shifted to the test position to allow the bill to be removed from the carriage plate by means of a pusher 72.

The slide plate 72 is mounted on a vertically arranged frame plate 70 which is fastened to the frame. It can be moved between a raised or retracted position ( FIG. 4) and a lowered or operating position ( FIG. 3) . In the raised position, its lower edge is spaced from the carriage plate, while in the operative position it extends through the carriage plate and the aligned slots so that the lower edge extends below the underside of the table. The slide plate 72 is moved into the operating position by means of a magnet 74, which acts via a rod 76 and a spring 78 and pivots the lever arm 80 about its joint 82, against the retaining force of the helical spring 84. If the magnet is not switched on and the rod 76 protrudes from the magnet, the force of the retaining spring 84 predominates in order to bring about the return movement of the slide plate 72 into the normal position. The plate 72 is guided during its movement by means of vertically spaced apart supports 86 and 88 which are fastened to the frame plate 70 and extend through a continuous longitudinal slot 90 in the guillotine. The supports also limit the movement of the plate between them. Operating position and the withdrawn position.

Under the table are shown in FIGS. 3 and 6, a pair of shafts 92 and 94 are arranged, which are provided with rollers 96 and 98 which are arranged at a distance from one another and cooperate in pairs. The shaft 94 is an electromagnet with a drive shaft 100 - connected to the motor 102, while the other shaft is freely rotatable in bushings 104, the voltages in slotted Öff- are slidably received in the depending side walls of the table 106th The shaft 92 is pressed against the other shaft 94 by means of helical springs 108. The distance between the rollers 96 and 98 of each pair is greater than the width of the plate 72, but less than the width of the security paper 20, so that the rollers only detect this.

The test device has a switch arm 110 which is connected to the switch 112. and protrudes into the movement path of the security when it has been pulled down by means of the slide plate. When the switch arm 110 is pushed, the switch 112 is closed so that the further operations can be carried out, for example the delivery of corresponding change for the means of payment of the particular value, e.g. B. by means of the in F i g. 6 labeled C facility.

In addition, the security is checked for its correct dimensions before the slide plate is in the test position and the light transmission test is carried out. Two switches 114 and 116 are used for this, which are arranged laterally at a distance from one another on the underside of the table, and whose switch arms 118 protrude upwards through openings 120 in the table. The edge of the security touches it when it is moved into its end position for checking. The distance between the switch arms 118 is just about the width of the paper 20. If the switches 114, 116 are closed and they remain closed during the test processes, the subsequent locking and test can be carried out. If, on the other hand, they are not closed, the slide plate is not locked and slides back into the rest position.

In the following description of the operation of the machine as a money changer, it is assumed that the coin tubes are appropriately filled with coins so that the switch 130 is closed and no current is passed via the line 132 to the blank lamp 134 which indicates when one or more tubes are empty are. If the slide plate 24 is initially in the starting position, the flap 36 can be pivoted into the raised position, as shown in FIG. 4 is shown in dashed lines ". After inserting a bill, the flap is closed and holds the bill.

The slide plate can be moved into the test position by means of the button 136 , the bill then coming to lie between the light source 32 and the photocells 34. If the dimensions are correct and the bill lies properly flat, its leading edge 122 presses against the switch arms 118 of the switches 114 and 116, so that these are closed. A current then flows via line 140 and switch 130 to line 142 and via switch 144 to line 146. Current passes from line 146 via coin tube closure relay 148 to line 150, via reset relay switch 152 to line 154 and via the closed ones Switches 116 and 114 to line 156 to latch magnet 158 which pivots the latch lever 42 to the latch position while at the same time the switch arm 160 is actuated to close the switch 162. This positions the pawl pin 40 opposite the block 46 to hold the carriage plate in the test position. When the ratchet lever is moved into the locking position, the switch 162 is closed, and current flows from the line 164 via the line 166 to the starter relay 168, which closes the switch 170 , so that the cycle motor 174 is switched on via the line 162. The clock motor rotates a rotor 176 standing on the over line 180 to the network in Verbindun (y 'center strip 178 grinds and successively a light contact 182, a switch relay contact 184, a scraping contact 186, a reset contact 188, and a motor contact 190 sweeps before he runs back to the starting position.

The timing engine provides the further decrease run the test program. After the lamps 32 have been switched on via the contact strip 182 , the contact strip 184 receives current and the switch relay 192 picks up, so that its switches 194 switch over to bypass the potentiometer 196 and the associated resistance winding 198 as well as the switch 200. Penetrates from the lamps 32 do not have enough light through the above the cells 34 b and 34 - located areas of the note, so that the relay 204 is not responsive, then the switches 206 and 208 remain closed. If the light falling on cells 34 w is sufficient to cause relay 210 to respond, switches 212 and 214 are closed. If the rotor 176 then comes to the stripping contact 186, current can flow via the lines 216, the switch 208 and the switch 214 to the stripping motor 102, so that the rollers 96 and 98 coincide.

After the stripping motor 102 has started, the stripping switch 218 is closed, for example by shifting its drive shaft 100; as a result, the stripping magnet 74 receives current. The rod 76 is withdrawn and the pusher plate 72 moves downward through the aligned slots 62, 64 and 66 , folds the bill and pushes it through the slot 66 into the gap of the underlying roller pairs 96 and 98 Front edge of the bill to the switch arm 110 and closes the switch 112. The black cells and the green cells 34 b and 34 g are each connected in parallel, so that when the cells are illuminated above the predetermined value, the relay 204 is actuated and the switches 206 and 208 opens. This means that the stripping motor 102 can no longer be switched on.

Regardless of whether the bill can be accepted or not, the rotor 176 of the timing motor 174 passes on the reset strip 188 so that current can flow on the line 272 to the reset relay 224 which resets the magnets 74 and 158 and the various switches; the slide plate is released for a return movement into the normal position. After actuation of the reset relay 224, the current cannot flow to the motor 174 via the previous Weo, but rather it flows via the motor contact strip 190 and the line 226 directly to the clock motor 174, which then completes its cycle.

In order to operate the alternating motor or other dispensing motor 228 , current must flow through the switch 112, which is closed in response to the displacement of the bill from the carriage plate. It flows over the switch 114, 116, which has meanwhile been switched back. The switches 206, 208, 212 and 214 also remain closed. To improve the reliability of the test, a further limit value is checked for the white transmittance. For this purpose, a potentiometer 198 and an auxiliary relay 192 are also provided, which is switched on by the contact strip 184 and is connected to the relay 204 at one of the contacts of the switch 194 in order to control the contact switches 206 and 208.

The potentiometer 196 is set in such a way that the contacts are actuated at a predetermined maximum current which is generated by the white cells 34 w located below the points of high light transmission. If the rotor 176 runs with the light contact strip 182, the current generated by the cells 34 w flows out through the potentiometer. If the current is above the amount to which the potentiometer is set, the switch allows current to pass from line 230 to line 240 and via contact switch 194 to line 242. The line 242 leads to the relay 204 and makes the relay open 206 and 208 so that the device operates the contacts, such as when an excess of light through one or more of b or 34 g lying areas over the black or green cells 34 transmits would have been, so that the certificate does not meet the test conditions and the operation proceeds as described above. If the amount of light transmitted via the white cells does not exceed the maximum power generation, the relay 204 remains unaffected and the bill meets the acceptance condition.

If the rotor 176 continues to run and comes into contact with the relay strip 184, the current runs over the line 244 to the switch relay 1.92 to open the contact 194 and the switch 200, whereby the potentiometer is switched off and the white cells stop the operation of the Do not influence relay 204 any longer. Under these circumstances, the test returns to the original condition described earlier and determines whether the amount of light transmission through the bill is sufficient. The current from cells 34 w flows past the potentiometer. If sufficient current is generated by the cells, the current in line 230 flows via line 240 and switch 194 to line 246 which leads to relay 210 so that switches 212 and 214 are closed when the light transmission is sufficient.

This additional test is carried out during the time segment within which the rotor 176 is moving from the light contact strip 182 to the relay contact strip 184.

Claims (1)

1. A Wertpapierprüfgerät with the marked to be examined securities from one side of the illuminating radiation source and on the opposite-C to the side of the security arranged radiosensitive cells to determine the intensity of the transmitted radiation d a d u rch that the cells (14) into groups ( 34b, 34g, 34w) are interconnected, each of which is assigned a specific intensity limit value, and that the individual groups are connected to a lock (204, 206, 208) which prevents acceptance of the security and which responds when the upper limit value is reached at least one group . In that a respective group of cells is less for regions (b 34) is provided 2. Wertpapierprüfgerät according to claim 1, characterized in that the medium (34 g) and high (34w) permeability of the security. 3. Securities checking device according to claim 1 and 2, characterized in that the group (34w) assigned to the areas of high permeability can be switched to a further lock (210, 212, 214) which responds when a lower limit value is not reached. 4. Security checking device according to spoke 1 to 3, characterized in that the locks are designed as relays (204 or 210) with series-connected contacts (206, 212 or 208, 214). 5. Security checking device according to claim 1 to 4, characterized in that the contacts (206, 208) of the relay (204) responding to the upper limit value as normally closed contacts and the contacts (212, 214) of the relay (210) responding to the lower limit value are designed as working contacts. - 6. Security checking device according to claim 1 to 5, characterized in that the radiation source is designed in a manner known per se as a light source (32) and the cells (34) are designed as light-sensitive cells.