RU2123723C1 - Device for checking validity of banknote - Google Patents

Abstract

FIELD: bank equipment. SUBSTANCE: device has ultraviolet source with gas-discharge lamp, photodetector, power supply, actuating unit and comparator. Input window of photodetector is directed for receiving both power reflected from banknote under investigation and light of gas-discharge lamp. In saturation mode additional opaque wall may be mounted between gas-discharge lamp and input window of photodetector. Said wall is equipped with hole through which light of gas-discharge lamp is passed towards input window of photodetector. Area of window in wall conforms to condition excluding possibility of operation of photodetector in saturation mode in case of simultaneous receiving light of gas-discharge lamp through window in wall and power reflected from banknote under investigation with maximal amplitude values. EFFECT: increased validity of checking, decreased cost of manufacturing and repair. 2 cl, 1 dwg

Description

 The invention relates to devices for recognizing the authenticity of banknotes or securities and can be used in the development and manufacture of devices for the automatic control of the authenticity of banknotes or securities for bank employees.

 A known machine for rejecting banknotes [1], containing a thickness sensor, a fluorescence detector (ultraviolet irradiator, filter, photocell and electronic detector of the level of radiation), a block of photocells passing through a banknote light to measure the length, a piezoelectric head to determine the unevenness of the protective pattern, a photometer to determine transparency of watermarks, a pair of photometers for scanning by moving the test and reference banknote and comparing the controlled banknote from both sides with the reference th.

 A banknote recognition device [2] is also known, in which paper is irradiated with ultraviolet radiation and radiation induced in the paper substance is detected using a photo sensor.

 In addition, a device for recognition and verification of banknotes (3) is known, in which the banknote is illuminated by a source of visible light and a source of ultraviolet radiation. Visible radiation passing through the banknote is perceived by a line of photosensors located across the banknote movement, as well as by additional photosensors, each of which has its own filter. Reflected ultraviolet radiation is detected by its sensor.

 The above-mentioned known devices allow you to control the authenticity of banknotes, but they have a significant drawback, namely, they do not have the ability to adapt to changes in the level of radiation of energy by a gas discharge lamp in a source of ultraviolet radiation due to its aging, as well as the spread of its other parameters when installing and replacing it during repair.

 Optical reading systems [4] are also known, incorporating a lighting lamp, photodetectors, and nonlinear amplifiers for generating logical signals of acceptable levels. In these known systems, the output operating voltage of each receiver also depends on the life of the lamp and its temperature. The aforementioned disadvantage in known reading systems is largely eliminated by the introduction of an additional photodetector scanning a completely clean track. Its signal after amplification by a buffer amplifier and tuning by means of resistors is used as the setting of the switching threshold of all other readout amplifiers from other tracks. However, this well-known technical solution does not allow to completely eliminate the above drawback, since it is technologically impossible to manufacture all photodetectors (in the case under consideration, silicon photodiodes) with exactly the same technical characteristics, therefore, a change in the brightness of the illumination lamp due to its aging will cause a change in the output signal of each individually a photodetector by an amount depending on its specific parameters and naturally differing from the magnitude of the signal change by the output of other photodetectors. This drawback adversely affects the accuracy of the measurements, which reduces the reliability of the authenticity control results, and also entails the need for a large amount of work related to setting up and adjusting the electrical circuit of the authentication device, as well as during repair work.

The proposed electrical circuit of the banknote authentication device is aimed at solving the following problem:
- increasing the reliability of the control of the authenticity of banknotes and securities;
- reducing the complexity both in the manufacture of authenticity control devices and during repair work during their operation.

 To solve the aforementioned problem, a new, more advanced electrical circuit of the banknote authenticity verification device is declared, comprising an ultraviolet radiation source with a gas discharge lamp, a photodetector, a reference voltage source, an executive unit and a comparator connected by the first input to the output of the photodetector, and the second input to the output of the reference voltage source . Unlike the known ones, in the inventive control device, the receiving window of the photodetector is oriented with the possibility of receiving both energy re-radiated from the controlled banknote and direct radiation from a gas discharge lamp, the reference voltage source is connected by its signal input to the output of the photodetector, and the control input to the first output of the determination unit the presence of banknotes in the zone of its control, the output of the comparator is connected to the input of the executive unit through a managed key, the control input of which is connected to the second output Lok determine whether the banknote in the region of its control.

 If necessary, when the radiation power of the source is excessively large, between the gas discharge lamp of the ultraviolet radiation source and the receiving window of the photodetector, an opaque barrier can be installed with a hole for the radiation from the source to pass to the receiving window of the photodetector. The hole area in the opaque partition is selected from a condition that excludes the possibility of the photodetector operating in saturation mode while receiving re-emitted light energy from a controlled banknote with a maximum amplitude and direct radiation from a discharge lamp.

A block diagram of a banknote authentication device is shown in the drawing, which shows:
1 - a source of ultraviolet radiation,
2 - power source of a discharge lamp,
3 - gas discharge lamp,
4 - lightproof partition with a hole,
5 - photodetector,
6 - comparator,
7 - voltage reference source,
8 - block determining the presence of banknotes in the zone of its control,
9 - managed key,
10 - Executive unit
11 - controlled banknote.

 The block diagram of the banknote authenticity control device contains an ultraviolet radiation source 1 with a gas discharge lamp 3 connected to its power source 2, a photodetector 5, a comparator 6 connected by a first input to the output of the photodetector 5, and a second input to the output of the reference voltage source 7, and the output through the managed key 9 to the input of the executive unit 10. The reference voltage source 7 is connected to the output of the photodetector 5 by its input, and the control input to the first output of the unit for determining 8 the presence of banknote 11 in its zone control. The controlled key 9 is connected with its control input to the second output of the determination unit 8. The receiving window of the photodetector 5 is oriented with the possibility of receiving both energy re-radiated from the controlled banknote 11 and direct radiation from the gas discharge lamp 3 of the ultraviolet radiation source 1. If necessary (an excessively high radiation power of source 1), between the gas discharge lamp 3 of the ultraviolet radiation source 1 and the receiving window of the photodetector 5, a lightproof partition 4 can be installed with an opening for the radiation to pass from the source 1 towards the receiving window of the photodetector 5. The area of the hole in the lightproof partition 4 is selected from a condition that excludes the possibility of operation of the photodetector 5 in saturation mode while receiving the re-emitted light energy from the control uemoy banknote 11 with the maximum amplitude and the direct radiation from the discharge lamp 3.

 If there is no banknote 11 in the zone of its control, the corresponding electrical signal from the first output of the sensor 8 is fed to the control input of the reference voltage source 7 and puts it into operation, in which the constant voltage at its output changes in proportion to the change in the signal from the output of the photodetector 5 to the input the reference voltage source 7, and from the second output of the sensor 8, an electrical signal will be supplied to the control input of the key 9 and switch it to the closed state, at which the passage of electric signal from the output of the comparator 6 to the input of the Executive unit 10.

 If the banknote 11 is in the control zone, the corresponding electrical signal from the first output of the sensor 8 will go to the control input of the reference voltage source 7 and put it into operation, in which the output voltage of the source 7 preceding this signal is stored and remains unchanged while the banknote 11 will be in the zone of its control, and from the second output of the presence determination unit 8, the corresponding electrical signal will go to the control input of the key 9 and switch it to the open state, when which is possible the passage of an electrical signal from the output of the comparator 6 to the input of the Executive unit 10.

 Consider the operation of the device in the case when there is no banknote 11 in the zone of its control.

 In this case, only that part of the ultraviolet radiation of the source 1 will pass to the input of the photodetector 5, which will pass through the hole in the diaphragm 4. Since there is no banknote 11 in its control zone, the possibility of receiving re-emitted light energy by the photodetector 5 will also be absent. The ultraviolet radiation received at the input of the photodetector 5 will be converted into the corresponding electrical signal, which will be fed to the input of the reference voltage source 7 and the first input of the comparator 6. Under its influence, a constant voltage is generated in the reference voltage source 7, which is proportional to the input voltage coming from the output of the photosensor 5. Any change in the input voltage caused by the influence of both external factors and the departure of the parameters of the components of the electrical circuit (aging gasor a discharge lamp, a change in the parameters of the photodetector as a result of its replacement, etc.) automatically causes a proportional change by the corresponding value of the constant voltage at the output of the reference voltage source 7. The constant voltage from the output of the reference voltage source 7 is supplied to the second input of the comparator 6, and its first input receives an electrical signal from the output of the photodetector 5. Since the controlled key 9 is in the closed state under the influence of the corresponding signal received at its input Since the second output of the unit for determining the presence of 8 banknotes 11 in the zone of its control, any changes in the signal at the output of the comparator 6 will not lead to the actuation of the executive unit 10.

 The operation of the authentication device in the case when there is a banknote 11 in the zone of its control.

 In this case, in addition to the part of the ultraviolet radiation of the source 1, which passed through the hole in the lightproof partition 4, in addition to the part of the reradiated energy in the visible range from the banknote 11 being monitored, the electric signal at the output of the photodetector 5 will accordingly increase and will continue to be vary in proportion to the change in the total energy received at the input of the photodetector 5. An electrical signal from the first output of the location determination unit 8 will be applied to the control path of the reference voltage source 7, which then transfers it to the operating mode, in which its output voltage will have a constant fixed value and will not change under the influence of an input variable signal coming from the output of the photodetector 5. From the second output of the unit for determining the presence of 8 banknotes 11, the corresponding electrical signal will be fed to the control input of the key 9, which after that will go into the open state, in which the passage of the electrical signal from the output of the computer is possible 6 to the input of the executive unit 10. Depending on the degree of authenticity of the banknote being monitored, there will be a change in one direction or another of the electrical signal at the output of the photodetector 5, and this will cause the comparator 6, and then the executive unit 10 to respond, which will produce the results control banknote authenticity information.

 Due to the fact that the formation of the reference voltage supplied to the input of the comparator 6, as well as the reception and processing of the working signal are carried out using the same discharge lamp 3 and the same photodetector 5, changing their parameters under the influence of external factors, natural aging, or replacement as a result of repair work will not affect the reliability of the authenticity control, since, for example, a decrease (increase) in the brightness level of a glow of a discharge lamp 3 will automatically lead to a decrease ( Accelerating) as one of the working signal and the reference voltage and the same value, so the results of comparison in the comparator 6 above changes will have no effect. Due to the foregoing, the proposed technical solution successfully solved the problem.

 The inventive device for controlling the authenticity of banknotes can be serially manufactured under production conditions using standard equipment and modern materials. Based on the results of the work, prototypes of the product that implements the claimed invention in full were manufactured and tested with positive results.

Sources of information:
1. British patent N 1430099, G 07 D 7/00, 1976.

 2. British patent N 2029009, G 07 D 7/00, 1980.

 3. Patent EPO N 0101115, G 07 D 7/00, 1984.

 4. Vulvet J. Sensors in digital systems. - M.: Energoizdat, 1981, p. 36 - 38.

Claims (2)

 1. A banknote authenticity control device comprising an ultraviolet radiation source with a gas discharge lamp, a photodetector of energy reradiated from the controlled banknote, a reference voltage source, an executive unit and a comparator connected by the first input to the output of the photodetector, and the second input to the output of the reference voltage source, characterized in that the receiving window of the photodetector is oriented with the possibility of receiving both energy re-radiated from the controlled banknote and direct radiation from the gas discharge amp, the reference voltage source is connected by its signal input to the output of the photodetector, and the control input is connected to the first output of the banknote determination unit in the zone of its control, the comparator output is connected to the input of the executive unit via a controlled key, the control input of which is connected to the second output of the presence detection unit banknotes in her control zone.  2. The device according to claim 1, characterized in that between the gas discharge lamp of the ultraviolet radiation source and the receiving window of the photodetector there is a lightproof partition with a hole for passing radiation from the gas discharge lamp in the direction of the receiving window of the photodetector, while the area of the hole in the lightproof partition is selected from the condition excluding the possibility of the photodetector operating in saturation mode in the case of simultaneous reception of radiation from a gas discharge lamp as a light through a hole in the light barrier aemoy septum and reemitted light energy from the controlled banknote with the maximum amplitude values.