RU2651436C1 - Device for devaluation banknote sheaves - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: invention relates to the field of banknote antitheft protection. Additional result is a low consumption of the depreciating agent. In the device placed inside the evacuated bag, the casing is made of a deformable material, containing a container filled with a fluid viscous depreciating substance, the shell of which is at least partially made of a deformable material, wherein at least a portion of the deformable part of the shell is in contact with the envelope of the evacuated bag, the deformable part of the shell being configured to reduce the internal volume of the container when deformed in conjunction with the envelope of the bag. Device comprises an activation means configured to connect the inner cavity of the container to the inner cavity of the evacuated bag in which the banknotes are placed, in response to a predetermined change in the predetermined physical factor acting from outside the envelope of the evacuated bag.

EFFECT: ensuring a reliable operation of the devaluation of banknotes, with the exception of the negative impact of the device on personnel and property.

14 cl, 4 dwg

Description

The invention relates to the field of protection of banknotes from theft. Since the late 60s, a method of guaranteed depreciation of banknotes has been widely used to protect banknotes from theft. According to this method, the container for storing or transporting banknotes is equipped with a depreciating device that is triggered in case of theft or attack and has a certain depreciating effect on the banknotes. As such an impact, the most widely used instant staining of banknotes with special indelible paint. Irreversible bonding of banknotes to each other or exposure of banknotes to a destructive agent, for example, a solvent or caustic, is somewhat less commonly used. After the depreciating device is triggered, the banknotes that were in the container for storage or transportation lose their solvency and can no longer be used by criminals as money.

The practical experience of using depreciating devices in many countries has proved the effectiveness of this method of protection. When criminals know that banknotes in the event of theft will necessarily be discounted, theft or robbery itself makes no sense. States that legally allow the use of guaranteed depreciation of banknotes carry out extensive public outreach so that the meaninglessness of stealing banknotes from banks, ATMs, cash machines and containers becomes apparent to the entire population. It is important that the central banks of these countries ensure the reception of impaired cash from the affected organizations with full compensation of its nominal value. Therefore, the affected organizations do not suffer large financial losses as a result of the operation of the depreciating device. In these countries, over the past decades, the number of cash thefts, attacks on banks and collectors has sharply decreased.

Modern types of depreciating devices, as a rule, provide a quick supply of paint to banknotes using a spring, pneumatic or explosive mover. So, in the patent of the Russian Federation No. 2362864 (PCT publication WO 2005/010306 of 03/03/2005) a device for supplying ink to banknotes stacked in a bundle in a storage container is disclosed. The paint is contained in a container made of plastic film. At the moment of activation of the depreciating device, the container with paint is strongly compressed with the help of a pre-charged spring mechanism, while cutting through the container shell. Paint under pressure is ejected from the device onto a bundle of banknotes. Further, the paint, under the action of capillary forces, wets the banknotes and passes into the gaps between them. In this way, it is possible to color all the banknotes in a bundle, however, the average staining area of each banknote usually does not exceed 50-60%.

Another device is disclosed in RF patent No. 2526707 (PCT publication WO 2011/110830 of September 15, 2011). In this device, paint under pressure is supplied to the system of tubes with holes located around the stack of banknotes from different sides. The paint is located inside the flexible corrugated fur, which, in turn, is placed in the cylinder and preloaded by the piston. When the device is activated, carbon dioxide is supplied to the cylinder from the back of the piston under pressure. The source of carbon dioxide is a miniature cylinder. To open the cylinder, a pyro cartridge is used, ignited by an electric signal. This device, as well as the previous one, cannot provide complete coloring of banknotes, since the advancement of the paint deeper into the pack occurs solely under the influence of capillary forces.

In the patent of the Russian Federation No. 2190075 (PCT publication WO 98/01646 dated January 15, 1998) a collection case is described, where the paint is also in a container made of plastic film. The capacity in the suitcase is located next to the bundles of banknotes. Between the bundles of banknotes and the container with paint is a strip of tape explosive. On the wall of the suitcase near the container with paint is a U-shaped reflector of the blast wave. To activate the depreciating device, detonation of an explosive is created. The blast wave breaks the container with paint, and then, reflected from the U-shaped reflector, is sent back to the side of the banknotes. The paint is carried away by the blast wave and at high speed is thrown towards the bundles of banknotes.

All three described devices work well when bundles of banknotes do not have additional packaging, such as a plastic bag. However, the devices according to patents No. 2362864 and No. 2526707 do not provide for the depreciation of banknotes packed in plastic bags, since they do not provide a structural unit for opening the bags, and the paint in these devices cannot penetrate inside the bag.

The depreciation of banknotes packed in a plastic bag is an important task. Packing bundles of banknotes in individual plastic bags is used very often. In particular, in the Russian Federation, the majority of interbank transportation of banknotes is carried out in so-called vacuum packages. A pack of banknotes is placed in a plastic bag, air is pumped out of it and the neck of the bag is welded by heat welding. Bank details are applied on the weld by embossing. The contents of the package are compressed by atmospheric pressure from all sides, due to which the banknotes are pressed against each other, cannot be shifted, so that the entire bundle acquires high rigidity. The receiving bank can easily verify the integrity of such a package, since the slightest violation leads to a loss of vacuum and loss of the characteristic stiffness of the package.

To depreciate banknotes packed in plastic bags, special technical means are used to violate the integrity of the package and ensure the passage of paint to its contents. Of particular difficulty is ensuring the passage of paint into the evacuated bag, since a thick and strong multilayer plastic film is usually used for its manufacture. In the aforementioned patent No. 2190075, a blast wave propagating from tape explosives both directly and due to reflection from a U-shaped reflector serves to destroy a plastic bag. An alternative technical solution is presented in patent EP 1499787 (published on January 26, 2005). This patent discloses a pneumatic mechanism for moving a system consisting of a plurality of hollow needles. When the destruction device is activated, the mechanism moves the needles in the direction of the bundles of banknotes, tears the plastic bags with the needles, and then injects the depreciating agent through the needles into each bag.

It is necessary to note the general shortcomings, to one degree or another, characteristic of the above technical solutions. Firstly, in order to provide any reliable staining of banknotes, it is necessary to moisten the edges of all banknotes in the pack abundantly and maintain moisture for some time for the ink to penetrate inside the pack. Therefore, it is necessary to feed a large amount of paint in the direction of the bundle of banknotes, which significantly exceeds the useful volume absorbed by the bundle. Excess paint contaminates and damages equipment (for example, collection bags and ATMs), which requires a mandatory repair after each actuation of the depreciation device, including false. False positives, as a rule, due to various unavoidable reasons, occur more often than real thefts and robberies. Excess paint easily falls on staff clothing and irreversibly spoils it. If excess paint gets on the skin of staff, which often happens when dismantling a triggered device, it is almost impossible to wash it. It should also take into account the rather high cost of the paint itself.

Secondly, the penetration of paint into the gap between banknotes occurs under the action of capillary forces, which do not allow to achieve a high degree of staining of banknotes, even with heavy irrigation of their edges.

Thirdly, most devices (with the exception of those described in patent No. 2362864) use pyrotechnic means to one degree or another. In the event of a false operation of the device in the immediate vicinity of personnel, the sound of an explosion, shaking, and the appearance of smoke cause negative psychological consequences. This effect is especially noticeable when the explosion is the main mover in the device. When the mover in the device is compressed gas, traumatic consequences may occur during dismantling of the triggered device due to the residual gas pressure in its elements.

The device according to patent No. 2190075 provides a sufficiently reliable opening of vacuum-packed bags and a relatively high degree of staining of banknotes due to the effect of the pressure of the blast wave. The flip side of these advantages is the need for a thorough repair or even a complete replacement of the collection case due to the impact of a strong explosion after the device is triggered. To ensure the safety of people during an explosion, the suitcase has a powerful force structure, which is associated with the high cost of its manufacture.

Thus, the most common drawback of the above technical solutions can be considered the possibility of a negative impact on personnel and property in the event of a depreciation device, including a false one.

The device according to patent No. 2190075 was selected as a prototype of the claimed invention. The claimed invention is intended solely for use in conjunction with evacuated bags.

The technical result of the claimed invention is to ensure reliable operation of the device for the depreciation of banknotes while eliminating the negative impact of the device on personnel and property. An additional result is the low consumption of the depreciating agent itself.

The specified technical result is achieved in that in a device for depreciating banknotes packaged in a pack in an evacuated bag placed inside an evacuated bag, the shell of which is made of a deformable material containing a container filled with a fluid viscous depreciating substance, the shell of which is at least partially made of a deformable material, and at least a portion of the deformable part of the shell is in contact with the shell of the evacuated bag, while the th part of the shell is made with the possibility of reducing the internal volume of the container during deformation together with the package shell, and also containing activation means configured to connect the internal cavity of the container with the internal cavity of the evacuated bag in which the banknotes are placed, in response to a predetermined change in a given physical factor acting from outside the shell of the evacuated bag.

As a result of evacuation, a plastic bag forms a stable and rather rigid structure around a bundle of banknotes and a security device. This structure is well known to those skilled in the art of vacuum packaging technology. Under the influence of atmospheric pressure, the envelope of the packet is pressed against the contents of the packet. In this case, numerous folds and voids are formed around the contents, since the flat sheet of plastic film from which the bag is made cannot exactly take the form of the contents of the bag. These folds and voids communicate with each other both directly and through the contact areas of the film with a bundle of banknotes. The connecting channels are formed both due to the roughness of the banknotes themselves, and gaps along the ends of the bundle of banknotes. Thus, we can talk about a single cavity, including a bundle of banknotes and a network of voids and channels around it.

The portion of the shell of the evacuated bag is pressed against the portion of the deformable part of the shell of the container due to the vacuum in the gap between them and the atmospheric pressure outside the packet. Therefore, there is contact between the portion of the deformable part of the container shell and the shell of the evacuated bag, so that atmospheric pressure is applied to the viscous fluid inside the container. Accordingly, a viscous fluid inside the vessel is at atmospheric pressure. At the moment of activation of the activating device, the internal cavity of the container is connected with the internal cavity of the evacuated bag, and a viscous fluid from the container under the influence of pressure difference begins to flow into the internal cavity of the package, where banknotes are placed. As the ink exits the container, its volume decreases, which leads to the retraction of the deformable part of the container inside. Together with it, under the influence of atmospheric pressure, the envelope of the packet, which is in contact with the area of the deformable part of the tank, also shifts. This is due to the ability of the materials of the container and the package to deform with a decrease in internal volume. As a result of maintaining contact between the shells, atmospheric pressure is maintained inside the vessel. The fluid viscous substance that has escaped into the internal cavity of the bag diverges along the system of channels and voids around the bundle of banknotes, penetrates the inter-banknote gap and impregnates the banknotes in the bundle. Moreover, it, under the influence of the pressure difference, moves towards voids and pores, in which there is still vacuum.

The described operation of the depreciation device is highly safe for humans and equipment. It is not accompanied by an explosion, concussion and other sounds, smoke and gas, and the flow of a depreciating agent. All fluid viscous substance remains closed inside the bag, does not damage the container for storing and carrying banknotes, skin and clothing of staff. Since the volume of voids in the evacuated bag is small, filling them requires a small flow rate of a viscous fluid, in comparison with the large volume of freely spilling depreciating agent in other known solutions.

Another additional technical result of the claimed device is a high degree of coverage of banknotes with a depreciating agent. This result is achieved when the shell of the tank is made in such a way that due to the deformation of its deformable part, it is possible to reduce the volume of the shell by an amount exceeding the volume occupied by the vacuum in the evacuated bag.

Under these conditions, the process of flowing of a viscous fluid flows uninterruptedly until all cavities and pores inside the bag are filled with this substance. At this point, the pressure of the flowing viscous substance in the container and throughout the cavity of the package is equalized and becomes equal to atmospheric. It is obvious that the volume of the container shell at this moment becomes less than the initial one by the amount of the volume initially occupied by the vacuum in the evacuated bag. An additional volume of fluid viscous substance could be forced out of the tank during further joint deformation of the shell of the evacuated bag and the deformable part of the shell of the tank in contact. However, due to the equality of pressure outside the bag and in the tank, such deformation and displacement no longer occurs. This excess of depreciating substance is a reserve for technological deviations in the process of evacuation, which can lead to a small unplanned increase in the volume occupied by the vacuum in the bag. Liquid paint may be used as a fluid viscous depreciating agent.

Let us consider in more detail the process of flowing at its last stage. In interbanknote gaps and in the pores of the banknotes themselves, vacuum continues to be maintained at this time. Fluid viscous depreciating substance from the voids of the bag rushes into the inter-banknote gap and fills the pores of the banknotes under the influence of a significant pressure difference. This process extends from the edges of the banknotes to their center, and in the already filled gaps, the pressure increases and approaches atmospheric. This leads to the fact that the compression force between the banknotes, which previously existed due to the vacuum, weakens, and the gaps between them expand. Accordingly, the passage section for the movement of a fluid viscous depreciating substance increases, which further accelerates the process of its flow to the middle of the banknotes.

The same effect of the expansion of the bore is observed in the channels, the walls of which are partially formed by the portion of the package shell. Initially, the cross section of the channel can be narrowed due to atmospheric air pressure on the channel wall and vacuum inside the channel. However, as a fluid viscous depreciating agent enters the channel, the pressure in the channel increases and begins to counteract the atmospheric pressure on the outer wall. This leads to an increase in the cross section of the channel. An increase in the cross section propagates in the direction of flow of the viscous viscous depreciating substance, like a wave, along with the propagation of increased pressure of the viscous viscous depreciating agent. The described effect accelerates the propagation of the viscous viscous depreciating agent throughout the cavity of the bag. When the process reaches its completion, then in the channels the total pressure on the wall of the packet turns out to be zero, so that the force compressing the channels and reducing their cross section is completely absent.

The degree of coverage of the surface of banknotes with a depreciating substance turns out to be close to 100%, since the process of passing a fluid viscous depreciating substance into interbanknote gaps lasts until each gap is completely filled with this substance. Due to the passage of a fluid viscous depreciating substance into the pores under the action of vacuum, the banknotes are intensively saturated, even if the banknote material has poor wetting.

As already indicated, the process is very economical with respect to the consumption of the depreciating substance. For the intensive penetration of a fluid viscous depreciating substance into a pack, only a small reserve excess of this substance is needed in relation to the amount consisting of a small amount of voids in the bag and the usable volume directly absorbed by the pack. This economy is important due to the relatively high cost of the depreciating substance.

A bundle of banknotes, before placing it in a bag for evacuation, can be further tightened by a strip of packaging tape. A bundle of large banknotes can be folded from several bundles, each of which is pulled together with packing tape. The presence of such bands of packaging tape does not significantly affect the operation of the claimed device.

The device according to the claimed invention is intended for use as part of a security system of a container for transporting or storing banknotes. In such a container is placed one or more evacuated bags, in each of which there are banknotes, as well as the device according to the claimed invention. It is assumed that the container is equipped with a security system controller, which, using sensors, detects the occurrence of a threat and decides to depreciate the banknotes stored in the container. As soon as a security risk arises, the container controller, through a certain change in the specified physical factor, transmits an activation signal to the activating device of each of the evacuated packets inside the container. An activating device that detects a given change, starts the process of depreciating banknotes in the package.

As a physical factor, electromagnetic waves of various ranges or acoustic waves can be used. A change in the physical factor, such as a change in the power of waves of a certain length or their disappearance, a change in the wavelength, as well as manipulation of the wave parameters to transmit a code message, can be used as an activation signal. Various types of communication channels well known in the art can be used to transmit an activation signal. For example, a short-range radio channel, such as an NFC channel, may be used. The use of this channel for a banknote marking system is described, for example, in international application WO 2015/165965 (published on November 5, 2015). The radio communication channel, due to the free propagation of radio waves, allows you to place the evacuated packets in the container in any orientation and in any order. However, it requires special measures to counter attempts to suppress activation signals from criminals using an NFC standard transceiver or jamming device.

An optical infrared communication channel is another possible option for transmitting an activation signal. An example of such a channel in a banknote security system is described in US Pat. No. 8,534,207 (publ. 06/30/2011). The advantage of infrared radiation is the inability to intervene in the transmission process in the communication channel without opening the container. However, the optical communication channel requires sufficiently accurate pointing of the radiation receiver and transmitter to each other, as well as the absence of obstacles for the passage of radiation between them. This imposes additional restrictions on the location of evacuated packets in the container.

The activation signal can also be transmitted using acoustic waves, such as tonal or percussive sound. This approach has certain advantages over the use of radio waves and infrared radiation. The acoustic signal is weakly sensitive to the location and orientation of the packets in the container, since the sound wave can propagate throughout the container and through the air in the gaps between the packets and through the packets themselves. The low level of acoustic noise is typical for all stages of the cash life cycle and allows you to accurately transmit a loud acoustic signal. An abnormally high level of noise and vibration, in itself, can be considered as one of the signs of a dangerous situation and used as an initiator of unconditional activation. Thus, criminals have few opportunities to suppress the acoustic activation signal.

To counter the attempts of cybercriminals to suppress the communication channel, the absence of reception of a pre-agreed, regularly repeated message can be used as an activation signal. If the attacker manages to suppress the communication channel, then regularly repeated packages cease to be accepted by the activation device, which serves as a signal for him to start the process of depreciating banknotes in the packet.

Certain changes in physical factors that usually accompany criminal access to banknotes can be directly used to activate the device. This can be a high level of vibration and shock acceleration, a sharp change in temperature and other similar factors.

A practical implementation of a banknote protection device according to the claimed invention is shown in FIG. 1-4.

In FIG. 1 shows a device placed in an evacuated bag along with a bundle of banknotes and ready for use.

In FIG. 2 shows the device and the evacuated bag after activation and completion of the depreciation process.

In FIG. 3 shows a simplified electrical schematic diagram of an activation device.

In FIG. 4 shows a container for carrying packaged cash equipped with a security system using several of the described banknote protection devices.

The bundle 1 of banknotes is placed in an evacuated bag 2. In direct contact with one of the surfaces of the bundle 1 there is a device for protecting banknotes (3-10). It consists of a base 3, an activating device, made in the form of a printed circuit board 4, containing a block of 5 electronic components, as well as a container 6 with paint 7. The shell of the tank 6 protrudes above the base 3 and the elements of the activating device 4, 5. The shape and volume of the shell 6 chosen in such a way that its volume, due to the deformation of the deformable part, can be reduced by an amount slightly exceeding the volume occupied by the vacuum in the evacuated bag 2.

In the base 3 and the printed circuit board 4, a through hole 9 is made for the passage of paint from the container 6 to the bundle 1 of banknotes. Coaxially with this hole, a ceramic ring-shaped heating element 8 is mounted on the printed circuit board. The container 6 with paint 7 is adjacent to the surface of the printed circuit board 4 and the heating element 8. The task of the heating element 8 is to open the shell of the container 6 by melting the plastic film from which the container shell is made. At the time of activation, an electric voltage is supplied to the heating element 8, it heats up and melts a portion of the shell of the container 6. This opens up access for the ink 7 to exit from the container 6 into the hole 9.

The surface of the base 3, facing the bundle 1 of banknotes, contains a network of recessed grooves 10, diverging from the hole 9 to all four edges of the base. This network of grooves serves for the quick passage of paint 7 through the opening 9 to the side surfaces of the stack 1. For the same purpose, the size of the base 3 is chosen slightly larger than the size of the banknotes in the stack 1. When evacuating, the film of the bag 2 covers the edges of the base and the side surfaces of the pack, forming with additional channels along the perimeter of the base.

To supply voltage to the heating element 8, the activating device contains an electrical circuit, which will be described in detail below. The electronic elements of this circuit are located in area 5 on the printed circuit board 4, filled with a rigid sealing compound. Compound filling is designed to protect against the effects of vacuum on electronic components, some of which may not be designed to work in low pressure conditions.

In FIG. 3 shows a simplified electrical diagram of an activation device. It contains a controller 12, to which a rechargeable battery 13 is connected, an induction antenna 14 for receiving and transmitting NFC signals, a heating element 8 and an external power connector 15. The controller 12 is made on the basis of the microcontroller microcircuit and also contains elements (not shown) necessary for control the charge and discharge of the battery 13, receive and transmit radio signals through the antenna 14, and apply voltage to the heating element 8. While in the vacuum package, the activation device is powered from the battery 13. The connector 15 allows you to charge the battery 13 before using the banknote protection device.

In the cavities and channels of the evacuated bag 2, the pressure is close to zero, while inside the container 6, the paint 7 is at atmospheric pressure. This is due to direct contact of the portion of the deformable shell of the container 6 with the deformable shell of the bag 2, which, in turn, is pressurized by atmospheric air.

Upon receipt of an external activation signal through the antenna 14 in the form of a certain code package of the NFC standard, the controller 12 supplies the supply voltage to the heating element 8. The power of the heating element 8 is selected so that for a short time, within a few hundred milliseconds, it would warm up to the melting temperature of the shell of the vessel 6. As soon as this temperature is reached, a slot is formed in the shell of the vessel 6 in the central zone of the heating element 8, through which into the hole 9 from the vessel 6 under paint 7 starts to come in under the pressure of the sphere. The paint moves under the action of the pressure difference in the container 6, on the one hand, and in the cavities and channels of the bag 2, on the other. It passes through the hole 9, diverges along the grooves 10 and then spreads over the entire surface of the pack 1 through the voids, channels and gaps. For distinction, the paint passing through the hole 9 is indicated in FIG. 2 using the number 11.

As the ink exits the container 6, the portion of the container shell and the portion of the package 2 in contact with it are deformed and together are displaced toward the inside of the container 6, as shown in FIG. 2. The contact between the portion of the shell of the container 6 and the portion of the shell of the bag 2 in contact with it is maintained as it deforms, since there is still a vacuum in the gap between them at this time. In the container 6, due to the specified contact, the paint 7 continues to be under atmospheric pressure.

In the process of the ink leaving the container 6, a certain change in the shape of that part of the packet 2, which covers the bundle of banknotes 1, takes place. Before activation, sections of the shell of the evacuated packet are either pressed against objects inside the packet by atmospheric pressure or are concave by this pressure into the packet. A stable position of the concave parts is achieved due to the high tension of the shell. When a paint under atmospheric pressure fills the voids of the bag 2 near the edges of the base 3, the effect of atmospheric pressure outside the bag is balanced by the pressure of the liquid from the inside of the bag. The forces of pressure and tension acting on the shell of the package in these places are sharply reduced. Under the action of the elasticity of the material of the shell of the bag and banknotes in the bundle 1, an increase in the volume of cavities and channels near the edges of the base 3, as well as their passage sections. This allows the ink to quickly move further along the surface of the stack of 1 banknote. In the volume newly occupied with paint during this advancement, the balancing of external and internal pressures and the corresponding increase in the flow cross sections also occur. The paint advances again, and this process continues until the entire pack is surrounded by a layer of paint, as shown in FIG. 2. The paint in this layer is under atmospheric pressure. The new stable shape of the package shell around the pack is only slightly different from the original, since its change occurs mainly under the action of elastic forces. However, this change plays an important role in accelerating the spread of paint throughout the package.

When a bundle of 1 banknote is surrounded by paint on all sides under atmospheric pressure, areas filled with vacuum still remain inside the bundle. This applies to both interbanknote gaps and the pores between the paper fibers of the banknotes themselves. Under the influence of the pressure difference, the paint rushes into these areas and completely fills them. A similar process is well known from the technology for manufacturing electronic components and is called vacuum impregnation. The effect of the expansion of cavities and gaps under the action of paint, which we described above for the package shell, exactly affects the expansion of inter-bank gaps. At the initial moment, the banknotes are tightly pressed against each other by atmospheric pressure, however, as the paint passes into the gaps between them, the pressing force drops to zero, the gaps expand and the passage of paint is further accelerated. As experience shows, pack 1 is completely saturated with paint for several seconds.

It should be noted that the choice of the electric heater 8 as a means to ensure the connection of the internal cavity of the container 6 with the internal cavity of the evacuated package 2 is due to the simplicity of this design. However, instead of the electric heater 8, any device for cutting through the shell of the container 6 can be used, for example, a sharp blade or tip moved by an electric motor or a solenoid. You can also use an electrically controlled valve mounted in the wall of the tank 6, the output channel of which is connected to the hole 9. For the specialist, various possibilities of implementing the above means for ensuring the connection of the cavities are obvious. It is important that this tool, when triggered, does not release a significant amount of extraneous gases into the internal volume of packet 2. The appearance of extraneous gas in the package 2 reduces the level of vacuum and affects the efficiency of the device.

The depreciating substance 7 can be not only a liquid, but also a gas. Initially, the gas can be placed in the tank 6 under atmospheric pressure. In the case of a gaseous depreciating substance, the same physical processes take place that were described above for the case of using liquid paint. In the case of activation, the gaseous depreciating substance under pressure from the container 6, the spreading of the depreciating substance through the packet 2, its passage into the interbanknote gaps and the expansion of the passage sections of the channels occur similarly to the case of using liquid paint. Unlike liquid paint, the gaseous depreciating substance has a very low viscosity, so the depreciation process can be much faster. To further increase the response speed, the depreciating gas can be placed in the tank 6 under a pressure slightly higher than atmospheric, and the shell of the tank 6 is made inextensible. In this case, after operation, the shape of the packet 2 will change in the direction of increasing its volume, which will lead to a significant increase in the passage sections of the channels and even greater acceleration of the response.

Consider the use of banknote protection devices in a container security system for carrying packaged cash. As shown in FIG. 4, the container 16 is designed to carry several bags with banknotes 17. The structure and composition of each of the bags 17 are shown in FIG. one.

Also, the container 16 is equipped with a security controller 18, which is connected to several sensors 19. These sensors can detect the opening of the container, an attempt to violate the integrity of its shell, shock or explosion, as well as a sharp change in temperature. The security controller 18 is equipped with an NFC standard transceiver, which allows you to communicate with the activation devices of all packages 17 located in the container 16. In addition, the controller 18 can communicate with the authorization device 20, which must be placed outside the container 16, near its surface.

Information packets on the NFC communication channel in the security system are transmitted in encoded form. Coding is organized in such a way that parcels with the same information content are transmitted using constantly changing codes. Encryption keys are secretly stored in all devices exchanging information 17, 18, 20, but are not accessible to the attacker. This method of secure exchange is well known and is used, for example, in the management of car security devices. Due to such encoding, the attacker is deprived of the opportunity to decode informational packages and cannot interfere in the exchange, having formed his own package for maliciously managing the security system.

Initially, at the place of packing the cash, banknote protection devices (3-10) are used that have a charged battery 13 and are in a neutral mode of operation. A banknote protection device in neutral mode is awaiting receipt of additional encoded commands over an NFC standard radio channel.

Banknote protection devices are placed in bags 2 over a stack of banknotes 1, vacuumized and sealed. The resulting bags 17 are folded into a container 16 and the container lid is closed. Further, using the arming button connected to the controller 18 (not shown), the controller 18 is placed in the armed mode. The controller 18 transmits to the device activation packages 17 command entry into the armed mode. After receiving this command, the activation devices begin to track the activation signal. Such a signal can be either the receipt of an activation command or the absence of a special communication check command for a given time. It is assumed that the command to check the connection, in the absence of alarm, should be issued by the controller 18 several times per second, and its absence within one to two seconds should lead to the activation of the device in package 17. The received activation command should immediately activate the device in package 17.

After transferring the activation devices of all packets 17 to the armed mode, the controller 18 constantly transmits a command for checking communications with an interval of several hundred milliseconds. As soon as a dangerous operation of the sensors 19 is detected, the controller 18 stops transmitting communication verification commands and transmits an activation command several times in a row. Having received the activation command, the activation device in each of the packages 17 starts the depreciation process by applying voltage to the heating element 8. As a result, all banknotes in the container are depreciated.

If the attacker tries to interfere with the security system by suppressing radio communications between the controller 18 and packet activation devices 17, this will lead to the loss of communication verification commands. As soon as the activation device detects the disappearance of several communication test commands that must follow in a row, it starts the depreciation process by supplying voltage to the heating element 8.

To exit the security mode, it is necessary to bring the authorization device 20 to the container and instruct it to disarm the system. By this command, the controller 18 transmits several times the disarming command for the packet activation devices 17. Having received this command, each of the activation devices goes into neutral mode. After that, the container can be opened without causing depreciation of the banknotes stored in it.

Claims (14)

1. A device for depreciating banknotes packed in a pack in an evacuated bag placed inside an evacuated bag, the shell of which is made of a deformable material, containing a container filled with a fluid viscous depreciating material, the shell of which is at least partially made of a deformable material, at least at least a portion of the deformable part of the shell is in contact with the shell of the evacuated bag, while the deformable part of the shell is made to reduce Cored oil volume of the container during deformation together with the package wrapper, and also comprising activation means operable to connect the inner cavity of the container with the interior of a vacuum package, in which the banknotes are placed, in response to a predetermined change in a given physical factor acting from outside shells evacuated package. 2. The device according to p. 1, in which the shell of the tank is configured to reduce the volume of the tank during deformation of its deformable part together with the shell of the bag, by an amount exceeding the volume occupied by the vacuum in the evacuated bag. 3. The device according to p. 1, 2, in which the fluid viscous depreciating substance is a liquid paint. 4. The device according to p. 1, 2, in which the means of activation contains an electric heater in contact with the shell of the tank and made with the possibility of its local heating to a temperature at which there is a violation of the integrity of the shell. 5. The device according to p. 3, in which the means of activation contains an electric heater in contact with the shell of the tank and made with the possibility of its local heating to a temperature at which there is a violation of the integrity of the shell. 6. The device according to p. 1, 2, in which the specified physical factor acting from the outside of the shell of the evacuated packet is a radio signal. 7. The device according to claim 3, in which the specified physical factor acting from the outside of the shell of the evacuated packet is a radio signal. 8. The device according to claim 4, in which the specified physical factor acting from the outside of the shell of the evacuated packet is a radio signal. 9. The device according to p. 1, 2, in which the specified physical factor acting from the outside of the shell of the evacuated packet is the radiation of the optical range. 10. The device according to p. 3, in which the specified physical factor acting from the outside of the shell of the evacuated packet is the radiation of the optical range. 11. The device according to p. 4, in which the specified physical factor, acting from the outside of the shell of the evacuated packet, is the radiation of the optical range. 12. The device according to p. 1, 2, in which the specified physical factor acting from the outside of the shell of the evacuated packet is the acoustic effect. 13. The device according to claim 3, in which the specified physical factor acting from the outside of the shell of the evacuated bag is an acoustic effect. 14. The device according to claim 4, in which the specified physical factor acting from the outside of the shell of the evacuated packet is the acoustic effect.

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