RU2394975C2 - Compressing device for reservoir with paint for contamination of documents in protected chamber - Google Patents

Abstract

FIELD: printing industry.

SUBSTANCE: device comprises support frame, movable element that determines plane of reservoir support, and moving element. Actuation of moving element provides for motion of movable element. Moving element comprises pyrodynamic facilities, which, prior to its actuation, provide for application of even pressure to reservoir ready for perforation. After actuation of moving element its pyrotechnical actuation releases movable element with provision of its dynamic motion. Application of uniform and evenly distributed compressing force to reservoir provides for dynamic motion of specified movable element into final position, parallel to initial position, in which reservoir is empty from its content.

EFFECT: invention provides for full compression of reservoir and full usage of substance or liquid in contamination of precious documents or objects.

9 cl, 3 dwg

Description

The present invention relates to a compression device for a reservoir containing a contaminant or liquid, and can be used, in particular, for the safety of transporting classified documents or valuable objects with the aim of pouring said substance or liquid onto said documents or objects in case of danger, said contaminant the device is preferably used in a security cassette-type chamber for the automatic issuance of tickets or bills, as well as in a security chamber such as a container and for transporting the protected mentioned documents or valuable items from origin to destination.

Polluting devices usually contain an energy source, an electronic circuit that controls the operation of the aforementioned device and causes the device to compress the tank when a burglary signal is received or a burglary attempt is made, the signal coming from thermal, hydraulic, gyroscopic, infrared contact sensors, position sensors and etc. capable of recognizing any deviation from the normal state. When turned on, the squeezing device compresses the reservoir containing a coloring or aggressive substance or liquid, thus ensuring a violation of the integrity of the reservoir with the release of the substance or liquid, while the compressed substance or liquid is poured by means of spraying onto valuable documents or objects, which are damaged.

Various compression devices are known to those skilled in the art, however, they usually use the same principle based on the triggering of a pyrotechnic charge, which provides a shock wave or emits gas with high intensity, these factors either directly compressing the tank or moving plates or pistons that compress said reservoir or directly expel contaminant fluid.

Compressing devices and / or devices for contamination, as a rule, are not leakproof, which follows from their concept; this entails the loss of gas released during the explosion of the pyrotechnic charge, which leads to a decrease in the intensity of the impact pulse and, consequently, to a decrease in the compression force acting on the tank.

As for devices in which the force generated by the shock wave upon the explosion of the pyrotechnic charge acts directly on the reservoir, for example the device described in document WO 92/07159, it should be noted that the distribution of force is not uniform, so that the reservoir is compressed by accidental law, and the tank is not emptied properly.

As for the compression devices, including a piston, made, as a rule, in the form of a plate, moving to compress the reservoir deep into the body of the polluting device, for example, the device described in patent application FR 2858005, when the charge explodes, a force is applied to the plate with a high intensity, but distributed extremely unevenly; therefore, there is a high likelihood of the slope of the plate inside the device body with the possibility of jamming of these two elements, which leads to a decrease in the compression force of the tank and restrict the movement of the plate, which also takes an inclined position. Therefore, the tank does not empty completely.

The spraying means of the polluting device are designed to distribute the polluting liquid poured out during the explosion into the various zones of the protected chamber in order to cover a combination of valuable documents or objects. Therefore, as a rule, it is envisaged to perforate the reservoir at several points in order to inject liquid into the totality of channels intended for its supply to spraying means. Due to the uneven distribution of the compression force acting on the reservoir, the perforation of said reservoir occurs non-synchronously, and the liquid pouring mode from the reservoir changes depending on the time intervals between the perforation of various holes and the random compression mode of the reservoir; therefore, contamination does not occur evenly, and some of the valuable documents or objects can still be recovered after hacking.

Other contaminating devices are also known, for example, the device according to French patent application 2836461, which describes a cylindrical device consisting of a central chamber of circular cross section, closed from the end faces by two covers and containing a polluting liquid. Each of these covers is provided with a circular fault line located on the periphery. Each of the covers contains a cylindrical axial part, one of these parts being solid and the second hollow, and these two cylindrical parts are mounted with the possibility of sliding one relative to the other, like a piston. These sliding mounted parts comprise a pyrotechnic gas generator. When the pyrotechnic gas generator is triggered, gas is released into the parts mounted with the possibility of sliding; the pressure of this gas ensures the separation of the two covers that cover the chamber along the fault line. After separating the covers from the chamber, the pressure inside the sliding parts repels one of the said covers from the other, with the covers sliding along their cylindrical parts. In this case, the covers are removed from one another until the stops formed by plugs located at both ends of the cylindrical device are reached.

At the same time, the chamber opens, which ensures the pouring of contaminating liquid through the holes formed when the covers located at the ends of the chamber are displaced, and the liquid pours out through the outlet openings made in plugs.

Also known is US patent application 2004/0007165, which describes a contaminating device for protecting against theft. This device comprises a movable element consisting of at least one pressure plate, a reservoir, and moving elements driven by a mechanical starting device.

The moving element makes it possible to move the pressure plate from the initial position, in which the tank is full and closed, to the final position, in which the tank is perforated and empty. The moving element consists of springs that exert pressure on the pressure plate. When the springs are weakened, the plate moves and compresses the tank, providing for its perforation and emptying from contaminating paint.

The principle of operation of the device described in the application 2004/0007165 is purely mechanical. This mechanical action device is influenced by the holding force of the pressure plate, while the holding force is proportional to the pressure created by the springs located under the plate, and said springs serve to move the plate when the mechanism is triggered. The operation occurs when the mechanism is moved in case of unauthorized access to the polluting device, in which the pressure plate is released. Thus, the holding force counteracts the movement of the mechanism. This mechanism may accidentally stall and interfere with the effective operation of the device.

The present invention provides a new type of compression device for a tank or bag, which can be adapted to any type of contaminant device of valuable documents or objects, ensures a favorable distribution of the compressive force exerted by the plate on said tank, with the aim of simultaneously punching it in various places provided for this and ensuring uniform coverage of valuable documents or objects, leading to their complete unsuitability for use.

Another advantage of the present invention is the provision of full compression of the tank and, thus, the full use of a substance or liquid when contaminating valuable documents or objects.

Another advantage of the present invention is the guarantee of direct pressure on the reservoir in the compression device in order to ensure uniform perforation of the reservoir and, thus, uniformly pour out of the ink contained therein to cover valuable documents or objects.

The aim of the present invention is also to provide direct operation of the compression device without the risk of failure of the starting device and to provide instant perforation of the tank when trying to unauthorized opening of the contaminant device.

To this end, in accordance with the present invention, there is provided a compression device for a reservoir containing a substance or liquid suitable for use, in particular, in contaminating devices for pouring said substance or said liquid onto valuable documents or objects, containing a support frame defining a plane “Re ", A movable element consisting of at least one pressure plate for compressing the tank, defining in its initial position the plane" P "of the tank support, parallel to the plane "Re", and a driving element driven by a trigger device located inside or outside said compression device, the actuation of the moving element causing the moving element to move from its initial position, in which the tank is full and closed, to its final position, in which the reservoir is perforated and emptied from its contents, characterized in that the moving element contains pyrodynamic means, providing application of uniform pressure to the tank, ready to be perforated, and then, after activating the said moving element, its pyrotechnic actuation, releasing the movable element, providing dynamic rectilinear movement of the plane "P" of the said moving element in the direction remaining perpendicular to the plane "Re", and ensuring a uniform and uniform distribution of the compressive force of the movable element to the tank and the dynamic movement of the said movable element in its final the second position, parallel to the initial position, in which the tank is completely empty from its contents, which is removed by continuous and uniform pouring.

It is understood that pyrodynamic means provide uniform and uniform compression of the reservoir, which guarantees its simultaneous perforation in the provided zones of the said reservoir and the same mode of pouring out a substance or liquid from each of the aforementioned perforated zones.

In accordance with one embodiment of the invention, the pyrodynamic means include fixing means for connecting the movable element in its initial position to the support frame, the fixing means being destroyed when the moving element is actuated, and means for dynamically moving the movable element to the end position, which it is separated from the support frame. The locking means may include a connecting part between the movable element and the support frame and pyrotechnic means capable of destroying said connecting part when the moving element is actuated. The connecting part may contain a zone of destruction, ensuring the destruction of the aforementioned connecting parts when triggered pyrotechnic means.

In one embodiment of the invention, the means for dynamically moving the movable element comprise a group of inertial springs providing perforation of the reservoir and a group of dynamic springs providing continued dynamic movement of the movable element to its final position.

In accordance with another embodiment of the invention, the suspension means include prestressed springs.

According to another embodiment of the invention, the movable element consists of at least two plates, the first intermediate plate being connected to the support frame at the initial position of the movable element, and the second plate spring-loaded in the plane “P1” parallel to the plane “Re” of the support frame, providing uniform pressure on the tank at the initial position of the movable element. In one implementation, the two plates of the movable element are closed to form a common plane “P” and instantly create a joint uniform compression force of the tank under the action of the means for moving when the connecting part between the first intermediate plate and the supporting frame is destroyed.

Other advantages and features of the present invention will be apparent from the description below with reference to the accompanying drawings, of which:

- Figure 1 is an exploded perspective view of a compression device of the present invention;

- Figure 2 represents an axonometric image of the compression device in an assembled form;

- figure 3 shows a protected chamber equipped with a contaminant device in which a compression device is used, which is the subject of the present invention.

As shown in FIG. 3, the compression device 1 that is the subject of the present invention is preferably used, but not limited to, for contaminating valuable documents or objects 3 placed in a security chamber 5, for example, in a cassette for automatically dispensing tickets or banknotes , or in a container used for transportation under guard. When the protected chamber 5 is broken into, the starting device 7, located inside or outside the compression device 1, activates the said compression device, which compresses the reservoir 9 containing a contaminant or liquid, which is poured through the spraying means 11 and contaminates valuable documents or objects 3, making them unusable.

The specialist can extend the application of the described device to any other area where it is necessary to uniformly compress the reservoir or package to extract its contents.

In accordance with FIG. 2, the compression device 1 includes a support frame 13, a movable element 15 and a moving element 17. Activating the moving element 17 causes the moving element 15 to move from its initial position, called “cocked”, in which the tank 9 is full and closed , in the second position, called "released", in which the said tank 9 is perforated and emptied from its contents.

The supporting frame 13 is located in the reference plane "Re" and in the preferred embodiment has the shape of a rectangular parallelepiped with an open top face 19, for example, an open box, and its dimensions ensure the placement of the components of the moving element 17.

The movable element 15 includes at least one plate located in the plane "P" shown in Fig.2, corresponding to the plane of the support of the tank 9, shown in Fig.2 in the working position with dash-dotted lines. According to a preferred, but not restrictive embodiment, said movable element 15 is in the form of a rectangular parallelepiped with an open bottom face 21, for example a cover, and its dimensions are significantly larger than the dimensions of the support frame 13. Thus, the movable element 15 covers the dimensions of the support frame 13 and covers a plurality of parts the moving element 17, when the compression device 1 is in the assembled state, that is, ready for action, and gives this device the shape of a rectangular box, covered with a lid and having a slight thickness. The advantage of this arrangement of the device is the possibility of its placement in any polluting device.

As shown in FIG. 1, the movable element 15 in the preferred, but not restrictive embodiment, consists of two plates 23 and 25. The plate 23 is located above the intermediate plate 25 and is identical in shape to that described in the previous paragraph of the plate of the moving element 15 including one plate. The plate 23 has an opening 29 on the upper surface 27; said upper surface 27 is in the plane "P1".

The intermediate plate 25 has a rectangular shape and is configured to slide inside the plate 23 through the lower face 31 of the latter. On its upper face 33, the plate 25 has a protruding part 35 located in the plane "P2" parallel to the plane "P1"; the size and shape of the protrusion 35 correspond to the size and shape of the hole 29 of the plate 23. When the two plates 23 and 25 are assembled, the upper surface 37 of the intermediate plate 25 rests on the inner surface 39 of the upper surface 27 of the plate 23, and the protrusion 35 is pushed into the hole 29 so so that the two planes “P1” and “P2” coincide and lie in the same plane “P” shown in FIG. 2, thus providing a joint effect on the reservoir 9. In the initial position of the movable element 15, the reference plane “P” is parallel plane "Re" of the supporting frame.

The driving element includes pyrodynamic means, which, when the starting device 7 is actuated, provide continuous dynamic movement to the movable element 15, which moves along a straight path, the direction of which remains constantly perpendicular to the plane "Re". Thus, the movable element 15 in the process of its movement is constantly located in the plane "P" parallel to the plane "Re", until the final position is reached, in which the tank 9 is perforated and emptied from its contents. In this case, the movable element 15 maintains an unchanged position of the supporting plane, which ensures uniform distribution of pressure on the reservoir 9, and the removal of a substance or liquid from the reservoir 9 occurs by continuous and uniform pouring onto valuable documents or objects 3.

Pyrodynamic means include, first of all, the fixing means 41, which provides the connection of the movable element 15 with the supporting frame 13 in the initial position of the compression device. This fixing means 41 is destroyed when you try to break into the protected chamber 5, while the movable element 15 is separated from the support frame 13. Said fixing means 41 includes a connecting part 43 and pyrotechnic means 45 capable of destroying the said connecting part 43 when the driving element 17 is actuated .

According to a preferred, but not limiting embodiment, the connecting part 43 is a monoblock metal element, the first part 47 of which is connected to the movable element 15 or to the plate 25 (in a preferred embodiment, in which said movable element consists of two plates 23 and 25, as described above). The second part 49 of the connecting part 43 is connected to the support frame 13. The connection of the two parts 47 and 49, respectively, with the plate 25 and the frame 13 is preferably made with screws. However, the possibility of using any other connecting means is implied.

The connecting part 43 contains a fracture zone 51 defining a rupture plane “Pr” between the two parts 47 and 49, as shown, for example, in FIG. Pyrotechnic means 45 comprise a pyrotechnic detonating cord and a detonation device, preferably suitable for remote operation; a pyrotechnic detonating cord, not shown in the figures, crosses the connecting part 43 in the fracture zone 51, providing the possibility of destruction of the said connecting part 43 along the rupture plane "Pr" when the pyrotechnic charge is triggered; however, the first part 47 is separated from the second part 49, thereby separating the movable element 15 from the supporting frame 13.

Other embodiments of the locking device 41 are also clear to those skilled in the art; said fixing device 41 may be made, for example, on the basis of two magnetized parts, one of which is attached to the movable element 15, and the second to the supporting frame 13; in this case, when the driving element is activated, the magnetic field is removed, as a result of which said movable element is separated from the support frame.

Pyrodynamic means include, in addition, means 53 for moving the movable element 15 from the initial to the final position, in which the tank 9 is perforated and empty to contaminate valuable documents or objects. These moving means 53 are released when the connecting piece 43 is destroyed, while instantly compressing the reservoir 9.

According to a preferred, but not restrictive embodiment, the means 53 for moving consist of a plurality of springs 55, 57, 59, 61, 63, 65, 67, and 69, of which the springs 55, 57, 59 and 61, hereinafter referred to as “inertia springs”, provide overcoming the inertia of the movable element in the initial position, and the springs 63, 65, 67 and 69, hereinafter referred to as "dynamic springs", provide continued dynamic movement of the movable element 15 to the final position.

The inertia springs 55, 57, 59 and 61 are supported by their bases 71 on the bottom 73 of the support frame 13, which is preferably provided with a plurality of locating pins 75, shown in FIG. 1, providing an appropriate arrangement of the said inertia springs, whose upper ends 77 abut against the lower surface 79 plates 25. Preferably, four inertia springs with the same technical characteristics are used, uniformly spaced along the working surface and having a coefficient of elasticity of "k1", providing impact uniform compressive efforts of high intensity on the tank 9, which is initially tight and contains a contaminant or liquid. The coefficient of elasticity "k1" and the length of the inertial springs are selected based on the condition of overcoming inertia, and this inertia is overcome with the creation of pressure on the reservoir 9, sufficient for its perforation.

The dynamic springs 63, 65, 67 and 69 are supported by their bases 81 on the lower surface 79 of the plate 25, and the free ends 83 on the bottom 73 of the support frame 13. Preferably, said support frame 13 is provided with uniformly spaced bosses 85, into which the ends 83 of the dynamic springs, which ensures their uniform arrangement. Mentioned bosses 85 also provide a fixation of the position of the ends 83 of the dynamic springs and, thus, maintaining the direction of their longitudinal axes 87, perpendicular to the bottom 73, lying in the plane "Re". Dynamic springs have the same technical characteristics, and their number is four; they have a coefficient of elasticity “k2”, which, in combination with their uniform arrangement, ensures the preservation of parallelism of the plane “P” of the movable element 15 of the plane “Re” during its movement.

The coefficient of elasticity "k2" and the length of the dynamic springs are selected based on the condition that the action on the movable element 15 is sufficient to dynamically move it to the final position, in which the reservoir 9 is completely compressed and empty, and in this position some compressive force of the dynamic springs must be maintained to ensure full raising of the said movable element 15. In order to optimize the functioning of each group of springs, the coefficient "k1" must exceed the coefficient "k2", and the length of the dynamic springs should exceed the length of the inertia springs.

In a preferred, but not limiting embodiment, when the movable element 15 consists of two plates 23 and 25, the moving element includes suspension means 89 for suspending the movable element 15. These suspension means are made in the form of springs 91, 93, 95 and 97, which are lower are called "spring springs." Said spring springs hold the plate 23 in a floating position relative to the intermediate plate 25 when the movable element 15 is in the initial position. In this initial position, the ends 99 of the spring springs are in contact with the bottom 73 of the support frame 13 and are preferably located inside the bosses 85. The second ends 101 of the spring springs are in contact with the inner surface 39 of the upper surface 27 of the plate 23. The intermediate plate 25 is preferably provided with openings 103 for the passage of spring springs through said intermediate plate 25.

According to a preferred, but not restrictive embodiment, the spring springs have the same technical characteristics, and their number is four; this ensures a uniform distribution of the springing force of the plate 23 and guarantees parallelism of the plane “P1” of said plate 23 and the plane “Re” of the support frame and thereby uniformly pressing the plate 23 to the reservoir 9. The characteristics of the spring springs are selected based on the condition of ensuring uniform compression of the reservoir 9 in the initial the position of the movable element 15 and to prevent too much compressive force exerted by the plate 23, in order to avoid premature perforation of the tank 9 to acti ayuschego device 1.

When the assembled compression device 1 is in the initial position and is ready for use, the plate 25 is attached to the upper part 47 of the connecting part 43, and the support frame 13 is connected to the lower part 49 of the said part; inertial springs 55, 57, 59 and 61 and dynamic springs 63, 65, 67 and 69 are compressed between the bottom 73 of the support frame 13 and the lower surface 79 of the intermediate plate 25. Spring springs 91, 93, 95 and 97 are in the equilibrium position in which they support the stove 23 and the tank, maintaining it under pressure inside the contaminant device. When breaking the protected chamber pyrotechnic means 45 are activated and destroy the connecting part 43, which separates the intermediate plate 25 from the support frame 13; while inertial springs 55, 57, 59 and 61 in combination with dynamic springs 63, 65, 67 and 69 instantly move the intermediate plate 25, which is immediately installed in the abutment position to the plate 23 with the formation of a common plane "P", and the reservoir 9 is subjected to a uniform compressive force of high intensity, which provides instant and simultaneous perforation of the reservoir in all the perforation zones provided for this purpose on said reservoir, and the inertia of the movable element 15 is overcome, which while moving along a rectilinear trajectory perpendicular to the plane "Pe", and the plane "P" of the said movable element 15 maintains a position of full parallelism of the plane "Pe" of the support frame 13, thus ensuring the constancy and uniformity of the pressure generated by the movable element 15, during the entire process of compression of the reservoir 9. After overcoming the inertia, the inertial springs are released and move to a position at which they reach the elastic limit, and their ends 77 come out of contact with the lower surface 25 Stu plate 79; at the same time, the dynamic springs ensure the continuity of the dynamic movement of the movable element 15 until it reaches its final position at which the tank is completely empty.

Thus, the proposed compression device 1 of the present invention provides dynamic movement of the movable element 15 along a rectilinear path perpendicular to the plane "Pe", while maintaining the parallelism of the plane "P" of the said moving element 15 and the plane "Pe" of the supporting frame 13 during the movement, thus ensuring the constancy and uniformity of the distribution of pressure on the reservoir 9 during the process of moving the movable element 15 from the initial position to the final position, at which m said tank 9 is completely empty.

One of ordinary skill in the art may propose other concepts of a compression device 1 that are within the scope of the present invention, for example, an embodiment of a compression device of a circular shape adapted to a tank and a protected chamber of specific shapes. In this case, each group of springs may consist, for example, of three springs.

Claims (9)

1. A compression device (1) for a reservoir (9) containing a substance or liquid suitable for use, in particular, in contaminating devices (5) for pouring said substance or said liquid onto valuable documents or objects (3) containing a support frame (13) defining the “Re” plane, a movable element (15) consisting of at least one pressure plate for compressing the tank (9), defining in its initial position the “P” plane of the tank support (9) parallel to the “Re” plane ", And the driving element (17), driven using a starting device (7) located inside or outside the aforementioned compression device (1), and the actuation of the moving element (17) causes the movable element (15) to move from its initial position, in which the tank (9) is full and closed , in the final position, in which the tank (9) is perforated and emptied from its contents, characterized in that the moving element (17) contains pyrodynamic means, providing before applying it the application of uniform pressure to the cut woire (9), ready for perforation, and then, after activating the said moving element (17), its pyrotechnic actuation, releasing the movable element (15), providing dynamic rectilinear movement of the plane "P" of the said movable element (15) in the direction remaining perpendicular to the plane "Re", and ensuring a uniform and uniform distribution of the compressive forces of the movable element (15) on the tank (9) and the dynamic movement of the said movable element (15) in its final polo parallel to the initial position, in which the tank (9) is completely empty from its contents, which is removed by continuous and uniform pouring. 2. A compression device (1) according to claim 1, characterized in that the pyrodynamic means include fixing means (41), which provides the connection of the movable element (15) in its initial position with the support frame (13), and the fixing means (41) is exposed destruction when the driving element (17) is actuated, and means (53) for dynamically moving the movable element (15) to an end position in which it is separated from the support frame (13). 3. A compression device (1) according to claim 2, characterized in that the fixing means (41) includes a connecting part (43) between the movable element (15) and the support frame (13) and pyrotechnic means (45) capable of destroying said connecting part (43) when actuating the moving element (17). 4. A compression device (1) according to claim 3, characterized in that the connecting part (43) contains a fracture zone (51), which ensures the destruction of the said connecting part (43) when pyrotechnic means (45) are triggered. 5. A compression device (1) according to any one of claims 2 to 4, characterized in that the means (53) for dynamically moving the movable element (15) contain a group of inertial springs (55, 57, 59 and 61) that provide perforation of the reservoir ( 9), and a group of dynamic springs (63, 65, 67, and 69), ensuring the continuation of the dynamic movement of the movable element (15) in its final position. 6. Compressing device (1) according to claim 1, characterized in that the moving element (17) includes suspension means (89) for suspending the movable element (15), ensuring uniform pressure on the reservoir (9) while the said movable element is located ( 15) in its initial position. 7. A compression device (1) according to claim 6, characterized in that the suspension means (89) include prestressed springs (91, 93, 95 and 97). 8. A compression device (1) according to any one of claims 6 or 7, characterized in that the movable element (15) consists of at least two plates (23 and 25), the first intermediate plate (25) at the initial position of the movable element (15) is connected to the support frame (13), and the second plate (23) is spring-loaded in the plane “P1” parallel to the plane “Re” of the support frame (13), providing uniform pressure on the tank (9) at the initial position of the movable element (15 ) 9. A compression device (1) according to claim 8, characterized in that the two plates (23 and 25) of the movable element (15) are closed to form a common plane "P" and instantly create a joint uniform compression force of the tank (9) under the action of means (53) to move upon failure of the connecting part (43) between the first intermediate plate (25) and the support frame (13).

Images