RU122421U1 - PROTECTED INFORMATION DEVICE - Google Patents

Abstract

1. Protected information device (ZIU), which includes, located, mainly in a case, a protected medium of confidential information (NCI), placed in a container with double walls, briquettes from the composition of self-expanding high-temperature synthesis (SHS), placed in the cavity formed by the walls of the container, and an ignition system, characterized in that the ignition system includes a sealed ampoule with a fluorine-oxidant (FO) located in the cavity of the sleeve screwed into the side wall of the container, made with a partition separating the cavity of the sleeve where the ampoule with the FO is located from the cavity formed by the walls of the container, in this case, the device is equipped with a rod installed with the possibility of punching an ampoule with a FO and a partition and inserting a FO onto a briquette from the SHS composition when one end of the rod moves along the longitudinal axis of the sleeve, and is pivotally connected by its opposite end to a lever fixed on the outer surface of the side wall of the case , while the lever is tightened pr supper to the side wall of the case and is additionally fixed with a locking device made, for example, in the form of a check, and the FO is selected from the group of halogen fluorides or their complex compounds in a liquid or solid state. 2. The device according to claim 1, characterized in that on the fastened bottom walls of the container and the case, at least one hole aligned with each other is made, closed by a bursting disc. The device according to claim 1 or 2, characterized in that between the rod and the capsule with PO in the sleeve, at least one additional tablet from the CBC composition is placed.

Description

The utility model relates to the field of computer science and chemistry, namely to a chemically protected information device.

The most effective utility model can be used to ensure the security of information devices from unauthorized access to the confidential information available in them, placed mainly in the case, by emergency liquidation of confidential information carriers (paper, electronic, etc.) by burning. The autonomy of the device is ensured by independence from the supply of a command or programmed electrical signal.

There are various types of secure information devices, in particular, a secure electronic information device containing a housing, a microcircuit board and a protection unit, including substances placed in layers around the microcircuit board and destroying it when the device is opened [1]. The disadvantage of this device is the limited range of its use, since the protection unit can ensure the destruction of only flat microcircuits, which are crystal chips, but is not suitable for protection against tampering of volume microcircuits made of active and passive elements soldered onto a board. This is due to the fact that the protection unit, including substances (materials), consisting of crystals and metallized films and placed around the microcircuit board, can destroy it only due to the action of internal voltage arising in these layers and providing the expansion of the microcircuit board during layer-by-layer cutting of the block. In addition, the disadvantage of this device is the relative complexity of the protection unit due to the need to use a large number (up to 22) of protective layers.

Known secure information system device containing a housing, a source of information in the form of a microchip electronic circuit board and a protection unit [2]. The disadvantage of the device is that the possibility of identifying and reproducing the circuit diagram of the device is not ruled out, since the protection unit prevents access only to software, data encryption and encryption conditions, but does not ensure destruction (destruction) of the microcircuit board itself and its elements when the device is opened.

Known protected electronic information device [3], which consists of a container with triple walls: in the outer cavity (between the first and second walls) is placed a flammable chemical reagent - fluoride oxidizer (FO), in the middle cavity (between the second and third walls) are briquettes from the composition of self-propagating high-temperature synthesis (SHS), in the internal cavity (bounded by third walls) is placed a protected NKI. The disadvantage is the impossibility of emergency liquidation of the device, since this requires the use of an external (not related to the design of the NCI) means of ignition (cutter, milling cutter, grinding tool, etc.). In addition, the disadvantage is that in the device according to this scheme it is necessary to use a large number of FDs, as a result of which the ignition of the composition of the SHS can be accompanied by an explosion, which is unacceptable for emergency liquidation of the protected information device.

It is also known that the protected information device for emergency liquidation of NDK [4], adopted for the prototype, contains a container with double walls, between which (in the outer cavity) briquettes from SHS are placed, and the NKD is placed between the walls that form the internal cavity. Due to the high temperature of the SHS reaction, existing fire extinguishing agents are not able to interrupt the combustion process [4, 5]. Therefore, this direction of creating secure information devices is promising.

The disadvantage of this device is the impossibility of autonomous (independent of the command or programmed electrical signal) elimination of NKI, since the means of initiating the combustion process of a block of SHS compositions is an electric igniter, the operability of which is impaired if the battery is discharged.

The problem the utility model aims to solve consists mainly in creating portable electronic information devices that are protected from unauthorized access to confidential information, while ensuring the emergency (independent of external power sources) emergency liquidation of these devices (in particular, in the case of the alleged possibility capture device).

The technical result is to increase the reliability of protection of information sensitive materials.

The problem is solved, and the technical result is achieved by the fact that in a secure information device (ZIU), including placed, mainly in a case, a protected medium of confidential information placed in a container with double walls, briquettes from the composition of self-propagating high-temperature synthesis (SHS), placed in cavity formed by the walls of the container, and the ignition system, in which, according to the invention, the ignition system includes a sealed ampoule with fluorooxidant (FD), placed in the cavity of the sleeve screwed into the side wall of the container, made with a partition separating the cavity of the sleeve, where the ampoule with FD is located, from the cavity formed by the walls of the container, the device is equipped with a rod installed with the possibility of breaking through the ampoule with FD and the partition and bringing FD onto the briquette from the SHS structure during the movement of one end of the rod along the longitudinal axis of the sleeve, and pivotally connected to its opposite end with a lever mounted on the outer surface of the side wall of the case, while the lever is spring-loaded which is adjacent to the side wall of the case and is additionally fixed with a locking device, made, for example, in the form of a check, moreover, FD is selected from the group of halogen fluorides or their complex compounds in liquid or solid state.

In cases where the formation of gaseous products during combustion is possible (for example, in the presence of gasified impurities in the boron, which is part of the SHS), at least one closed opening is made on the fastened bottom walls of the container and the case bursting disc.

In cases where it is necessary to provide the necessary delay time for igniting briquettes from the SHS composition, an additional at least one tablet from the SHS composition is additionally placed between the rod and the capsule with ФО in the sleeve. The significance of the distinctive features of the device is due to the following:

- the use in the ignition system of a fluoride oxidizer (FD) ensures the creation of a self-igniting pair when it is in contact with the components of the SHS compositions;

- the placement of FD in a sealed ampoule provides the possibility of long-term storage of the ignition system in a sleeve screwed into the side wall of the container;

- the presence of a partition separating the cavity of the sleeve from the cavity from the cavity formed by the walls of the container prevents environmental influences on briquettes from the SHS composition during separate storage of the sleeve and container;

- the use in the ignition system of the rod, pivotally connected to a lever mounted on the side outer surface of the case with the support, provides the ability to move the rod towards the ampoule with the FD, breaking it and entering the FD (or part of it) onto the briquette from the SHS composition to create self-igniting pairs upon contact;

- pressing the lever with a spring to the side surface of the case prevents the possibility of involuntary movement of the rod and premature destruction of the capsule with DO. In addition, the presence of a spring requires the application of the necessary effort to destroy the ampoule with the FO rod and the subsequent return of the rod to its original position;

- the choice of FD from the group of halogen fluorides in comparison with other types of FD (nitrogen fluorides, oxygen fluorides, chlorine oxofluorides, noble gas fluorides, dioxigenyl compounds - derivatives of metal fluorides) is due to the proven technology, thermal stability, high oxidation ability, low cost and (in depending on the conditions of use) the possibility of using both in liquid (for example, bromine trifluoride BrF ₃ ) and in the solid state (for example, dichlorofluoronium hexafluoroantimonate );

- the execution on the fastened bottom walls of the container and the case, at least one hole combined with each other prevents the possibility of exposure to hot gaseous products on a person, destroying urgently manually confidential information placed in the case;

- the placement between the rod and the capsule with FD in the sleeve of the tablet (s) from the composition of the SHS provides a delay in the ignition time of the briquettes from the SHS, for example, if necessary, throwing the case to the side.

An analysis of published sources of information confirms the uncertainty of the claimed combination of essential features and their patentability.

Other goals and advantages of this PM follow from the following examples of its implementation and the accompanying drawings, where:

figure 1 shows a secure electronic device including a carrier of confidential information placed in a case;

figure 2 - diagram of the tests for the ignition of briquettes from the composition of the SHS when in contact with them FD;

figure 3 is a diagram of a bench test for autonomous emergency liquidation of ZIU, placed in a model container;

on figa, 4b - photographs of fragments of a case made according to the proposed technical solution.

The secure information device of FIG. 1) comprises a case body 1, a case cover 2, a container with double walls (outer wall 3 and inner wall 4), between which briquettes 5 of the SHS composition are placed. At the same time, walls 4 form an internal cavity in which the protected NKI (electronic information device) 6 is placed; the bottom part of the walls 3 of the container is rigidly bonded (glued) to the inner surface of the bottom part of the case body 1. On the side surface of the container wall 3, a sleeve 7 is fixed (screwed in), containing a cavity in which an ampoule with FD is placed (an ampoule with FD is not shown in FIG. 1). Between the rod 8 and the ampoule with FD in the sleeve there is a tablet from the composition of the SHS (not shown in figure 1). In case 1 of the case there is a rod 8, installed with the possibility of breaking through an ampoule with FD and entering it onto a briquette 5 from the SHS when one end of the rod moves along the longitudinal axis of the sleeve 7. The opposite end of the rod 8 is pivotally connected to a lever 9 mounted on the lateral outer surface case 1 of the case using the support 10, while the lever 9 is spring-loaded 11 to the side surface of the case 1 and is additionally fixed with a locking device made in the form of a check (not shown in FIG. 1). The case also contains a handle 12 for carrying it. On the inner side of the end surface of the wall 3 of the container is placed (glued) a foil partition (not shown in FIG. 1), separating the cavity of the sleeve 7 and the container. Depending on the purpose of the protected NKI, the inner walls of the container 4 can be of different types (combustible, fireproof, solid, perforated, mesh, etc.).

The photographs (figa, 4b) show fragments of the case, respectively, in the working (assembled) state and after removing the LCI (a removable container lid is not shown). On the bottom of the case body 1 there are two holes (the position is not affixed), which are aligned with the holes on the bottom of the wall 3 (Fig. 1) of the container and are closed by bursting membranes.

To replace NKI (microcircuits, chips, etc.) one of the sides of the container, as part of it (preferably the front side), can be made in the form of a removable cover. In this case, before carrying out the specified work, the NKI can be stored separately from the device designed to protect it. This also applies to an ampoule with FD (to prevent the possibility of accidental depressurization of it).

The operation of a secure information device.

In the initial (working) position, the handle 12 of the portable case is in the hand of the subject (the person responsible for maintaining confidential information). The bottom of the container body 1, made with holes (visible in the photograph — FIG. 4a) aligned with the holes on the bottom wall 4 of the container and closed by bursting membranes (not visible in FIGS. 4a, 4b), is directed to the side opposite to the subject.

In the event of an emergency (for example, if there is a threat of capture of the case), the subject releases the lever 9 from the locking device (for example, pulls out the pin), then abruptly moves the lever handle 9 from the side surface of the case, overcoming the resistance of the spring 11, and releases the lever 9. The spring 11 returns lever 9 and rod 8 to its original position. In the process of abrupt removal of the lever 9, the rod 8, pivotally connected to the lever 9, punches the ampoule with the FD and the septum, brings the FD (or part of it) onto the briquette 5 from the SHS composition and ignites it. In the case of the formation of gaseous products, the created pressure destroys the membranes, and the gas is vented to the atmosphere through openings in the bottom of the case (Fig. 4a). After breaking through the capsule with DO, the case can be thrown to the side, since the process of burning briquettes 5 from the SHS composition will continue. With the additional placement of 7 tablets from the SHS composition in the sleeve, ignition of the briquettes 5 from the SHS composition can be carried out with the necessary delay time (depending on the number of tablets and their burning rate).

The effectiveness of the proposed technical solution is confirmed by tests to assess the flammability of various SHS compositions when using FO in a liquid and solid state and bench tests of a model container.

According to the scheme shown in FIG. 2, a design variant was tested when a tablet of SHS composition is additionally placed between the rod 8 and the ampoule with FD in the sleeve 7 (in accordance with claim 3 of the formula).

1. On a briquette 5 of the SHS composition, a tablet 13 was placed with a diameter of 8 mm and a height of 15 mm, pressed from the SHS composition (as the composition of the SHS mixtures were used: titanium-boron, titanium-carbon, titanium-boron-carbon). Then they moistened the spatula 14 with a fluorine oxidizing agent 15 in the liquid state (BrF ₃ ), pressed the wetted spatula 14 to the tablet 13 from the SHS composition, which ensured the formation of a self-igniting pair and the undamped burning of the tablet 13, and then the briquette 5. The mass of FO on the spatula 14 was somewhat mg Other types of POs in liquid state may be used (e.g., bromine pentafluoride BrF ₅ ).

2. Conducted a similar test except that on the spatula 14 placed several crystals of FO in the solid state . Reliable ignition and burning of tablets 13 and briquettes 5 of the SHS compositions is also provided. The mass of FO on the spatula was several mg. Other types of solid-state DFs may be used (e.g., potassium tetrafluorochlorate KClF ₄ ).

In accordance with the diagram and installation shown in figure 3, tested a model container. The model container is formed by the upper disk 16, the lower disk 17 and the cylinder 18. In the cavity formed by the outer walls of the model container 16, 17, 18 and the inner perforated walls (without position), briquettes 5 of the SHS composition are placed. The carrier of confidential information (NKI) is placed in the cavity formed by the inner walls of the model container on a fiberglass substrate with dimensions 40 × 40 × 2 mm). An ampoule 19 with fluoroxidant 15 is placed on the upper disk 16 in the cavity of the sleeve 20, which is screwed into the disk 16. On the bracket 21 above the disk 16 coaxially with the sleeve 20, the movable rod 22 is fixed by means of a pin 23. On the upper part of the rod 22 is placed the load 24. Upper the disk 16 is made with two holes 25.

Two tests were carried out, differing in the composition of the briquettes 5 and the selected fluorine oxidizer 15.

1. Briquettes are made of a mixture of titanium-boron-carbon in the ratio of 75.6 / 12.4 / 12.0 weighing 18.6 g. The fluorooxidant is in the liquid state (BrF ₃ ) weighing 1.2 g.

2. Briquettes are made of a mixture of titanium-boron in a ratio of 69/31, weighing 20, 1 g; fluorine oxidizer - weighing 1.3 g. In a solid (bulk) state.

During the tests, a cable (out of position) 3 m long was tied to the check 23 and pulled out the check 23 remotely. The cable length was chosen taking into account the possibility of dropping the case after breaking rod 8 (FIG. 1) of an ampoule with FD. Under the action of the load 24, the rod 22 pierced the fluoroplastic ampoule 19, brought the fluorine oxidizer 15 onto the surface of the briquette 5 from the SHS composition, which led to its ignition. The subsequent combustion of the briquettes 5 ensured the almost complete combustion of the confidential information carrier 6 and the fiberglass substrate. Gaseous products are vented into the atmosphere through openings 25.

In this way, the protection of informational confidential materials has been improved by burning an electronic microcircuit board placed in a case during the interaction of the FI with briquettes from the SHS.

The utility model can be used in the development of portable and stationary carriers of confidential information.

Information sources:

1. V.L. Dshkhunyan, V.F. Shangin. "Electronic Identification." Category: Information Security. Moscow, NT Press, 2004

2. Patent RU No. 2224288. Protected electronic device ..

3. Patent RU No. 2419895. A method for initiating a process of self-propagating high-temperature synthesis.

4. Boborykin S. N., Ryzhikov S. S. Thermochemical destruction of information carriers // Special Technique No. 2, 2002

5. Levashov EA, Rogachev AS, Yukhvid V.I., Borovinskaya I.P. Physicochemical and technological foundations of self-propagating high-temperature synthesis. M., CJSC Publishing House BINOM, 1999.

Claims (3)

1. A secure information device (ZIU), which includes, mainly located in a case, a protected confidential information carrier (NKI), placed in a double-walled container, briquettes from a self-propagating high-temperature synthesis (SHS) placed in a cavity formed by the walls of the container, and ignition system, characterized in that the ignition system includes a sealed ampoule with fluorine oxidizer (FD), placed in the cavity of the sleeve screwed into the side wall of the container, made with a rod that separates the cavity of the sleeve where the ampoule with the FD is located from the cavity formed by the walls of the container, the device is equipped with a rod installed with the ability to pierce the ampoule with the FD and the septum and bring the FD onto the briquette from the SHS when one end of the rod moves along the longitudinal the axis of the sleeve, and pivotally connected to its opposite end with a lever mounted on the outer surface of the side wall of the case, while the lever is spring-loaded to the side wall of the case and is additionally fixed with a locking device, complements, such as checks, wherein the FD is selected from the group consisting of halogen fluorides, or their complex compounds in the liquid or solid state. 2. The device according to claim 1, characterized in that on the fastened bottom walls of the container and the case is made, at least one aligned hole closed with a bursting disc. 3. The device according to claim 1 or 2, characterized in that between the rod and the capsule with FO in the sleeve is placed an additional at least one tablet from the composition of the SHS.