RU2486583C1 - Electromechanical device for protection of information placed on digital usb flash storage against unauthorised access - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: electromechanical device for protection of information placed on a digital USB flash storage, against unauthorised access comprises a casing that contains a ferromagnetic frame, inside of which there are coaxially arranged a fixed inductor and a movable anchor made of an electroconducting material and a striker made of a ferromagnetic material. The anchor is made in the form of a disc with an inner cylindrical bushing and is connected with a striker. The frame is made in the form of a magnetic conductor and in the cross section covers the inductor, the anchor and the space of anchor and striker travel. The lower wall of the frame is made with a curve designed for a digital USB flash storage. In the frame there are two double flat springs, which are made as capable of moving the digital storage along the longitudinal axis of the z frame.

EFFECT: higher efficiency of information protection, reduced dimensions and higher reliability of a device.

14 cl, 14 dwg

Description

The invention relates to techniques for protecting information, and more particularly to techniques for protecting information on digital USB flash drives (abbreviated as “digital drives”) when there is a risk of leakage, in which information is destroyed both on the basis of receiving signals about an attempted unauthorized entry, and user request.

A device is known for protecting against accesses to the computer memory of unauthorized users, where, along with the operation of setting a password for authorized access to information contained in the computer's memory, an additional operation is performed to destroy (erase) confidential information after a specified period of time, the duration of which is chosen to be known to be shorter, necessary for an unauthorized user to unauthorized extraction of information by tools. To do this, an additional timer is built into the computer, and the control device generates an erase command [1] according to the timer signal.

The disadvantage of this device is the ability to access the computer's memory when the computer is turned off, protection from access to the computer's memory by unauthorized users is carried out only until the password is entered, after entering the password, access to the memory is open.

There is a method of protecting information by erasing a record on a digital magnetic storage device, based on the creation of a magnetic field and exposure to a magnetic storage device, magnetizing it to saturation [2]. The known technical solution allows the destruction of information by erasing by magnetizing a magnetic storage device to saturation using an alternating magnetic field created by an erasing system that moves along the entire storage device.

However, the use of the known method does not allow for the rapid destruction of information and requires high energy costs due to the need to maintain an undamped magnetic field throughout the process of erasing information on a magnetic disk.

There is a method of protecting information by erasing recordings on a digital magnetic storage device, including magnetizing the magnetic storage device to saturation and demagnetizing it throughout the volume with a series of bipolar decaying pulses arising in the oscillatory circuit [3]. A device for implementing this method contains a constant voltage source, a resonant circuit made of a cylindrical inductor and capacitor, a lifting device for moving magnetic drives in a vertical plane.

A disadvantage of the known technical solution is the need to use a capacitive energy storage device (ENE), designed for high (more than 3 kV) voltage, using a non-polar ENE to charge, which greatly increases the size of the device, the bulkiness of the inductor (weight more than 700 kg). All this leads to a significant increase in the duration of the erasure. In addition, the presence of a lifting device significantly complicates this technical solution, making it less reliable.

A device for erasing information on a magnetic storage device containing a constant voltage source, a parallel oscillatory circuit made of an inductor and a capacitor, a two-position switch and a polar CES connected with a two-position switch alternately to a constant voltage source and to an oscillating circuit coil, which is made in the form of a single-input spiral flat reels [4].

However, studies show that with any process of magnetization / demagnetization of a magnetic storage device, information can be restored using special programs. For example, a study of the surfaces of magnetic plates using scanning microscopy is used.

As a rule, a magnetic digital information storage device has protection against external magnetic fields, for example, external electromagnetic and magnetic screens made in the form of a housing (pressure chamber), respectively, of electrically conductive and ferromagnetic material. Therefore, the efficiency of the known device for erasing information by magnetizing / demagnetizing a magnetic storage device is not high enough.

A device is known for protecting information when there is a danger of leakage, containing a constant voltage source, an inductor made in the form of a single-input spiral flat coil, a two-position key and a polar CES, connected by a two-position key alternately to the constant voltage source and to the inductor, while between the digital information storage device and an inductor rigidly fixed by means of a mounting plate relative to the information storage device, an anchor made in the form of mechanically unified and adjacent to each other electrically conductive and impact disks, strikers with an extended support and pointed impact ends and a return element, wherein the conductive disk of the armature is adjacent to the inductor, the impact disk of the anchor is opposite the expanded support end of the striker, and the return element made, for example, in the form of a coaxial spring, located between the digital information storage device and the shock disk of the armature, and the expanded supporting end of the hammer is connected to a coaxially mounted guide pin Passing through the central hole in the armature and the inductor with the frame guide is rigidly fixed relative to the mounting plate inductor [5].

The disadvantages of the known device are the significant height of the elements placed between the inductor and the digital storage device. Due to the large diameter of the striker and the creation of the corresponding hole in the digital storage device, a significant amount of powerful mechanical shocks is required, which increases the time required to pierce it to the required depth, and hence the time from signaling when there is a risk of information leakage to mechanical damage to the digital storage device. In addition, the reciprocating movement of the armature is associated with difficulties in the implementation of the guide elements, the configuration and installation of the device.

This device is not very effective for protecting information stored on a digital USB flash drive that uses flash memory to store data and connects to a computer or other reading device via a standard USB connector. USB flash drives are non-volatile, have an elongated shape (length about 5 cm, width up to 2 cm, height up to 1 cm), which allows you to transfer them to the owner, for example, in a suit pocket or briefcase. A typical USB flash drive device includes: a USB connector, a microcontroller, control points, a flash memory chip, a quartz resonator, an LED, a write-protect switch, a place for an additional memory chip.

The closest in technical essence and the claimed result is a device for protecting information placed on a digital USB flash drive from unauthorized access, containing a frame, inside of which an inductor is fixed coaxially, fixed to one side of the frame, movable anchor and firing pin, and the inductor is made in the form a flat spiral coil, the anchor is made in the form of an electrically conductive disk, the flat surface of which is adjacent to the inductor, and a shock disk, the flat surface of which is adjacent to the electric a conducting disk, the firing pin is made with a guide pin, an expanded part and a pointed end, and the guide pin is located in the Central holes of the inductor and the armature, the flat surface of the expanded part is adjacent to the flat surface of the impact disk, and the pointed end is directed towards the digital storage device and the elastic locking element, pressing the anchor to the inductor and interacting with a digital storage device, two inductors, centers are attached to one side of the frame made of ferromagnetic material whose axes intersect with the longitudinal axis of the frame, and the inductor is fixed on the opposite side of the frame in such a way that its central axis is located in the middle between the central axes of oppositely mounted inductors, the elastic locking elements pressing the digital storage device to the longitudinal axis of the frame are made in the form of flat springs with the ability to move the digital drive along the longitudinal axis of the frame, a portable frame and an electronic unit containing The sequence interconnected autonomous source of DC voltage, the inverter DC voltage to AC step up transformer, a rectifier and capacitive energy storage device to which managed by the electronic key connected electrically in series connected inductors [6]. The end of the guide pin of the striker is located in the hole of the frame, and the flat springs located opposite the pointed end of the striker are made with slots for the striker to pass through.

In the known device provides almost instantaneous operation of the device after pressing a button or receiving a signal on a controlled electronic key, since the CES is in a charged state. Its readiness for work is indicated by the glow of the LED indicator. The CES can be charged from a low-power autonomous source of constant voltage, for example, a battery or a compact portable battery, for a long time. This device works once, has a relatively small size and weight can be effectively used for permanent storage and transfer of a digital USB flash drive by the owner, for example, in a jacket pocket or briefcase.

The disadvantages of the known device are the increased complexity of the design, manufacturing technology, commissioning and assembly, due to the presence of three specially installed units (inductor, anchor, impact disk and hammer), as well as elastic locking elements of a special shape and design.

In this device, in each node, the entire shock load is transmitted from the anchor through the shock disk to the extended part of the striker, which is subjected to significant mechanical stresses. This, as experimental studies show, can lead to the cutting of the expanded part of the striker with the impact disk.

The series connection of three inductors reduces the current in each of them three times in comparison with the current in one inductor. Even if the induced current in the armature decreases a similar number of times (in fact, more), the electrodynamic force between the armature and the inductor decreases, at least in a quadratic dependence, i.e. nine times. As a result, the total force from three strikers is lower than from a similar one striker. In addition, three strikers provide not concentrated, but dispersed power to a digital USB flash drive, which may not be sufficient to deform it.

The strikers are not reliably fixed by elastic locking elements, especially in the absence of a digital USB flash drive, which can lead to their dropping and difficulties in entering the digital drive inside the frame.

The implementation of the strikers and shock disks of non-magnetic material (stainless steel with poor magnetic properties) does not significantly affect the magnetic characteristics of the device, and therefore its power indicators. If the movable strikers and impact disks are made of ferromagnetic material, then the resulting pushing force of the striker will decrease because the electromagnetic force of attraction will act on the striker and the impact disk from the inductor, against the electrodynamic repulsive force acting on the anchor.

Due to the presence of these three nodes, the device has significant dimensions in the longitudinal direction.

The objective of the invention is to increase the efficiency of protection of information placed on a digital USB flash drive, if there is a danger of leakage, reduce the size and increase the reliability of an electromechanical device.

The problem is solved due to the fact that in the known device for protecting information placed on a digital USB flash drive against unauthorized access, containing an elongated frame made of ferromagnetic material with parallel opposite walls, inside of which are movable anchor and firing pin, as well as attached an inductor made in the form of a flat spiral coil to the wall of the frame, to which is placed in an electronic a capacitive energy storage unit, the armature contains an electrically conductive disk, the flat surface of which is attached to the inductor by means of an elastic fixing element, the hammer is made with a guide pin, an expanded part and a pointed end directed towards the digital USB flash drive, and the guide pin is located in the central holes of the inductor and anchors, and its end is located in the hole of the frame, the elastic locking element is made in the form of a flat spring with the ability to move a digital USB flash drive eating along the longitudinal axis of the frame and interacting with a digital USB flash drive, in accordance with the invention, the electrically conductive armature is connected to a ferromagnetic striker and is made in the form of a disk with an internal cylindrical sleeve tightly enclosing the guide pin of the striker with a protrusion of a hardened pointed end beyond the surface of the disk and covered to half the inner hole of the inductor, the end face of the sleeve abuts against the expanded cylindrical part of the striker, the end of which protrudes beyond the outer surface of the frame, the outer diameters of the sleeve and the extended part of the striker are the same, the cross-sectional frame made in the form of a magnetic circuit covers the inductor attached to the top wall of the frame, the armature and the working space of the armature with the striker, and the bottom wall of the frame is made with a bend for the USB digital flash - the drive, two double flat springs located along the longitudinal axis of the frame, are fixed relative to its transverse walls, on one of which is a hole for a digital USB flash drive akopitelya, with the possibility of longitudinal displacement, pin passage therebetween, pressing the armature and the inductor digital USB flash drive to the central longitudinal arching bottom frame walls, which adjacent side walls frame mounted sliding abutments for digital USB flash drive.

In addition, the upper wall of the frame is made in the form of a fixing cover.

In addition, on the bend of the lower wall of the frame opposite the striker, a hole is made whose diameter exceeds the diameter of the pointed end of the striker.

In addition, the connection of the electrically conductive anchor with the striker is carried out by means of a tight thermal fit of the cylindrical sleeve of the anchor with the guide pin of the striker.

In addition, the connection of the electrically conductive armature with the ferromagnetic striker is carried out by means of a threaded fit of the cylindrical armature sleeve with the guide pin of the striker.

In addition, the connection of the electrically conductive anchor with the ferromagnetic striker is carried out by means of a pin connection of the cylindrical sleeve of the armature with the guide pin of the striker.

In addition, the electronic unit is located in a single housing adjacent to the bottom wall of the frame.

In addition, the electronic unit is located in a single housing adjacent to the upper wall of the frame.

In addition, the inductor is fixed in an insulating casing, by means of which it is fastened to the upper wall of the frame.

In addition, the connection of the electrically conductive armature is carried out with a striker pre-cooled in liquid nitrogen.

In addition, the surface of the inductor and the insulating housing facing the bottom wall of the frame are located in the same plane.

In addition, the insulating casing is made in the form of a parallelepiped with an internal recess for the inductor and with thickened side walls facing the transverse walls of the frame.

In addition, the fixation of the inductor in the insulating casing and its turns is carried out by means of impregnation with an epoxy compound.

In addition, the insulating casing is made of fiberglass.

The proposed device provides an increase in the force impact on the firing pin due to the summation of the electrodynamic repulsive forces directed towards the digital drive acting on the side of the inductor on the electrically conductive armature and electromagnetic forces acting on the expanded cylindrical part of the ferromagnetic pin from the side of the inductor. This is facilitated by the connection of the anchor with the striker.

The tight coverage of the anchor of the guide pin of the striker with a cylindrical sleeve contributes to the reliable connection and distribution of mechanical loads acting on both the striker and the anchor.

The implementation of the conductive armature in the form of a disk with an inner cylindrical sleeve increases the coefficient of magnetic coupling of the armature with the inductor, providing an increase in the electrodynamic repulsive force. As the calculations show, the greatest force is created by the anchor, in which the height of the cylindrical sleeve is equal to half the height of the inner hole of the inductor. In this case, the cylindrical sleeve of the armature shields the covered part of the guide pin of the striker, preventing the occurrence of braking electromagnetic force between the inductor and this part of the striker.

The location of the protrusion of the hardened pointed end of the striker behind the surface of the armature disk ensures the penetration of the pointed end of the striker into the digital drive at the required distance.

The execution of the same outer diameters of the sleeve of the armature and the extended part of the striker allows you to ensure a minimum distance between them and the inner hole of the inductor in which they axially move. The same goal is facilitated by the fact that the end face of the sleeve abuts against the expanded cylindrical part of the striker.

The implementation of the frame in cross section in the form of a magnetic circuit increases the electromagnetic force of attraction acting on the ferromagnetic striker from the side of the inductor. The protrusion of the end of the expanded part of the striker beyond the outer surface of the frame contributes to this goal.

The presence of two double flat springs located along the longitudinal axis of the frame and fixed relative to its transverse walls with the possibility of longitudinal displacement, provides the passage of the striker between them, pressing the armature to the inductor and the digital drive to the central longitudinal curvature of the bottom wall of the frame.

The implementation of the bottom wall of the frame with a bend for the digital drive, located along the longitudinal axis, provides space for its reliable fixation inside the frame. The presence of sliding stops for the digital drive located in the bend of the bottom wall of the frame adjacent to the transverse walls of the frame, provides the creation of a mechanical moment breaking the digital drive when exposed to the striker.

The presence of a hole on one of the transverse walls of the frame provides input / output of a digital storage device to / from the frame.

The implementation of the upper wall of the frame in the form of a fixing cover increases the manufacturability of the frame for its manufacture, assembly and configuration.

The presence of a hole in the bend of the lower wall of the frame opposite the striker, whose diameter exceeds the diameter of the pointed end of the striker, eliminates the deformation of the lower wall of the frame with the pointed end of the striker.

When connecting the electrically conductive anchor to the striker by means of a tight thermal fit of the cylindrical sleeve of the armature with the guide pin of the striker, structural changes in the connected elements are eliminated. It is most effective to provide such a compound by pre-cooling the striker in liquid nitrogen, in which its radial dimensions decrease, with a subsequent increase under ambient temperature conditions.

When connecting the anchor to the striker using the threaded fit of the cylindrical sleeve of the anchor with the guide pin of the striker, multiple assembly / disassembly is necessary, for example, to replace one of the elements. A similar problem is solved by connecting the anchor to the striker by means of a pin connection of the cylindrical sleeve of the anchor to the guide pin of the striker, which is provided by inserting / removing a pin into the connected elements.

The location of the electronic unit in a single housing with the frame makes the device functional and convenient to use. If the electronic unit is located in the housing adjacent to the bottom wall of the frame, the digital drive will be located in the middle of the housing with reliable protection from external influences.

If the electronic unit is located in the housing adjacent to the upper wall of the frame, the digital drive will be located at the bottom of the housing with visual diagnostics of the location of the end of the expanded part of the striker relative to the outer surface of the frame.

Fixing the inductor in the insulating casing, by means of which it is fastened to the upper wall of the frame, increases the reliability of the inductor and makes such a design technologically advanced. The most technologically advanced is an insulating casing made in the form of a parallelepiped with an internal recess for the inductor and with thickened side walls facing the transverse walls of the frame.

The location of the surface of the inductor and the insulating casing, facing the bottom wall of the frame, in one plane provides a snug fit to the disk of the armature and maximum magnetic coupling between the inductor and the armature.

When the inductor is fixed in an insulating casing made of fiberglass and its coils by impregnation with an epoxy compound, the design becomes monolithic and reliable.

Figure 1 presents a General view of the electromechanical device for protecting information located on a digital USB flash drive from unauthorized access, in which the electronic unit is located in the housing adjacent to the bottom wall of the frame;

figure 2 presents a General view of an electromechanical device in which the electronic unit is located in the housing adjacent to the upper wall of the frame;

figure 3 is a section aa in figure 2 in the absence of a digital drive in the frame;

figure 4 - section bb in figure 2 in the absence of a digital drive in the frame;

figure 5 - figure 3 in the presence of a digital drive in the frame before the device;

figure 6 - figure 4 in the presence of a digital drive in the frame before the device;

in Fig.7 - Fig.5 after the operation of the device;

on Fig - view C in figure 4;

figure 9 is a General inverted view of the inductor, fixed in an insulating casing;

figure 10 is a General view of an electrically conductive anchor connected to a ferromagnetic striker;

figure 11 is a General view of a digital USB flash drive in its original state;

in Fig.12 - the state of the digital USB flash drive in Fig.6 before (bold lines) and after (thin lines) the operation of the device;

Fig.13 is a circuit diagram of an electromechanical device;

on Fig - calculated distribution of vectors and induction of the magnetic field (the value is shown by the saturation of the black and white hue) of the electromechanical device during operation.

The electromechanical device for protecting information placed on a digital USB flash drive against unauthorized access consists of a housing 1 containing a frame 2 made of ferromagnetic material and having an elongated shape with parallel opposite walls: upper 2a and lower 2c, front transverse 2c and rear transverse 2d. Inside the frame 2, a fixed inductor 3 and movable armature 4 made of an electrically conductive material, such as copper, and a hammer 5 made of a ferromagnetic material, for example electrical steel, are coaxially located.

The inductor 3 is made in the form of a flat spiral coil and is attached to the upper wall 2A of the frame. The electrically conductive anchor 4 is made in the form of a disk 4a with an inner cylindrical sleeve 4c.

The firing pin 5 is made with a guide pin 5a, an expanded part 5c and a pointed end 5c directed towards the digital USB flash drive 6. The guide pin 5a and the expanded part 5v of the striker are located in the central hole 3a of the inductor.

Anchor 4 is connected to the striker 5, for example, by tightly fitting the cylindrical sleeve 4b of the armature with the guide pin 5a of the striker. For this, pre-cooling of the striker 5 in liquid nitrogen is used (not shown in Fig.). The connection of the anchor 4 with the striker 5 can also be carried out by means of a threaded fit or a pin connection (not shown) of the cylindrical sleeve 4B of the armature with the guide pin 5a of the striker.

The flat surface of the armature disk 4a is adjacent to the inductor 3. The inner cylindrical armature sleeve 4b tightly encloses the hammer guide pin 5a with the protrusion of the hardened pointed end 5c beyond the surface of the disk 4a. The inner cylindrical sleeve 4c of the armature is covered up to half of the inner hole For the inductor, i.e. the height of the armature sleeve h ₄ <0.5h ₃ , where h ₃ is the height of the inductor. The end face of the sleeve 4B abuts against the expanded cylindrical part 5b of the striker, the end 5d of which protrudes beyond the outer surface of the carcass 2 and is located in the hole 7 in the upper wall 2a of the carcass. The outer diameters of the sleeve anchor D _4B and the extended part of the striker D _{5B are the} same.

The frame 2 is made in the form of a magnetic circuit, i.e. provides a magnetic flux, and in cross section (Fig.3, 5, 7) covers the inductor 3, the armature 4 and the space 8 of the working stroke of the armature with the striker 5.

The bottom wall of the frame 2B is made with a bend 9, intended for a digital USB flash drive 6 and located along the longitudinal axis z of the frame.

In the frame 2 along the longitudinal axis z there are two double flat springs 10 and 11, which are fixed relative to the front 2c and rear 2d transverse walls and are configured to move the digital storage device 6 along the longitudinal axis z of the frame (Fig. 8). The ends of the springs 10 and 11 are located in the protrusions 12, mounted on the transverse walls of the frame 2, with the possibility of longitudinal (along the z axis) displacement and passage of the pointed end 5c of the striker between them. Each of the springs, for example 10, is double, i.e. in the form of two springs bent in opposite directions, one of which 10a is designed to press the armature disk 4a to the inductor 3, and the second 10b is designed to press the digital storage device 6 to the central longitudinal bend 9 of the lower wall 2c of the frame.

In the bend 9 of the lower wall 2c of the frame adjacent to the transverse walls 2c and 2d of the frame are installed sliding stops 13 for the digital drive 6. On the front transverse 2c wall there is a hole 14 for the digital drive 6.

The upper wall 2a of the frame is made in the form of a fixing cover connected to the frame using fasteners 15.

In the bend 9 of the lower wall 2c of the frame opposite the striker 5, a hole 16 is made, the diameter of which D ₁₆ exceeds the diameter D _{5c of the} pointed end 5c of the striker.

The inductor 3 is fixed in an insulating housing 17, which is attached to the upper wall 2a of the frame by means of fasteners 18. The insulating housing 17 is made in the form of a parallelepiped with an internal recess for the inductor 3 and with thickened side walls 17a facing the transverse walls 2c and 2d of the frame. The surface of the inductor 3 and the insulating housing 17, facing the bottom wall 2B of the frame, are located in the same plane. Fixation of the inductor 3 in the insulating housing 17, which is made, for example, of fiberglass, and its turns is carried out by impregnation with an epoxy compound.

The electronic unit 19 is installed in the housing 1 adjacent to either the lower 2B (Fig. 1) or the upper 2a (Fig. 2) wall of the frame. In the electronic unit 19, a constant voltage source 20, a DC-to-AC converter 21, a step-up transformer 22, a rectifier 23 and a CES 24, to which an inductor 3 with an impedance Z _{3 is} connected via a controlled electronic switch 25, are connected (Fig.13 ) The DC voltage source 20 is made in the form of a battery or battery, ENE 24 is in the form of an electrolytic (low voltage polar) capacitor, the controlled electronic key 25 is in the form of a thyristor connected to the start button 26. The electronic unit 19 has an LED 27 with a limiting resistor 28 and reverse diode 29. On the outer surface of the electronic unit 19, there is a start button 26, for example, a touch type (not shown), and an LED indicator 27, glowing when the ENE 24 is fully charged.

Electromechanical device for protecting information located on a digital USB flash drive against unauthorized access works as follows.

In the initial state, the upper wall 2a, made in the form of a cover, is disconnected from the frame 2. An insulating housing 17 is attached to the indicated wall using fasteners 18, the inductor 3 is fixed in one piece with the epoxy compound in it and the anchor 4 and the strikers 5 are connected to each other put on the inductor 3, so that the flat surface of the disk 4A of the armature is adjacent to the inductor 3, and the inner cylindrical sleeve 4B of the armature is located in its hole 3A. In the protrusions 12, which are located on the front 2c and rear 2d transverse walls of the frame, the ends of the double springs 10 and 11 are installed. After that, the upper wall 2a of the frame using fasteners 15 is connected to the frame 2.

In the initial state, electric energy from an autonomous source of constant voltage 20, for example, a 9 V battery, is supplied to the converter 21, where the constant voltage is converted into an alternating frequency, for example, 20 kHz. This alternating voltage is supplied to the transformer 22, where it rises, for example, to 350 V, after which it is rectified in the rectifier 23 and charges the CES 24. At the same time, the LED indicator 27 lights up, indicating that the CES 24 is fully charged and the device is ready for operation.

The digital drive 6 through the hole 14 is introduced into the frame 2. A spring 10b presses the digital drive 6 to the central longitudinal bend 9 of the lower wall 2c of the frame, fixing on the sliding stops 13.

When a signal is received about unauthorized access to the information of the digital storage device 6, press the start button 26. An electronic key 25 is opened, a charged ENE 24 is discharged, and a current of the same polarity arises in the inductor 3 due to the presence of a reverse diode 29. After the discharge of ENE 24, the luminescence of the LED indicator 27 is stopped.

The current in the inductor 3 forms a decaying magnetic field pulse, which induces current in the electrically conductive armature 4. The interaction of the magnetic field of the inductor 3 with the armature current leads to the appearance of an electrodynamic repulsive force acting on the armature and directed towards the digital storage 6.

In this case, the inner cylindrical sleeve 4b of the armature reinforces the magnetic field acting on the disk 4a of the armature, and shields from it the guide pin 5a of the hammer. Thus, the magnetic field of the inductor 3 acts only on the expanded part 5c of the ferromagnetic striker 5, providing electromagnetic force of attraction to the inductor, which is also directed towards the digital storage 6. This contributes to the implementation of the frame 2 in the form of a magnetic circuit (Fig. 14).

The mechanical force due to the total electrodynamic and electromagnetic forces acting on the anchor 4 and the firing pin 5, ensure their movement in the space 8 of the working stroke. The pointed end 5c of the striker acts on the digital drive 6, forming a hole in it (Fig. 7) and / or a fracture using sliding stops 13 (Fig. 12). With this deformation, the digital drive 6 is damaged and the information stored on it is destroyed.

After the pulse current damps in the inductor, the electrodynamic and electromagnetic forces disappear, and under the action of the flat springs 10a and a similar spring 11, the armature disk 4a is pressed against the inductor 3, i.e. return of the anchor and brisk to its original state. If the pointed end 5c of the striker is stuck in the digital drive 6, then the fasteners 15 are unscrewed, the upper wall 2a is disconnected from the frame 2, the anchor 4 is removed with the striker 5, which makes it easy to remove the digital drive 6.

After the device is activated, the end 5d of the expanded cylindrical part 5b of the striker moves into the inside of the frame 2, freeing the hole 7 in the upper wall 2a, which indicates the deformation of the digital drive 6 and the destruction of the information stored on it.

Thus, a comprehensive mechanical destruction (punctured area and kink) of a digital USB flash drive is ensured, which ensures the complete destruction of the information stored on it due to irreversible damage to its microcontroller, flash memory chip and quartz resonator.

The protection device is triggered almost instantly by pressing the start button 26. This increases the efficiency of information protection by preventing the adoption of preventive measures, for example, removing the digital drive 6 from the frame 2. The trigger signal for the protection device to be triggered can also be contacted using a radio signal.

In the proposed protection device, you can store and transport the digital drive for a long time.

The proposed device has small dimensions due to a single duty cycle and the use of a low-power autonomous source of constant voltage, since it can be charged with a small current for a single current. The device has increased reliability due to a single operating mode, the presence of a steel frame and the presence of a diagnostic system, indicating readiness for work and its operation.

Information sources

1. Patent RU No. 2106686, IPC G06F 12 / 14.10.03.1998.

2. JP patent No. 10293903, IPC G11B 05/027, 04.11.1998.

3. US patent No. 5198959, NKI 361-149, 05/30/1993.

4. Patent RU No. 2206131, IPC G11B 5 / 024.10.06.2003.

5. Patent RU No. 2305329, IPC G11B 5/024, 07/04/2005.

6. Ukrainian Patent No. 96517, IPC G11B 5/024, G06F 12/14, 11/10/2011 (prototype).

Claims (14)

1. An electromechanical device for protecting information placed on a digital USB flash drive against unauthorized access, containing an elongated frame made of ferromagnetic material with parallel opposite walls, inside of which are movable anchor and firing pin, as well as an inductor attached to the frame wall, made in in the form of a flat spiral coil, to which a capacitive energy storage device located in the electronic unit is connected via a controlled electronic key, the anchor contains an electrically conductive disk, the flat surface of which is attached to the inductor by means of an elastic fixing element, the firing pin is made with a guide pin, an expanded part and a pointed end directed towards the digital USB flash drive, and the guide pin is located in the central holes of the inductor and the armature, and the end is located in the hole of the frame, the elastic locking element is made in the form of a flat spring with the ability to move the digital USB flash drive along the longitudinal axis of the frame and in interacting with a digital USB flash drive, characterized in that the electrically conductive anchor is connected to a ferromagnetic striker and made in the form of a disk with an internal cylindrical sleeve tightly covering the guide pin of the striker with a protrusion of a hardened pointed end beyond the disk surface and covered up to half of the inductor’s inner hole, the end face the sleeve rests against the expanded cylindrical part of the striker, the end of which protrudes beyond the outer surface of the frame, the outer diameters of the sleeve and the expanded part of the striker being one forged in the form of a magnetic circuit, the frame in cross section covers an inductor attached to the upper wall of the frame, the anchor and the working space of the armature with the striker, and the lower wall of the frame is made with a bend for a digital USB flash drive along the longitudinal axis, two double flat springs, placed along the longitudinal axis of the frame, fixed relative to its transverse walls, one of which has a hole for a digital USB flash drive, with the possibility of longitudinal displacement, passage friction end pin therebetween, pressing the armature and the inductor digital USB flash drive to the central longitudinal arching bottom frame walls, in which adjacent transverse frame walls mounted sliding abutments for digital USB flash drive. 2. The electromechanical device according to claim 1, characterized in that the upper wall of the frame is made in the form of a fixing cover. 3. The electromechanical device according to claim 1, characterized in that a hole is made in the bend of the lower wall of the frame opposite the striker, the diameter of which exceeds the diameter of the pointed end of the striker. 4. The electromechanical device according to claim 1, characterized in that the connection of the electrically conductive anchor with the striker is carried out by means of a tight thermal fit of the cylindrical sleeve of the anchor with the guide pin of the striker. 5. The electromechanical device according to claim 1, characterized in that the connection of the electrically conductive anchor with the ferromagnetic striker is carried out by means of a threaded fit of the cylindrical sleeve of the anchor with the guide pin of the striker. 6. The electromechanical device according to claim 1, characterized in that the connection of the electrically conductive armature with the ferromagnetic striker is carried out by means of a pin connection of the cylindrical sleeve of the armature with the guide pin of the striker. 7. The electromechanical device according to claim 1, characterized in that the electronic unit is located in a single housing adjacent to the bottom wall of the frame. 8. The electromechanical device according to claim 1, characterized in that the electronic unit is located in a single housing adjacent to the upper wall of the frame. 9. The electromechanical device according to claim 1, characterized in that the inductor is fixed in an insulating casing, by means of which it is fastened to the upper wall of the frame. 10. The electromechanical device according to claim 4, characterized in that the connection of the electrically conductive armature is carried out with the striker pre-cooled in liquid nitrogen. 11. The electromechanical device according to claim 9, characterized in that the surface of the inductor and the insulating body facing the bottom wall of the frame are located in the same plane. 12. The electromechanical device according to claim 9, characterized in that the insulating body is made in the form of a parallelepiped with an internal recess for the inductor and with thickened side walls facing the transverse walls of the frame. 13. The electromechanical device according to claim 9, characterized in that the fixation of the inductor in the insulating housing and its turns is carried out by means of impregnation with an epoxy compound. 14. The electromechanical device according to claim 9, characterized in that the insulating casing is made of fiberglass.

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