RU2368019C1 - Container device for efficient destruction of information on magnetic carriers - Google Patents

Abstract

FIELD: physics, computer engineering.

SUBSTANCE: invention is related to the field of electric communication and computer engineering, namely to systems of information protection against unauthorised access, mentioned information is contained on magnetic carriers (3.5 inch discs, diskettes and reservoirs of UMEGA type, hard disks, audio- and video-cassettes), in case of their unauthorised carrying out from closed premises. Container device for efficient destruction of information on magnetic carriers comprises control device, field-producing system from even number of N flat spiral solenoids, energy accumulator, two power supply sources, three controlled switches, two electronic switches and switch-breaker of the second power supply source, charging device, device of grid connection, converter of AC voltage into DC voltage, voltage stabiliser, microcontroller, indication device, device for indication switch-off, generator of rectangular voltage pulses, delay line, the first and second electronic switches, current generator, button, start-up device, switching device, fan, temperature sensor, sensor of magnetic field intensity, capacitance sensor, device of individual detection and metal container. Electronic part of device, excluding devices of individual detection, is installed inside metal container.

EFFECT: reduced dimensions of solenoids, provision of simultaneous erasure from two and more magnetic carriers, design of field-producing system provides for variation of vector directions and value of magnetic field intensity, high extent of protection against unauthorised access to information of magnetic carrier.

12 dwg

Description

The device relates to the field of telecommunications and computer technology, namely to systems for protecting information from unauthorized access contained on magnetic media (3.5-inch disks, floppy disks and drives like UMEGA, hard disks, audio and video tapes), when unauthorized removal of them from enclosed spaces.

Information recorded on a magnetic medium corresponds to a certain sequence of sections of the surface of the medium (magnetic cells), in which the magnetization vectors corresponding to bit zero Mn ° and unit Mn ¹ (Fig. 1) are oriented in opposite directions parallel to the magnetic field vector Нз, which information was recorded (hereinafter, the recording vector). Moreover, all cells are in stable states.

The most common are two types of recordings - parallel and perpendicular, differing in the orientation of the recording vector Нз relative to the plane of the medium. Typically, media such as floppy disks, magnetic tapes, and hard disks manufactured before 2002 are used for parallel recording, while modern hard disks and magneto-optical disks are perpendicular to recording. The most common ways to erase a recording are demagnetization or magnetization of a magnetic storage medium by exposure to an external magnetic field.

A device for destroying information on computer hard drives, magnetic storage media of the “Raskat” series [1]. The device is built into a metal cabinet (safe) for storing and destroying information on five magnetic information carriers. The principle of operation of devices of the “Raskat” series is based on the creation of a pulsed magnetic field in the module of the accumulated charge, which when applied to a magnetic medium erases the recorded information without the possibility of its recovery. Charge accumulation time for erasing information up to 3 seconds. Triggering occurs in fractions of a second - 1.5 ms. If there is an electric single-phase power supply (220 V, 50 Hz), the devices of the Raskat series are in a state of readiness for erasing information. The presence of an autonomous power supply pole 12 V allows you to operate the device in the absence of a network. The accumulated charge emitters are connected to the charge storage module through a power cable up to 400 mm long. The emitters of the accumulated charge are single and bidirectional. A bi-directional radiator is two lamellar unidirectional radiators placed in one housing. The structure of the information destruction device on hard magnetic storage media of the “Raskat” series includes: a single-phase network power supply, an autonomous power supply, a charge storage module, a single-sided plate radiator, a control module - a wired button, a power cable, an indication device, a housing for placement lamellar radiators with mount and slide for mounting discs. The power source is connected to the charge storage module, which in turn is connected to the plate radiator via a power cable, and the display device is connected to the power supply and the charge storage module, which is connected to the wire button control module.

The disadvantage of this device is the low reliability of erasing due to the fact that the magnetization reversal of cells with different initial orientations of the magnetization vectors (corresponding to zero and one of the recorded binary code) occurs asymmetrically, that is, the angles between the direction of the erasing field and the direction of the magnetization vectors M ° and

Mn ¹ vary significantly. The scope is limited by the fact that the erasing fields created by the solenoids lie perpendicular to the plane of the medium, that is, the device is ineffective for disk media with other types of recording. With non-ideal rectangularity of the hysteresis loop of the magnetic carrier, this leads to a residual magnetization difference of these cells, which can be used to restore the record. Low erasing efficiency, since the value of the erasing field strength is not more than 350 kA / m. This is the minimum allowable value of the intensity of a pulsed erasing magnetic field with a tangential angle of the directivity vector. In the “Raskat” device, the erasure angle is different from the tangential, which reduces the reliability of the erasure of the record. High energy consumption because When storing magnetic media, the device must be constantly energized in a state of recharging. There is no measurement and confirmation of the presence of a pulsed magnetic field of the required value to erase the record, low reliability during operation of the device due to the lack of temperature control.

A device for the operational destruction of information on magnetic media [3], containing a block for generating an external magnetic field, a block for switching on and a control, a power source, a rack — a base, an optical radiation source, a photodetector, a block for generating control signals, an actuator, and the photodetector output is electrically through an amplifier connected to the input of the inclusion and control unit, the output of which is sequentially through the control signal generation unit and the test mechanism electrically connected to an external magnetic field generating unit. The optical radiation source and the photodetector are rigidly fixed to the base stand and mounted coaxially opposite each other, while the output of the optical radiation source is optically connected to the input of the photodetector. The power source is connected to the inputs of an optical radiation source, a photodetector, an amplifier, an inclusion and control unit, an external magnetic field generation unit, and an external magnetic field formation unit is mounted on a base stand and made in the form of two elements (subunits) interconnected by the magnetic field, located against each other.

The disadvantage of this device is the limited scope, due to the fact that the erasing field lies at an acute angle to the plane of the medium and differs from the direction of orientation of the vector of the recording field Нз. This leads to a mismatch of the angles between the direction of the erasing field and the directions of the magnetization vectors Mn ° and Mn ¹ . To reliably erase information with a pulsed magnetic field, it is necessary to increase the value of the erasing pulsed magnetic field by 2.5-3 times [2], and this leads to an increase in current consumption, an increase in the overall dimensions of the external magnetic field generating unit.

Insufficient erasure reliability due to the lack of measurement and confirmation of the presence of a pulsed magnetic field of the required value.

Closest to the claimed invention is a method of erasing from a magnetic medium and a device for its implementation [4], in which the medium is affected by two mutually perpendicular pulsed magnetic fields. A device for erasing from a magnetic medium comprises: a control unit, first and second circuits, each of which includes a solenoid, capacitor, power source and key, a sensor of amplitude-time parameters of the magnetic field.

The output of the sensor is connected to the input of the control unit. The control input of the key of the second circuit is connected to the output of the control unit. The solenoids of the circuits are made of two cylindrical coils arranged coaxially with a gap between them. The coils of one solenoid have a diameter smaller than the diameter of the coils of another solenoid. The coils are arranged coaxially and so that the vectors of the magnetic fields created by them in the region of the magnetic carrier are mutually perpendicular.

The disadvantages of this device are the limited scope due to the large overall dimensions of the solenoids made cylindrical, a reduced degree of protection (only double protection against unauthorized access to information of the magnetic medium). The ability to erase from only one magnetic information carrier, there is no autonomous power supply, there is no ventilation system that improves the reliability of the device, when destroying information from several magnetic media, it requires a large amount of energy.

The disadvantages of the prototype include a limited scope, large overall dimensions of the solenoids, the simultaneous erasure of only one magnetic medium. The design of the field-forming systems does not allow changing the direction of the directional vector and the value of the magnetic field strength, insufficient degree of protection against unauthorized access to information of the magnetic medium, high energy consumption and the inability to observe the temperature regime when the device is operated in a closed container.

The technical result of the invention is the elimination of the described disadvantages of the prototype, namely, reducing the overall dimensions of the solenoids, ensuring simultaneous erasing from two or more magnetic media, the design of the field-forming system provides a change in the direction of the vector and the value of the magnetic field strength, a high degree of protection against unauthorized access to information of the magnetic medium.

The invention is illustrated by drawings.

Figure 1 shows the orientation of the erasing orthogonal magnetic fields relative to the recording vector Hz information on a magnetic medium, as well as the orientation of the magnetization vectors corresponding to zero (Mn °) and unit (Mn ¹ ) of digital information for the case of perpendicular recording.

On figa, b shows a block diagram of a device for the operational rapid destruction of stored information on magnetic media.

Figure 3 shows the plot of the control signals.

Figure 4 shows a circuit diagram of a controlled key.

Figure 5 shows a circuit diagram of a rectangular pulse generator.

Figure 6 shows a circuit diagram of an electronic key.

Figure 7 shows a circuit diagram of a launcher.

In Fig.8 shows a circuit diagram of a current generator.

Figure 9 shows the package of modules of the field-forming system, creating a magnetic field with the orientation of the vector of the intensity of the pulsed magnetic field perpendicular to the recording vector, and magnetic media.

Figure 10 shows the package of modules of the field-forming system, creating a magnetic field with the orientation of the vector of the intensity of the pulsed magnetic field parallel to the recording vector, and magnetic information carriers.

Figure 11 shows the design of the field-forming system module. In this drawing, the cross section of the module is shown from above, and below it is a top view of the plane of a spiral solenoid.

Figure 12 shows the appearance of a metal container storage device where the location of N / 2 modules of the field-forming system is shown, starting from the first MP1 - 37 and ending with the last MPN / 2 - 42. The modules of the field-forming system can form columns (at least one module per column) . The number of columns and the number of modules in a column is determined by the internal volume of the container allocated for the field-forming system. Above one of the modules of the field-forming system is a magnetic field sensor 36.

In the lower part of the metal container with lock 47, electronic blocks 1, 2, 3, 5, 11-16, 18, 19, 33,48 are placed. In the upper left corner in the doorway of the container 47, a button 17 is integrated. An individual observation device 44 is connected to the eclectic circuit of the device at a distance.

The numbers in the blocks of circuits, written in small print, indicate the numbers of inputs and outputs of the blocks, in the text of the description of the invention they are enclosed in parentheses.

The technical result of the invention is achieved due to the fact that the inventive device for container operational destruction of information on magnetic media contains electronic and mechanical parts.

The electronic part of the claimed device contains (figa, 26, 9, 10): a second power source (ACC) 1; power switch (VP) 2; charger (charger) 3; network connection device (UPS) 4; first power source (PNP) 5; the first (KU1) 6, the second (KU2) 18 and the third (KUZ) 33 keys are managed; voltage stabilizer (ST) 7; microcontroller (MK) 8; indicating device (MI) 9; display shutdown device (OI) 10; a rectangular voltage pulse generator (G) 11; delay line (LH) 12; the first (KE1) 13 and the second (KE2) 14 electronic keys; energy storage device (NE) 15; current generator (GT) 16; button (KP) 17; control device (UU) 19; switching device (UP) 20; N is an even number of solenoids (C1) 21, (C2) 22, (C3) 23, (C4) 24, (C5) 25, (C6) 26, (C7) 27, (C8) 28, (C9) 29, (CU) 30, (Cn), (Cm); fan (B) 34; temperature sensor (DT) 35; magnetic field strength (DF) sensor 36; N / 2 modules of the field-forming system (MP1) 37, (MP2) 38, (MPZ) 39, (MP4) 40, (MP5) 41, (MPN / 2) 42; field forming system (PS) 43; capacitive sensor (DE) 44; device for individual detection (UIO) 45; magnetic storage medium (PIM) 46; trigger device (US) 48.

The mechanical part of the claimed device contains a metal container device for storing and protecting against unauthorized access (KUH) to magnetic media - a container 47. Fig. 12 shows the location of the field forming system modules and electronic device units inside the container.

The execution of the blocks of the electronic part of the device

The second power source is made in the form of an ACC 1 battery and has a power supply output (1) with a voltage of 12 V, a charge current input (3) and a common “zero” terminal (2).

The power switch (VP) 2 voltage ACC 1 has a normally open (NO) contact between the terminals (1-3) and the input (2) of the control signal to close the NO contact.

The charger ZU 3 has a power input (1) voltage of 12-14 V and a stabilized voltage output (2) in the range of 12-14 V.

The UPS network connection device 4 has an output (1) of a 220 V, 50 Hz network.

The first power supply PNP 5 is made in the form of an AC voltage converter 220 V, 50 Hz to a constant stabilized voltage in the range of 12-14 V and has an AC input (1) and a constant output (2).

The first key controlled by KU1 6 has a normally closed (NC) contact between the terminals (1-2) and an input (3) of the control signal of the device UIO 45, designed to open the NC contact of key 1.

The voltage stabilizer CT 7 has an input (1) of a constant voltage of 12-14 V and an output (2) of a stabilized voltage of 5 V.

The microcontroller MK 8 is used to control the operation of the blocks of the electronic part of the device and has six inputs: the first input (1) of the indication off signals, the second input (5) of 12-14 V power, the third input (6) of 5 V power, the fourth input (8) the signal from the energy storage device, the fifth input (9) of the temperature sensor signal, the sixth input (11) of the Hall sensor signal 36. In addition, the microcontroller MK has five outputs: the first output (2) of the signal, which controls the illumination of the group of “power” LEDs, the second output (3) of a signal that controls the illumination of a group of LEDs attention ", the third output (4) signal which controls the illumination LED group" ready-start ", the fourth output (7) signal which controls the shift solenoids 43 field-generating system, a fifth output (10) signal that controls switching of the fan.

The indication device UI 9 is made of two LEDs and a group of four LEDs and has three inputs: the first (1) for control signals for the green LED “ready-start”, the second (2) signals for control for the yellow LED “attention”, the third (3) for luminance control signals of a group of red LEDs “power”.

The device for disabling the indication OI 10 has an output (1) of the control signal.

The square-wave voltage generator G 11 has first (1) and second (3) power inputs, a signal output (2) and a common “zero” terminal (4). The generator G 11 generates rectangular pulses only if there is a DC voltage of 12-14 V at its first input (1).

The delay line LZ 12 delays the signals for half the oscillation period T / 2 of the generator G 11 and has an input (1) and output (2) of the delayed signal.

The first KE1 13 and the second KE2 14 electronic keys have a first input (1) signal, a second power input (3), a power output (2) and a common “zero” terminal (4).

The NE 15 energy storage device is made in the form of a capacitor block and has a signal output (2) and a power input-output (1), the functions of which change when the NE 15 drive is switched, the input becomes an output.

The current generator GT 16 (up to 50,000 A) has a first power input (1), a second signal input (3) and a PS 43 field-forming system power output (2) and a common “zero” terminal (4).

The button KP 17 is installed in the doorway of the container and serves, when the door is opened, to activate the trigger device UZ 48, and has an output (1) signal.

The second KU2 18 and the third KUZ 33 controlled keys have a normally open (NO) contact between the terminals (1-2) and an input (3) of the signal that controls the closure of their NO contacts.

The control unit UU 19 has an input (1) and output (2) signal.

The switching device UP 20 is designed to switch the first (1) and second (2) power inputs of the modules MP1-MPN / 2 of the field generating system PS 43 to change the direction of the vector of the pulsed magnetic field. The device UP 20 has a first input (1) power and a second input (4) signal, the first (1) and second (2) power outputs.

The total number of solenoids N is even: 2, 4, 6, .... The solenoids are made flat spiral. The spirals are made of conductors. Solenoids with odd numbers C1, C3, ... have the first (1) and second (2) power inputs, which are the first (1) and second (2) power inputs of the MP1-MITN / 2 37-42 modules. Solenoids with even numbers have inputs-outputs (1) and outputs-inputs (2) and terminals (4) of the common “zero” field generating system PS 43.

A pair of solenoids, one with an odd number, and the other with the next even number are combined into a module. A modular pair of planar spiral solenoids is fixed coaxially on both sides of the planar dielectric substrate (Fig. 11).

Fan B 34 has a control input (1).

The temperature sensor DT 35 has a sensitive element, for example, a thermocouple and a signal output (1).

The Hall Sensor DX 36 has a sensitive element that responds to a change in the value of the magnetic field strength, and the output (1) is signal.

The field generating system PS 43 consists of N / 2 modules MP1-MPN / 2 and has first (1) and second (2) and third (3) power inputs, which are the first (1), second (2) and third (3) power inputs of modules MP1-MPN / 2, and terminal (4) of the general “zero”.

The capacitive sensor DE 44 has a sensitive sensor element and an alarm output (1). The sensor generates an alarm signal when the current value in its circuit changes due to a change in the capacitance value, for example, when approaching a container of 47 people.

The individual detection device UIP 45 has an output (2) signal and input (1) of the sensing element, which is triggered only when the UIP 45 recognizes an object with the right to access the container device.

The trigger device UZ 48 starts the current generator GT 16 and has a first input (1) of power, a second input (3) signal, output (2) signal and terminal (4) of a common "zero".

The container is made in the form of a filled fireproof iron cabinet or a metal safe with combination locks (Fig. 12).

The electronic part of the device for the operational rapid destruction of information on magnetic media is placed in the container. Outside the container in a secret place are the capacitive sensor DE 44 and the individual detection device UIO 45.

The container design of the device for operational destruction of information provides four-fold protection of information from unauthorized access to it. Mechanical protection by the container 47 itself with a mechanical combination lock. Remote, automatic, electronic protection of the prevention of potential danger or obvious danger is implemented by the introduction of an individual detection device 45. Automatically or by the user, forced protection is carried out by destroying information from a magnetic medium with a pulsed magnetic field with a pulsed magnetic field intensity vector parallel to the recording vector Нз, implemented by button 17 installed in the doorway of the container, the magnetic field of the set of modules 37-42 field binder system 43 (Figure 12).

Protection is automatically carried out by destroying information from a magnetic medium with a pulsed magnetic field with a pulsed magnetic field intensity vector directed perpendicularly or parallel to the recording vector Нз. Protection is carried out in accordance with the program embedded in the microcontroller 8. Using the switching device 20, the control device 19 changes in the field-forming system 43 the direction of the vector of the total magnetic field from the parallel plane of the information carrier to perpendicular and vice versa (Figs. 9, 10).

Connections of blocks of the electronic part of the device

The output (1) of the network connection device 4 is connected to the input (1) of the PNP voltage converter 5, the output (2), which is connected to the input (1) of the power stabilizer 7, with the input (1) of the power supply of the charger 3, with the first terminal (1 ) a second key of controlled KU2 18, with a second input of power (3) of a square-wave pulse generator 11, with second inputs (3) of the first KE1 and second KE2 of electronic keys and a second input (3) of power of the launcher 48, the output (2) of which is connected with power input (3) of the current generator GT 16.

The output (1) of the capacitive DE 44 sensor is connected to the first terminal (1) of the first key of controlled KU1 and is connected through the normally closed contact and the second terminal (2) to the input (2) of the power switch 2 control.

The output (2) of the individual detection device UIPO 45 is connected to the input (3) of the control signal of the power switch 2.

The output (2) of the charger 3 is connected to the input (3) of the battery AKK 1, the output (1) of which is connected to the first terminal (1) of the power switch VP 2, the second terminal (3) of which is connected to the input (3) of the control signal of the second the key of the controlled KU2 18. The second terminal (2) of the second key of the controlled is connected to the input (1) of the power supply of the square-wave voltage generator G 11 and the first terminal (1) of the third key of the control KU3 33, the second terminal (2) of which is connected to the input (1) fan control B 34.

The signal output (2) of the rectangular pulse generator G 11 is connected to the first input (1) of the first electronic key KE1 13 and to the input (1) of the delay line LZ 12, the output of which is connected to the first input (1) of the second electronic key KE2 14. The outputs of the first and the second electronic keys are connected to the first input (1) of the current generator GT 16 and the input (1) of the energy storage NE 15.

The output (2) of the power supply of the current generator GT 16 is connected to the third input (3) of the power of the field-forming system 43 and the first (1) power input of the switching unit UP 20, the first (2) and second (3) outputs of which are connected respectively to the first (1) and second (2) power inputs of the field-forming system 43, which are connected to the power inputs of the odd-numbered solenoids. The third input (3) of the power supply of the field-forming system 43 is connected to the power input of the solenoids with even numbers, the terminals of the common “zero” of which are connected to the common “zero” of the entire device. The switching device UP 20 by the second signal input (4) is connected to the output of the control device 19.

The microcontroller MK 8 is connected by the first input (1) to the output (1) of the display disable device 10, the second output (5) to the output (2) of the AC / DC converter 5, the third input (6) to the output (2) of the stabilizer 7, and the fourth input (8) with output (2) of energy storage 15, fifth input (9) with output (1) of temperature sensor 35, sixth input (11) with output (1) of magnetic field sensor DX 36. In addition, the first (2 ), second (3) and third (4) outputs connected to the corresponding inputs of the display device

UI 9, with the first (1), second (2) and third (3), fourth output (7) with the input (1) of the control device 19, the fifth output (10) with the input (3) of the key managed 33.

The button KP 17 output (1) is connected to the control input (1) of the trigger device UZ 48.

The terminals of the general “zero” of the ACC 1, G 11, KE1, KE2, UZ 48, GT 16 and PS 43 blocks are connected to the common “zero” of the entire device.

Device operation

In the operating mode of the device, with UPS 4 turned on, 12-14 V power from the first power source - PNP 5 converter is supplied to all electronic components of the device. At the first input (1) of the power key KU2 18, which has a NO contact, power from the battery 1 is not supplied. The electronic part of the device is in standby mode authorized or unauthorized access to information. In standby mode, the circuit does not consume current.

With authorized access, the device UIP 45 is turned on, which opens the NC contact of the key KU1 6, so the voltage from the second power source - ACC 1 cannot be supplied to the input (1) of the power supply of the key KU2 18, since the VP switch 2 has a NO contact and a generator G 11 does not generate the pulses necessary to start other blocks of the electronic circuit of information destruction. Information on magnetic media is stored and accessible to the user.

When an alarm occurs at the output (1) of the capacitive 44 sensor, it goes to the input (1) of the control key KU1 6 and through its NC contact (1-2) goes to the input (2) of the power switch VP 2, which closes its NO contact (1-3). The control signal is supplied to the input (3) of the key KU2 18 (Fig.2a), which closes its NO contact (1-2) and the supply voltage of 12 V from the battery 1 is supplied to the first input (1) of the power supply of the generator G 11, which begins to generate rectangular voltage pulses, and starts the electronic circuit of the device for destroying information on magnetic media located in the container 47.

When the device for connecting the network 4 is switched on, from its output (1) an alternating current with a frequency of 59 Hz and a voltage of 220 V is supplied to the input (1) of the AC-to-DC converter 5. In converter 5, the alternating voltage is converted to a constant stabilized in the range of values voltage 12-14 V. From the output (2) of the PNP 5, a constant supply voltage is supplied to the input (1) of the power supply of the key 18, to the input (1) of the power supply of the charger 3, to the signal input (5) of the microcontroller 8 and to the input (1 ) stabilizer power 7. On posal charge plus 12-14 enters the terminal (3) the battery 1 from the output (2) supply voltage stabilizer 3. The battery charger 1 operates in buffered mode and when the battery voltage drops below 10.5 volts plus its recharge is carried out.

Information about the charge level of the battery 1 is output to the input (3) of the indicating device 9 from the input (2), which controls the LEDs, microcalculator 8. The indicating device 9 signals the red LEDs on the discharge of the battery 1 and the need for recharging.

When an alarm occurs at the output (1) of the capacitive sensor 44, for example, when an attacker approaches, and in the absence of a control power signal from the output (2) of the individual detection device 45, a control signal is received at the control input of the power switch 2.

The power switch 2, when the control signal arrives, its NO contact (1-3) closes and the voltage 12 V from the battery 1, through the power switch 2, is fed to the input (3) of the control key 18 (Fig. 4), which closes the contacts ( 1-2). The voltage plus 12 V from the input (1) of the key of the controlled 18 through its closed contact (1-2) is supplied to its output (2) of power, simultaneously to the input (1) of the power of the rectangular pulse generator 11 and to the input (1) of the power of the key of the controlled 33.

The microcontroller 8, the supplied voltage plus 5 V, coming from the output (2) of the power supply to the stabilizer 7, supplies control signals from the output (10) to the control input of the control key 33, which close the contacts (1-2), which ensures supply with the output (2) of the key of the controlled voltage 33 to the input (1) of the power supply of the fan 34, which provides the creation of a temperature regime in the closed volume of the container 47 and turns on only when the limit of the permissible temperature is exceeded and a signal arrives from the output (1) of the temperature sensor 35 to the input d (9) signal microcontroller 8.

The supply voltage at the input (1) of the power supply of the rectangular pulse generator 11 provides the inclusion of this generator (figure 5). Generation starts when the NO contact (1-2) of the key 18 is closed. Signals of a rectangular shape, for example, of the meander type from the generator 11 (Fig. 3d) are fed to the input (1) of the signal electronic key 13 and through the delay line 12 (Fig. 3d), which provides a rectangular signal delay in the form of a “meander” for the time T / 2 (T is the pulse repetition period) to the input (1) of the signal electronic key 14 (Fig. 3d). Electronic keys 13 and 14 are assembled on transistors VT1, VT2, VT3 (Fig.6). When positive signals are supplied (Fig. 3) to the signal inputs (1) of the electronic keys 13 and 14 (Fig. 6), the power current flows from the constant voltage source of the battery 1 and through the coil L1 (Fig. 6), enters the input (3) electronic keys 13 and 14 and an open transistor VT3 to a common "zero".

When applying a low voltage level (5 V) to the input (1), the signal of the first 13 and second 14 keys of the transistor VT3 closes (Fig.3e, g), and the current in the coil L1 cannot instantly decrease. As a result, a voltage jump occurs at the drain of the transistor VT3, which charges the energy storage unit NE 15 through the diode VD1 output (2).

The charging of the capacitors of the energy storage device 15 takes place alternately from a rectangular pulse voltage generator 11 through the first 13 and second 14 electronic keys. First of all, from the key 13 in the first half of the period of rectangular pulses of the generator 11 (Fig.3e), and from the electronic key 14 into the second half of the period (Fig.3g), with a time delay of T / 2, which reduces the charge time of the capacitors energy storage 15 to 2 seconds. Repeated repetition of this cycle provides the charge of the capacitors of the energy storage device 15 in less than 2 seconds.

Forms of voltage signals at the outputs of the keys 13 and 14 are shown in figs. 3e, 3g.

When you press the button 17 by opening the container door at the output (2) of the signal triggering device 48 (Fig. 7), a short voltage pulse appears (Fig. 3, l), which is fed to the input (3) of the signal current generator 16. Current generator 16 ( Fig. 8) is launched and through its power input (1), the capacitors of the energy storage device 15 discharge, forming a current pulse at the output (2) (Fig. 3k), the value of which exceeds 50,000 A.

From the output (2) of the signal energy storage device 15, the “start” capacitor discharge signal is fed to the input (8) of the signal microcontroller 8, which generates a control signal at the output (4), which goes to the indicating device 8, the input (1) controlling the “ready-” LED launch. " The discharge current at this time, in the form of a current pulse, flows through the circuits connecting the field-forming system 43 directly and through the switching device 20. The field-forming system 43, consisting of modules 37-42, provides the summation of the pulsed magnetic fields generated by the modules 37-42, forming the total pulsed magnetic field with the orientation of the directivity vector of the pulsed magnetic field perpendicular (Fig.9) and in parallel (Fig.10) to the directional recording vector, depending on the position of the control switch UP 20.

Field-forming system 43 consists of N / 2 (N is an even number) modules. Each module consists of two flat spiral solenoids. Odd series solenoids 21, 23, ... Сn are fed through a switching device 20, which after “starting” by a control signal received at the input (4), the signal from the output (2) of the control signal device 19, switches and changes the direction of the pulse current by switching an odd series of solenoids, which leads to a change in the direction of the directivity vector of the magnetic field. Each solenoid of an even row 22, 24 ... Cm is powered by a circuit directly connecting the current generator 16 and the common “zero” terminal.

A pulsed magnetic field generated by even-series solenoids changes the direction of the magnetic field vector when summing the pulsed magnetic fields of all modules combined into a field-generating system 43 by vector summation. The magnetic field generated by the field-forming system 43 is detected by the magnetic field sensor 36. From the output (1) of the sensor 36, the signal is fed to the input (11) of the signal microcontroller 8, which generates a signal at the output (3) controlling the group of LEDs installed in the display device 9 and inducing the presence in the field-forming system 43 of a pulsed magnetic field with the orientation of the directivity vector of the pulsed magnetic field perpendicularly and parallel to the plane of the magnetic carrier 46 (Fig.9,10) when switching UP 20. The display disable device 10 is necessary to disable the display when arming, to exclude and not attract attention to the object of protection and protection. The control signal from the output (1) turn off the indication 10 is fed to the input (1) of the microcontroller 8.

A container device for the operational destruction of information on magnetic media can be performed in a filled fireproof iron cabinet or in a metal safe (Fig. 12). At the same time, four-fold information protection is organized. Mechanical protection by the safe itself with a mechanical combination lock, container storage device 47. Remote, automatic, electronic protection of potential danger or obvious danger prevention is implemented by the introduction of an individual detection device 45. Automatically or by the user, protection is carried out by destroying information from a magnetic medium with a pulsed magnetic field with a vector the intensity of the pulsed magnetic field directed parallel to the recording vector Нз, to the realization tsya button 17 installed at the doorway of the iron container, and the magnetic field set field-generating modules 37-42 of the system 43.

Protection is automatically carried out by destroying information from a magnetic medium with a pulsed magnetic field with a pulsed magnetic field intensity vector directed perpendicular to the recording vector H3. This protection is carried out in accordance with the program embedded in the microcontroller 8, the control device 19 using the switching device 20 changes in the field-forming system 43 the nature of the total pulsed magnetic field, as shown in Fig.9, 10.

The total total pulsed magnetic field formed by the field-forming system 43 is formed by the pulsed field of the solenoids in the amount of N (N is the even number of solenoids, N / 2 is the number of modules) with the magnetic field strength vectors of the modules directed perpendicular to the recording vector Нз.

Device implementation

The electronic part of the device is made according to the block diagram of figa, b, in which the following components are used:

1 - the second power source is a battery of type TP 1,2-12 (12 V; 1.2 A).

2 - battery power switch.

3 - charger.

4 - network connection device - network cable with Euro connector.

5 - the first power source is an AC to DC converter.

6, 18 and 33 - managed keys are made according to the circuit diagram of figure 4 on the transistor KT315.

7 - voltage regulator for 5 V.

8 - microcontroller.

9 - indication device is made on LEDs.

10 - display shutdown device.

11 - a rectangular pulse generator is made according to the circuit diagram of figure 5 on a chip type KR1006 VI1.

12 - delay line.

13 and 14, the electronic keys are made according to the circuit diagram of FIG. 6 (VT1 - BC846, VT2 - BC856, VT3 - iRFL014N, VD1 - D220A).

15 - energy storage device is made on K50-77 type capacitors.

16 - the current generator is made according to the circuit diagram of Fig. 8 (YS1 thyristor type T132-5012, diode VD1 type D132-80-14).

17 - button type PKN-2.

19 is a control device.

20 - the switching device is made using the switch to "two positions" and "two directions".

21-32 flat spiral solenoids are made using thin-film technology by spraying metal from two sides on one substrate of Fig.11.

34 - serial fan.

35 - temperature sensor.

36 - Hall type magnetic field sensor.

37-42 - the modules of the field-forming system incorporate two solenoids placed on both sides on the same substrate, filled with a compound, have grooves on the side walls for placing magnetic information carriers.

43 - field-forming system includes 6 modules, which are assembled in one cassette of Figures 9,10.

44 - capacitive sensor, the sensitive element of which as the object approaches the sensitive surface of the sensor changes its parameters, which increases the output voltage. The threshold circuit of the sensor generates a control signal. The device uses sensors of the type CM18PTFE, CM18, CM30DC. SM3OAS.

The container for the operational destruction of information on magnetic media is made in the form of a metal safe with a combination lock (Fig. 12). The device provides four-fold protection of information from unauthorized use:

1. Mechanical protection by safe.

2. Protection with a combination lock.

3. Remote, automatic, electronic protection of the prevention of potential danger or obvious danger is realized by the introduction of an individual detection device 45.

4. Forced protection by the user, in case of unauthorized access, using the button 17 installed in the doorway of the safe, which includes an electronic circuit for destroying information from magnetic media with a pulsed magnetic field.

The technical result of the invention is achieved — the prototype disadvantages are eliminated, namely, the dimensions of the solenoids are reduced, simultaneous erasing from two or more magnetic media is ensured, the field-forming system is designed to change the direction of the directional vector and magnetic field strengths, and a four-fold degree of protection against unauthorized access to magnetic information is provided carriers.

Information sources

1. A device for storing and destroying information. "The roll." Website www.abron.ru/Raskat Safe (5) - Abron Holding.htm.

2. The journal "Engineering Physics", No. 2, 2004

3. The device operational destruction of information on magnetic media. RF patent №2256955, bull. No.20 of July 20, 2005

4. A method of erasing a recording from a magnetic medium and a device for its implementation. RF patent №2217816, bull. No 33 of November 27, 2003

5. Electronic components, No. 9, 2005 “Capacitive sensors of the company SICK AG”, element base, www.elcp.ru.

Claims (1)

A container device for the operational destruction of information on magnetic media containing a control device, a field-forming system of two solenoids, an energy storage device, a first power source and a controlled key, characterized in that a second power source, a power switch of the second power source, a charger, a network connection device are introduced , the second and third keys are controllable, a voltage stabilizer, a microcontroller, an indication device, an indication off device, a rectangular generator voltage pulses, delay line, first and second electronic keys, current generator, button, N-2 solenoid, start-up device, switching device, fan, temperature sensor, magnetic field strength sensor, capacitive sensor, individual detection device and metal container with a lock, moreover, the first power source is made in the form of an AC voltage to DC voltage converter, the second power source is made in the form of a battery, the field-forming system is made up of N / 2 modules, each module contains two flat spiral solenoids placed coaxially on different sides of the flat dielectric substrate, in addition, the battery has an output, a charge current input and a “zero” terminal, the power switch has a normally open (NO) contact and a signal input that closes the contact, the charger the device has a power input and output, the network connection device has a network input and output, an AC / DC converter has an input and output, the first key controlled has a normally closed (NC) contact with the terminals and the input of the signal that controls the opening of the contact, the second and third keys are controlled, BUT contacts with the terminals and the signal inputs, the closing contacts, the first and second electronic keys have a first signal input, a second power input, a power output and a common “zero” terminal, a stabilizer the voltage has an input and output power, and the microcontroller has six inputs: the first input of the display shutdown signals, the second power input, the third power input, the fourth signal input from the energy storage, the fifth signal input of the temperature sensor, the sixth input of the Hall sensor signal, in addition, the microcontroller has five outputs: the first output, which controls the illumination of the group of LEDs "power", the second output, which controls the illumination of the group of LEDs "attention", the third output, which controls the illumination of the group of LEDs "ready - start", the fourth output controlling the switching control device of all solenoids, the fifth output controlling the fan on, the display device has two LEDs and a group of four LEDs and the first input that controls the glow the ready-to-start LED, the second input that controls the attention LED, the third input that controls the glow of the group of LEDs “power”, the display disconnect device has a control signal output, in addition, the square-wave voltage generator has first and second power inputs, an output signal and a common zero terminal, the delay line has an input and an output, the energy storage device has an input - a power output and a signal output, and the current generator has a power input, a signal input, a power output and a common “zero” terminal, a button has an output, the control device has an input and output, the switching device has a first power input, a second signal input and a first power output and a second power output, in addition, odd-numbered solenoids have first and second power inputs, which are the first and second power inputs modules of the field-forming system, solenoids with even numbers have power inputs, each of which is the third input of the field-forming system, and a terminal of the general “zero” modules, and the fan has a control input and power input , the temperature sensor has a signal output, the Hall sensor has a signal output, the capacitive sensor has an alarm output, the individual detection device has a signal input and output, the trigger device has a first signal input, a second power input, a signal output and a common “zero” terminal, except In addition, a field-forming system is placed inside the container, at the bottom of which there is a battery, its power switch, charger, first power source, a square-wave pulse generator i, delay line, two electronic keys, three controlled keys, energy storage, current generator, control device, fan, startup device, switching device, fan, temperature sensor, magnetic field sensor, capacitive sensor, individual detection device, in the upper left a button is built into the corner in the doorway of the safe, in addition, the individual monitoring device is located remotely, and the output of the network connection device is connected to the input of the voltage converter, the output to connected to the input of the voltage regulator, to the power supply of the charger, to the input of the first terminal of the second key controlled, with the second power input of the rectangular voltage pulse generator, with the second inputs of the first and second electronic keys and the second power input of the launcher, the output of which is connected to the input power of the current generator, in addition, the output of the capacitive sensor is connected to the first terminal of the first key controlled and through a normally closed contact and its second terminal is connected to the control input power switch of the first power source, and the output of the individual detection device is connected to the input of the control signal of the power switch, in addition, the output of the charger is connected to the input of the battery, the output of which is connected to the first terminal of the power switch, the second terminal of which is connected to the control signal input of the second key controlled, the second terminal of which is connected to the power input of the rectangular voltage pulse generator and the first terminal of the third control key, second the terminal of which is connected to the fan control input, and the signal output of the square-wave generator is connected to the first input of the first electronic key and to the input of the delay line, the output of which is connected to the first input of the second electronic key, in addition, the outputs of the first and second electronic keys are connected to the first input the current generator and the input of the energy storage device, and the power generator current output is connected to the third power input of the field-forming system and the first power input of the switching device, the first and second outputs of which are connected respectively to the first and second power inputs of the field-forming system, which are connected to the power inputs of solenoids with odd numbers, in addition, the third power input of the field-forming system is connected to the power input of solenoids with even numbers, whose common “zero” terminals are connected with a common “zero” of the entire device, the switching device being connected with the second signal input to the output of the control device, in addition, the microcontroller is connected with the first input to the output of the device and turning off the indication, the second input with the output of the AC / DC converter, the third input with the output of the stabilizer, the fourth input with the output of the energy storage device, the fifth input with the output of the temperature sensor, the sixth input with the output of the magnetic field sensor, in addition, the microcontroller is the first, second and the third outputs are connected to the corresponding inputs of the indicating device with the first, second and third, fourth outputs with the input of the control device, the fifth output with the input of the key controlled, m exit button coupled to a control input of start unit, the total of "zero" terminal of the second power source voltage generator of rectangular pulses, the first and second electronic switches, alternator and torque-generating system startup device connected to a common "zero" of the whole device.

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