RU2427933C1 - Method to protect information on storage of hard magnetic drives and device for its realisation - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: method to protect information on storage of a hard magnetic drive (HMDS) includes arrival of an information leakage risk signal to a controller, afterwards, capacitance storage charging starts from a battery. From the battery the DC voltage is supplied to a converter, at the output of which there is a series of high-frequency pulses generated. Using a transformer and a rectifier, the voltage is sent to the capacitance storage. As voltage of discharger actuation is achieved, the capacitance storage discharges to an inductor. The current pulse in the inductor excites magnetic field, which in electroconductive elements of HMDS induces currents and causes mechanical forces that damage HMDS.

EFFECT: increased efficiency of information protection method on storage of hard magnetic drives of a computer as risk of its leakage occurs, reduced dimensions and higher reliability of a device for its realisation.

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Description

The invention relates to a technique for protecting information, and more particularly, to a technique for protecting information on a computer’s hard disk drive (HDD) 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 at the request of the user.

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.

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

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 during the entire process of erasing information on the disk.

A known method of protecting information by erasing recordings on a magnetic medium, including magnetizing the magnetic medium to saturation and demagnetizing it throughout the series of a series of bipolar decaying pulses that occur 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 media in a vertical plane.

A disadvantage of the known technical solution is the need to use a capacitor designed for high (more than 3 kV) voltage, to use a non-polar capacitor 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.

The closest in technical essence and the claimed result is a method of protecting information in the event of a danger of leakage, including the formation of a series of decaying magnetic field pulses that occur when a polar capacitor is discharged through an inductor, in which due to the currents induced by the pulsed magnetic field in the conductive disk of the armature and due to the return element, the reciprocating movement of the anchor pushing the firing pin with a pointed end towards the information carrier up to its mechanical damage [4].

The closest in technical essence and the claimed result is a device for protecting information in the event of a risk of leakage, containing a constant voltage source, an inductor made in the form of a one-way spiral flat coil, a two-position switch and a polar capacitor connected with a two-position switch alternately to the constant voltage source and to the inductor , while between the storage medium and the inductor rigidly fixed with a mounting plate relative to the storage medium, an anchor is placed axially, made in the form of electrically conductive and shock disks mechanically connected and adjacent to each other, strikers with an expanded support and pointed shock ends and a return element, the armature conductive disk being adjacent to the inductor, the anchor shock disk is opposite the expanded support end of the striker, and a return element, made, for example, in the form of a coaxial spring, is located between the information carrier and the shock disk of the armature, and the expanded supporting end of the striker is connected n is coaxially mounted with the guide pin extending through the central hole in the armature and the inductor with the frame guide is rigidly fixed relative to the mounting plate inductor [4].

The disadvantages of the known method and device are significant dimensions associated with the placement between the inductor and the storage medium of the movable armature and the striker. This drawback is especially negative when protecting information located on a hard drive that is installed in the server basket. Moreover, modern hard drives are made with a heavy-duty casing, which requires a capacitive energy storage device (CES) with significant energy and dimensions. However, when using a high-energy ENE, the problem of the electrical safety of the device is significantly exacerbated. If the accumulated energy of the CES is negligible, then to achieve a positive effect in the known invention requires a significant number of power pulses, and therefore a long time for penetrating briskly hard disk.

In addition, in the known method and device, the electrically conductive armature induced by eddy currents shields the magnetic field of the inductor. As a result of this, undeformed (non-punctured) sections of hard magnetic disks are not exposed to the magnetic field of the inductor and are not demagnetized, which allows using special tools to read information from them.

In the known device for the operation of the information protection device, an AC network is used. However, when removing the voltage from the device (which can be done specifically with unauthorized access to the hard drive by disconnecting the device from the network), it is not possible to protect information, which significantly reduces the effectiveness of the known method and device for protecting information.

U≈310 В. Таким образом, именно до величины напряжения 310 В может быть заряжен ЕНЭ. С одной стороны, для эффективной работы устройства такой величины напряжения может быть недостаточно. Но с другой стороны, такая величина напряжения представляет опасность для обслуживающего персонала.When connected to an AC network with an effective voltage value (U = 220 V, the amplitude value of the voltage is U _m =

U≈310 V. Thus, it is up to a voltage value of 310 V that the CES can be charged. On the one hand, for the effective operation of the device such a voltage value may not be enough. But on the other hand, such a voltage value is a danger to maintenance personnel.

The known device is difficult to manufacture, commissioning and installation in the system unit of a computer. The consequence of this is the low reliability of its operation.

The objective of the invention is to increase the efficiency of the method of protecting information on the HDD of the computer when there is a danger of leakage, reducing the size and improving the reliability of the device for its implementation.

The problem is solved due to the fact that in the known method of protecting information, including the formation of a series of decaying magnetic field pulses by an inductor when a polar CES is discharged onto it, the induction of currents in an adjacent electrically conductive element with an aperiodic magnetic field pulse and the effect on the electrically conductive element directed from the inductor to the hard magnetic disks of mechanical forces, under the influence of which damage to the hard disk, in accordance with the invention, upon receipt on the controller of the signal of the danger of information leakage, the UHE charge from the charged battery begins by converting its constant voltage into a series of high-frequency pulses with subsequent increase and rectification, and the current pulse in the inductor that occurs after the spark gap is triggered excites a magnetic field, which causes mechanical forces in the electrically conductive elements damaging the indicated HDD with the number of pulses of the magnetic field of the inductor specified by the controller.

The problem is solved due to the fact that in the known information protection device containing a constant voltage source, a polar CES, an inductor made in the form of a spiral coil of a disk shape and fixed relative to the HDD, located between the inductor and the HDD mounted in parallel, an electrically conductive element, in accordance with the proposed by the invention, the inductor mounted adjacent, coaxial and opposite to the hard magnetic disks, is monolithic in the nonmetallic part of the housing, the side surface facing the HDD The shaft of which is made with the dimensions of its adjacent surface, the inductor is made in the form of two adjacent located spiral disk coils, wound according to the magnetic field from a single ribbon wire with an internal bend from one coil to another, the electrical leads from each disk coil are adjacent to the end side of the housing inductor, while on the non-metallic part inside the housing on the side opposite to the hard drive, a rectangular ferromagnetic plate is installed with bends located at the edges and placed in the nonmetallic part of the housing, the inductor being electrically connected to the CES by means of a spark gap controlled by a controller, to which a trigger signal about the danger of information leakage is received, while the DC voltage source, made in the form of a battery connected to the charger, is connected to a DC voltage converter high-frequency variable, which receives a signal from the controller, the output of the converter is connected to a step-up transformer, to the output of which is connected a rectifier connected to the CES is provided, and LED circuits are installed in the circuits between the charger and the battery, the rectifier and the CES, the controller and the converter, which respond to the presence of a signal.

In addition, the body of the inductor made in the form of a parallelepiped is covered with an insulating film.

In addition, on the insulating film fixed on the side surface of the inductor body and facing the HDD, a mark is made located on the axis of the inductor.

In addition, the outer diameter of the inductor is made corresponding to the outer diameter of the hard magnetic disks.

In addition, the bends of a rectangular ferromagnetic plate are made of a rectangular shape.

In addition, the nonmetallic part of the inductor body is made of an epoxy-resin-filled fiberglass frame inside which an inductor is installed.

Improving the effectiveness of the method of protecting information in the event of a danger of its leakage is carried out by charging the CES to a voltage (0.5 ... 1.0 kV), many times higher than the battery voltage (about 12V). With an increased voltage of the CES, the efficiency of the protection device increases due to an increase in amplitude, power and a decrease in the duration of the front of the inductor current pulse.

The proposed device can operate autonomously for a long time without an electric network due to the energy of the battery, charged to a safe (low) voltage. The battery voltage is low, does not pose a danger to maintenance personnel and does not require special protection. This increases the reliability of information protection and the safety of the device.

The large amplitude of the inductor current pulse creates a powerful magnetic field pulse, which in the electrically conductive elements of the hard drive causes mechanical forces that damage the drive. In HDD, the electrically conductive elements are recording and reading heads, a head positioning device, a housing, hard magnetic disks, etc. A powerful magnetic field pulse is also destructive for a controller board. All these mechanical damages disrupt the functioning of the HDD and do not allow to remove information from it.

For greater reliability of information destruction, the proposed technical solution uses a certain amount of pulses of the magnetic field of the inductor specified in advance by the controller, at which the HDD will be mechanically damaged and demagnetized.

The proposed device has small dimensions, since the compact body of the inductor is located in close proximity to the HDD. It can be installed in the server basket instead of one of the hard drives.

In the proposed method and device, several powerful magnetic field pulses created by an inductor act on the hard disk drive, which, in addition to mechanical damage to the drive’s electrically conductive elements, completely demagnetize all hard magnetic disks, erasing the information stored on them.

The proposed device is easy to manufacture, commissioning and installation in the system unit of the computer or the basket of the server, because the inductor housing does not contain composite, movable and elastic elements. The proposed device does not affect the computer in normal mode. All electronic components of the device can be located in a separate unit located outside the system unit of the computer.

The placement of the inductor adjacent, coaxial and opposite to the hard magnetic disks allows you to induce maximum currents in the electrically conductive elements of the HDD and create maximum mechanical forces that damage the drive. For the same purpose, the outer diameter of the inductor is made corresponding, for example, equal to the outer diameter of the hard magnetic disks.

The non-metallic part of the inductor body made of fiberglass frame filled with epoxy resin, inside of which the inductor is installed, makes the design mechanically strong and reliable. The implementation of the non-metallic part of the housing enhances the electrical insulation of the inductor, eliminates energy loss and makes the structure non-separable, making information about the design of the inductor housing inaccessible to unauthorized persons.

Since the surface of the inductor casing facing the HDD is made with the dimensions of its surface adjacent to which it is installed, this allows the inductor casing to be easily and conveniently inserted, for example, in the server basket instead of one of the HDD or in the computer system unit adjacent to the protected HDD.

The design of the inductor in the form of two adjacent circular disk spiral coils, wound according to the magnetic field from a single ribbon wire with an internal bend from one coil to another, allows you to create the maximum magnetic field (due to the adjacent location and winding), eliminate the internal electrical connection or internal conclusions of coils.

The adjacent arrangement of the leads of the inductor from each disk coil exiting the housing simplifies the installation and fastening of the inductor housing.

The location inside the inductor housing on the side opposite the HDD, of a rectangular ferromagnetic plate provides a weakening of the magnetic field created by the inductor in the space behind this plate. The plate is a magnetic screen that enhances the magnetic field of the inductor in the direction of the hard drive and reduces in the opposite direction, i.e. into the surrounding space. In this way, the closely located HDD baskets of the server are protected from the magnetic field of the inductor and the unwanted effect on the surrounding electronic equipment and maintenance personnel is eliminated. The strengthening of the magnetic field in the direction of the HDD increases the mechanical forces acting on its electrically conductive elements, and enhances the demagnetizing effect of the hard magnetic disks.

The presence of rectangular bends at the edges of the ferromagnetic plate in the direction of the HDD makes it possible to easily and reliably fix the plate to the nonmetallic part of the inductor body, making the design monolithic.

Closing an insulator body with an insulating film, filled with a non-metal part with an inductor and a ferromagnetic plate, and also made in the form of a parallelepiped, improves the aesthetic appearance of the device, enhances the insulating properties of the inductor, hides information about the design of the inductor, case and plate. This film is made decorative, which improves the overall appearance of the inductor housing.

The presence of a label on a decorative insulating film fixed to the side surface of the inductor body and facing the HDD allows you to correctly (adjacent) and coaxially install the inductor relative to the HDD and its hard drives. The location of the label on the axis of the inductor allows you to ensure maximum exposure to the inductor on the hard magnetic disks.

The presence of the controller in the device allows you to start the process of charging the CES when a signal is received about the danger of information leakage, to set the number of pulses of the inductor and the value of the voltage of the charge of the CES, controlling the spark gap.

Since the converter outputs an alternating high-frequency voltage at the output, due to the high frequency (about 20 kHz), the dimensions and mass of the transformer are small, which reduces the corresponding parameters of the information protection device.

The presence in the circuits between the charger and the battery, the rectifier and the CES, the controller and the converter of LED indicators that respond to the signal, allows you to register processes, respectively, the battery charge, CES charge and the moment the device starts up, which is important for monitoring the operation of the information protection device .

Figure 1 presents a schematic electrical diagram of a device for protecting information on a hard drive;

figure 2 is a General view of the body of the inductor, closed with an insulating film;

figure 3 - projection of the housing of the inductor;

figure 4 is a General view of the coils of the inductor;

figure 5 - schematic diagram of the coils of the inductor;

figure 6 is a General view of the ferromagnetic plate of the inductor body;

Fig.7 is a schematic layout of the body of the inductor relative to the hard drive;

on Fig - schematic arrangement of the inductor housing in the basket of the server with a set of hard drives;

figure 9 is a General view of the HDD.

The method of protecting information on a hard disk includes receiving an information leakage hazard signal on the controller, after which the CES starts to charge from the battery previously charged from the charger. A constant voltage is supplied from the battery to the converter, at the output of which a series of high-frequency pulses is formed. Using a transformer and a rectifier, the voltage rises, rectifies and is supplied to the CES. When the operating voltage of the arrester is reached, the CES is discharged to the inductor. The current pulse in the inductor excites a magnetic field, which induces currents in the electrically conductive elements of the hard disk drive and causes mechanical forces that damage the hard disk drive when the number of pulses of the magnetic field of the inductor is set by the controller. In this case, the magnetic field of the inductor demagnetizes the hard magnetic disks, deleting the information recorded on them.

The information protection device on the HDD contains a constant voltage source, made in the form of a battery 1, a polar CES 2, an inductor 3 mounted adjacent to the CCD 4. The inductor 3 is electrically connected to the CES 2 by means of a spark gap 5 controlled by a controller 6, to which a starting signal 7 about information leakage hazards.

The battery 1 is connected to the charger 8 and to the Converter 9, which converts a constant voltage into alternating high-frequency. The converter 9 is connected to a step-up transformer 10, the output of which is connected to a rectifier 11 connected to the CES 2. The controller 6 is connected to a device 12 that sets the number of pulses of the magnetic field of the inductor.

In the circuits between the charger 8 and the battery 1, the rectifier 11 and the CES 2, the controller 6 and the converter 9 are installed LED indicators, respectively, 13, 14 and 15, reacting to the presence of a signal in these circuits.

HDD 4 consists of an electrically conductive housing 16, hard magnetic disks 17, recording / reading heads 18, a device for positioning the heads 19 and controller boards 20.

The inductor 3 is installed adjacent to and opposite the hard magnetic disks 17 of the HDD 4. The inductor is installed inside the non-metallic part 21 of the housing 22, which is made of a fiberglass frame filled with epoxy resin (not shown). The lateral surface 23 of the housing 22, facing the HDD 4, is made with the dimensions of its adjacent (adjacent) surface.

The inductor 3 is made in the form of two adjacent circular disk spiral coils 24 and 25, wound according to the magnetic field from a single ribbon wire with an internal bend 26 from one coil to another.

The electrical leads 27 and 28 from the disk coils 24 and 25, respectively, are adjacent to one end face 29 of the inductor body. A non-metallic part 21 with an inductor 3 and a ferromagnetic plate 30 are located inside the housing 22. This plate 30 is mounted adjacent to the non-metallic part 21 on the side 31 opposite the HDD 4. The plate 30 is rectangular with rectangular bends 32 located at the edges and located in the non-metallic part 21 the housing 22. In the bends 32 of the plate 30, holes 33 are made in which fasteners (not shown) are installed connecting the non-metallic part 21 of the housing with the plate 30.

Made in the form of a parallelepiped housing 22 (figure 2) on the entire outer surface is closed glued to it with a thin decorative insulating film (not shown). This film can be made, for example, adhesive. On this insulating film fixed on the side surface 23 of the housing 22 facing the HDD 4, a mark 34 is made located on the axis 35 of the inductor.

The outer diameter of the inductor D _i is equal to the outer diameter D _{d of the} hard magnetic disks. The axis 35 of the inductor 3 coincides with the axis of the hard magnetic drives HDD 4 (Fig. 7, Fig. 8).

The body of the inductor 22 is fixed relative to the HDD 4 using a special frame 36 or the basket basket of the server 37. In the basket of the server basket 37, the inductor 3 is installed between the HDD 4a and 4b. In this case, the information is protected on the HDD 4b, and on the HDD 4a and 4b the information is stored.

The information security device on the hard drive works as follows.

In the initial state, the body of the inductor 22 using a special frame 36 or the basket basket of the server 37 is fixed relative to the HDD 4 so that the inductor 3 is installed adjacent to and opposite the hard magnetic disks 17. In this case, the axis 35 of the inductor coincides with the axis of the hard magnetic disks 17. Side surface 23 of the inductor housing 22, on which the mark 34 is made, is mounted opposite the HDD, the information on which is protected (Fig. 7). When using the server basket (Fig. 8), information is deleted on the HDD 4b, and on the HDD 4a the information is saved.

Since the inductor 3 is made in the form of two adjacent circular disk spiral coils 24 and 25, wound according to the magnetic field from a single ribbon wire with an internal bend from one coil to another, their magnetic fields are amplified. The electrical leads 27 and 28 from the disk coils 24 and 25 are located adjacent to the end side 29 of the body of the inductor 22, which allows them to be easily connected to the circuit of the spark gap 5 and ENE 2.

In the initial state, the battery 1 is charged from the charger 8, as evidenced by the glow of the LED 13. After the battery 1 is fully charged, the glow of the LED 13 stops. Depending on the design of the HDD 4 and the importance of the information stored on it, the device 12 sets the number of pulses of the magnetic field of the inductor. This information is recorded on the controller 6.

Upon receipt of the start signal 7 to the controller 6 about the danger of information leakage from the controller 6, a signal is supplied to the converter 9. At the same time, LED 15 lights up and the converter starts to work, changing the constant voltage of the battery into a series of high-frequency pulses (with a frequency of about 20 kHz). From the converter 9, an alternating voltage is supplied to a step-up transformer 10, where its value increases many times. Since the transformer 10 works with high-frequency signals, its mass and dimensions are small, and therefore the corresponding indicators of the electronic part of the information protection device are small.

From the transformer 10, an alternating high-frequency voltage is supplied to the rectifier 11, where it is converted to a constant voltage charging the CES 2. The glow of the LED 14 indicates the process of charging the CES 2.

After the charging voltage reaches a certain value (set by the controller 6), the arrester 5 is triggered, after which the CES 2 discharge to the inductor 3. Since the inductor is shunted by a reverse diode (not shown), the discharge pulse current has a significant value (over 1 kA) and an unchanged polarity.

Such a current pulse in the inductor 3 excites a strong magnetic field, which induces currents in the electrically conductive elements 16-20 of the HDD 4 and causes mechanical forces that damage the HDD. In addition, this demagnetizes the magnetic hard drives 17.

Such a process is repeated the number of times specified by the controller 6, creating the number of pulses of the magnetic field of the inductor necessary to destroy the HDD information.

Since a rectangular ferromagnetic plate 30 is mounted on the non-metallic part 21 inside the housing 22 on the side 31, the magnetic field created by the inductor 3 is amplified in the area of the HDD 4 (Fig. 7) or HDD 4b (Fig. 8), destroying the information stored on them by demagnetization of hard magnetic disks 17 and by mechanical damage to electrically conductive elements: housing 16, hard magnetic disks 17, recording / reading heads 18, positioning device 19 of heads and controller boards 20. Mechanical damage caused They are associated with the eddy currents induced in these elements and the occurrence of significant electrodynamic forces acting on them.

In this case, the magnetic field created by the inductor 3 is attenuated (shielded) in the space behind the ferromagnetic plate 30. As a result, the information in the HDD 4a is stored in the server basket. Information is also stored in the HDD 4c, located at a distance from the inductor, since the magnetic field of the inductor is small.

When using a battery with a voltage of 12 V, the CES charge, made, for example, in the form of a battery of electrolytic polar capacitors with a capacity of C = 6000 μF, reaches a voltage of 500 V in 2 ... 3 s, after which the battery is discharged to the inductor. Such a process is cyclically repeated a predetermined number of times, for example, from 2 to 6. As studies show, after such an impact on a nearby HDD, the case is deformed, hard magnetic disks and head positioning devices are bent, recording / reading heads fly off and controller cards are damaged. Thus, the HDD is irreversibly damaged and it is impossible to remove stored information from it.

Especially destructive effect on the protected HDD has the proposed device in the process of computer operation, since hard magnetic disks rotate at high speed and mechanical impacts of the shock type are most dangerous for them.

The inductor body is connected by its electrical leads 27 and 28 to the connecting wires (not shown), which allows all electronic components 1, 2, 4 ... 15 to be placed in a single compact electronic unit at a distance from the computer, which creates convenience during installation, commissioning and operation of the device protect information.

In addition, the inductor housing does not affect the operation of the HDD in normal mode until a signal is sent to destroy the information when there is a danger of its leakage.

Information sources

1. Pat. RU No. 2106686, IPC G06F 12/14, 03/10/1998.

2. Pat. JP No. 10293903, IPC G11B 05/027, 11/04/1998.

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

4. Pat. RF №2305329, MKI G11B 5/024. A method of protecting information and a device for its implementation. - Z. No. 20055120956. - Announced July 4, 2005. - Publ. 08/28/2007. Bull. Number 24. - 9s. (prototype).

Claims (7)

1. A method of protecting information on a hard disk drive, including the formation of a series of damped magnetic field pulses by an inductor when a polar capacitive energy storage device is discharged onto it, inducing currents in an adjacent electrically conductive element with an aperiodic magnetic field pulse and affecting the electrically conductive element directed from the inductor to the hard magnetic disks of mechanical forces, which damage the hard disk drive, which differs in we note that when a danger signal of information leaks to the controller, the capacitive energy storage starts charging from a charged battery by converting its constant voltage to a series of high-frequency pulses with subsequent increase and rectification, and the current pulse in the inductor that arises after the arrester is triggered excites a magnetic field that in the electrically conductive elements of the drive on hard magnetic disks causes mechanical forces that damage the specified drive for a given control lehr number of pulses of the magnetic field of the inductor. 2. A device for protecting information on a hard disk drive containing a constant voltage source, a polar capacitive energy storage device, an inductor made in the form of a disk-shaped spiral coil and fixed relative to a hard disk drive located between the inductor and the hard disk drive mounted in parallel an electrically conductive element, characterized in that the inductor mounted adjacent, coaxial and opposite to the hard magnetic disks is monolithic in non-metallic part of the housing, facing the hard disk drive, the side surface of which is made with the dimensions of its adjacent surface, the inductor is made in the form of two adjacent located spiral disk coils, wound according to the magnetic field from a single ribbon wire with an internal bend from one coil to another, electrical leads from each disk coil are adjacent to the end side of the inductor housing, while on the non-metallic part inside the housing on the side opposite A hard disk drive has a rectangular ferromagnetic plate with bends located on the edges and placed in the nonmetallic part of the housing, the inductor being electrically connected to a capacitive energy storage device using a spark gap controlled by a controller, which receives a trigger signal about the danger of information leakage, a constant voltage source, made in the form of a battery connected to a charging device, is connected to a constant voltage converter in The high-frequency signal that receives the signal from the controller, the output of the converter is connected to a step-up transformer, the output of which is connected to a rectifier connected to a capacitive energy storage device, and LED circuits are installed in the circuits between the charger and the battery, rectifier and capacitive energy storage device, controller and converter . 3. The device for protecting information on a hard disk drive according to claim 2, characterized in that the inductor housing made in the form of a parallelepiped is closed with an insulating film. 4. The device for protecting information on a hard disk drive according to claim 3, characterized in that on the insulating film mounted on the side surface of the inductor body and facing the hard disk drive, a mark is made located on the axis of the inductor. 5. The device for protecting information on a hard disk drive according to claim 2, characterized in that the outer diameter of the inductor is made corresponding to the outer diameter of the hard magnetic disks. 6. The device for protecting information on a hard disk drive according to claim 2, characterized in that the bends of a rectangular ferromagnetic plate are made of a rectangular shape. 7. The device for protecting information on a hard disk drive according to claim 2, characterized in that the non-metallic part of the inductor housing is made of an epoxy-resin-filled fiberglass frame, inside of which an inductor is installed.

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