RU2428749C1 - Device for record deletion from magnetic media - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device for record deletion from magnetic information media contains the following: storage battery, electronic switch, voltage converter, voltage divider, switched mode power supply, two energy accumulators, microcontroller, two electronic commutators, start control unit, two field-forming systems, two magnetically sensitive elements, two matrix converters of magnetic fields, amplitude selector, system block and monitor.

EFFECT: improving quality of information deletion on magnetic medium with simultaneous monitor viewing of magnetic record relief till the information is deleted and after it in any section of magnetic medium without removal of magnetic medium from working volume of field-forming systems.

8 cl, 17 dwg

Description

The invention relates to techniques for erasing recordings from magnetic media, in particular hard and flexible disks, magnetic tapes, etc.

As is known, 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 ⁰ and unity Mn ¹ are oriented in opposite directions parallel to the magnetic field vector H3, which recorded information (hereinafter referred to as the recording vector). Moreover, all cells are in stable magnetic states. The most common are two types of recordings - parallel and perpendicular, differing in the orientation of the magnetic field vector of the H3 record relative to the carrier plane. As a rule, produced in 1994-2000. media such as hard disks, floppy disks, magnetic tapes, parallel recording was performed, and modern hard disks and magnetic disks carry out perpendicular recording. In the case of parallel recording on a circular magnetic medium (hard disk drive, diskette), the effect of an external demagnetizing field in the plane of the disk base is not the same for different portions of the medium (this circumstance is illustrated in Fig. 12 and is explained in more detail below). The direction of the external demagnetizing field is parallel to the direction of magnetization of the carrier in the upper and lower parts of Fig. 12 of the disk of the information carrier and perpendicular to it on the left and right. When the magnetic field is perpendicular to the carrier, incomplete demagnetization from different sides of the magnetic disk is possible, which will lead to residual magnetization in its remaining sections.

The most common way to erase a recording is to demagnetize and magnetize a magnetic medium by exposing it to an external magnetic field. These methods are implemented by various devices.

A known method and device for erasing records on a magnetic medium, including the creation of an external magnetic field and exposure to magnetic cells until they are saturated (Japan, patent No. 10293903, G11B 5/027. Publication 1998). The basis of this method is the method of erasing a record on a magnetic medium, in which at least two pulses of mutually perpendicular magnetic field vectors lying in the plane of the medium are affected by the medium, both pulses not overlapping in time.

A device for erasing recordings on a magnetic medium that implements the method comprises a DC voltage source, at least a couple of channels for generating pulsed magnetic fields and a magnetic medium located in the space of their action, contains a control unit and two circuits. Each circuit includes a solenoid, a capacitor, a power source and a key, the control input of which is connected to the output of the control unit. Moreover, the solenoids are arranged so that the vectors of the magnetic fields created by them are mutually perpendicular.

Using the control unit, the solenoids of each circuit are alternately connected to the power source and monitors the supply of supply voltage to the capacitors.

The disadvantage of this method and its implementing device is the limited scope, due to the fact that the vectors of the strengths of the erasing magnetic fields created by the solenoids lie in the plane of the carrier, i.e. the method and device are ineffective for disc media with perpendicular recording. In addition, there is no control over the uniformity and quality of erasing information on both sides of the disk on different parts of their surfaces.

Also known is a method of erasing records from a magnetic medium and a device for its implementation, in which the magnetic medium is affected by at least two time-shifted pulses of mutually perpendicular magnetic field vectors lying in the plane of the medium, and a device for erasing recordings from magnetic media contains a solenoid, a capacitor, a power source, a key, a control unit and a sensor of amplitude-time parameters of the magnetic field (RU, patent No. 2117816, G11B 5/024. Publication 11/27/2003).

The disadvantage of this device is the limited scope, since the sensor of the amplitude-time parameters of the magnetic field is connected to the input of the control unit and is made in the form of a sensor of the magnetic field strength, which measures the time-varying amplitude-time characteristics of the magnetic field vector. When the amplitude value of the magnetic field in the first solenoid exceeds the coercive force of the information carrier in the direction of the recording vector, then, based on the signal from the sensor, the generated control signal includes a second switch and the current flowing in the second solenoid creates a magnetic field in the opposite direction. The sensor measures the level of magnetic field generated only by the first solenoid. The magnetic field generated by the second solenoid is not measured. The quality of erasing information on disk surfaces is not controlled. In addition, the method and device have low energy efficiency, which is associated with the need for repeated repetition of exposure to erasing pulses of a magnetic field. This is caused by uneven erasure from different parts of the carrier due to the fact that the directions of the strengths of the homogeneous magnetic fields created by the solenoids turn out to be different with respect to the direction of the magnetic field of the recording in different parts of the carrier. The need for repeated exposure to erasing pulses is also associated with the fact that each of the magnetic field pulses acts independently of one another.

The closest to the claimed device in technical essence and the achieved technical result is "Device for erasing recordings from magnetic media" (RU, patent No. 2284587, G11B 5/024. Publication 02.10.2006). This device consists of a control unit and two circuits, each of which contains a solenoid, a capacitor, a power source and a key. The input of the control unit is connected to the sensor of the magnetic field created by the solenoid of the first circuit, the output to the control input of the key of the second circuit. The solenoids are arranged so that the vectors of the magnetic fields created by them in the region where the magnetic carrier is located are mutually perpendicular in the plane perpendicular to the plane of the information carrier. In this case, the first solenoid is installed so that the vector of the intensity of the magnetic field created by it in the carrier region is perpendicular to the direction of the vector of the magnetic field strength of the recording on the magnetic medium. In addition, two magnetic field strength sensors and a pair of magnetic field intensity recording devices are introduced into the device, each magnetic field intensity sensor having its output connected to its device for recording the magnetic field strength level, which are connected to the second output of the power source by their inputs.

The disadvantage of this device is the limited scope, since quality control by erasing recordings from magnetic media is carried out indirectly - by measuring the intensity of pulsed magnetic fields. Using sensors, the magnetic field strength level is recorded only at two points of the working volume in which the magnetic carrier is located. One sensor of the magnetic field strength is installed in the region where the magnetic carrier is located, and the other is located in close proximity to the boundary that defines the edge of the disk of the magnetic carrier, with its working area of the magnetizing device perpendicular to the intensity vectors created by the pulsed magnetic field solenoids.

After the external pulsed magnetic field is exposed to the disk, the erasing device does not allow controlling the quality of erasing directly on the surface of the disk, namely, the presence of residual magnetization in individual sections and the change in the magnetic relief of the surface portion of the drive on the hard magnetic disk.

A common drawback of these methods and devices is the low reliability of erasing due to the fact that the magnetization reversal of magnetic cells with different initial orientations of the magnetization vector (corresponding to zero and one of the recorded binary code) occurs asymmetrically, i.e. the angles between the direction of the erasing magnetic field and the direction of the magnetization vectors Mn ⁰ and Mn ¹ differ significantly. The difference in the shape of the hysteresis loop of the magnetic carrier from the rectangle leads to the residual magnetization difference of the magnetic cells. This difference of magnetization can be used to restore recording and quality control by erasing recordings from magnetic information carriers, this is due to the fact that when erasing recordings from a magnetic information carrier, as a rule, the coercive force of the thin-film magnetic material of the information carrier remains unknown. Therefore, they create a powerful pulsed magnetic field that exceeds the value of the coercive force of the material, assuming that the magnetic field in the working volume of the solenoids has a uniform distribution; for this, they do not control the structure of the thin-film magnetic layer to saturate the magnetic carrier with magnetic cells. In addition, the methods and devices are characterized by high energy costs associated with the need to create a magnetic field with an amplitude exceeding the intensity of the saturation field of the magnetic material of the information carrier.

The claimed invention solves the problem of improving the quality of erasing information on a magnetic medium, increasing the uniformity of erasing with simultaneous instrumental control of the structure of a thin-film magnetic layer over the entire surface of the disk plate, confirming reliable erasure of information.

The aim of the invention is to create a technical solution that ensures uniformity and guaranteed reliability of erasing information, while simultaneously monitoring in real time the structure of magnetization reversal of magnetic cells with confirmation of the absence of recorded information.

The technical result of the invention is the registration of the magnetic relief of the recording in all areas of the magnetic medium before erasing and after erasing information.

The recording is erased by rotating the vector of the intensity of the acting magnetic field in the plane in which the axis of the disk of the magnetic carrier lies, in which the direction of the rotating vector consecutively coincides with the directions of magnetization of all sections of the magnetic disk for a certain part of the revolution, the visual control used makes it possible to observe the process on the laptop monitor erasing a recording (relief of magnetic recording). For example, for half a revolution of the vector of the intensity of the erasing magnetic field, the rotation of the vector of the magnetic field ensures uniformity of erasing information, which is visually controlled by the image on the laptop monitor. The picture shows the magnetic relief of the disk surface after exposure to a rotating vector of a pulsed magnetic field. If necessary, you can repeat the effect of the erasing rotating magnetic field to ensure reliable and guaranteed destruction of information to be erased. The lack of information is controlled, alternately on all its parts of the image, fragments of the disk surface with a magnetic relief characterizing the recording of information, residual magnetization or complete erasure of information.

The invention is illustrated by drawings.

Figure 1 shows the structural diagram of the device.

Figure 2 shows the electrical circuit of a switching power supply.

Figure 3 shows a diagram of the mutual arrangement of the vectors of the intensity of external magnetic fields and the mutual arrangement of the possible directions of the vectors of the strength of the magnetic fields, which were recorded information on the carrier.

Figure 4 shows diagrams of amplitudes of the vectors of magnetic fields of solenoids of field-forming systems (a), diagrams of amplitudes of voltage of control signals of electronic switches (b), diagrams of voltages of storage elements (c, d).

Figure 5 shows the diagrams of the amplitudes of the signals of the power switch (a), the first electronic switch (b), the pulse current generator (c), the delay line (d), the second electronic switch (e), the third electronic switch (e), energy storage (g), microcontroller (h) and electronic switch (s).

Figure 6 shows the electrical circuit of the energy storage device.

Figure 7 shows the electrical circuit of the first electronic key.

On Fig depicts an electrical circuit of a current generator.

Figure 9 shows the electrical circuit of the second and third electronic keys.

Figure 10 shows fragments of a portion of a disc with recorded information, overhead information (a) and user data (b).

In Fig.11 shows fragments of a portion of the surface of the disk after exposure to an external pulsed magnetic field on the recorded information, service information (a) and user data (b).

On Fig shows the orientation of the vector of the intensity of the external magnetic field and the direction of the magnetization of the domains of the magnetic information carrier. On Fig depicts the electrical circuit of the electronic switch. On Fig shows the electric circuit of the matrix on the magnetodiodes (a) and the electric circuit of the matrix element on the magnetotriode (b) with storage elements.

On Fig presents a longitudinal and lower cross-section of the construction of field-forming systems with a storage medium in the solenoid of the first field-forming system.

On Fig shows a structural diagram of a control unit launch. On Fig shows a structural diagram of an amplitude selector. In the figures, the numbers written in small print indicate the numbers of inputs and outputs of the blocks. In the text of the description of the invention, these numbers are enclosed in parentheses.

The list of blocks of the claimed device and their functional purpose

The technical result of the invention is achieved due to the fact that the device for erasing recordings from magnetic media contains (Fig. 1): a power source - accumulator A 1, electronic key KE 2, voltage converter PN 3, power switch VP 4, voltage divider DN 5, pulse IIP 6 power supply, first NE1 7 and second NE1 8 energy storage devices, microcontroller MK 9, first EC1 10 and second EC2 11 electronic switches, launch control unit BUZ 12, first PS1 13 and second PS2 14 field-forming systems, magnetic data carrier MNI 1 5, the first MCHE1 16 and the second MCHE2 17 magnetically sensitive elements, the first MPMP1 18 and second MPMP2 19 matrix magnetic field transducers, amplitude selector AC 20, system unit SB 21, monitor M 22 and laptop NB 23.

Battery 1 provides power to the recording erase device during transportation and has a “plus” terminal - power input / output (1) and a common zero terminal (4). In stationary conditions in the battery charging mode 1 terminal (1) “plus” performs the function of a power input. When the device is operating on battery 1, the plus terminal (1) serves as the power output. As a battery, a 12 ± 0.5 V battery with a capacity of at least 2.2 Ah can be used.

The KE 2 key is designed to switch battery 1 from recharging mode in stationary conditions using a PN 3 converter, powered by an industrial AC 220 V, 50 Hz, to autonomous - the device’s operating mode from battery 1, which is designed to supply constant voltage current 12 ± 0.5 V of electrical units and components of the device during its transportation.

Key KE 2 contains (Fig. 1) a power input (1), a first terminal (4) of common zero, a second terminal (2) plus, a third terminal (3) a power output. The KE 2 key has a normally open (NO) contact between the second (2) and fourth terminals (1) and a normally closed (NC) contact between the second (2) and third (3) terminals, and a diode. The diode is connected to the fourth terminal (1) by one output, and the second terminal (2) by the other. The KE 2 key works on the principle of a relay, when a voltage of 12 ± 0.5 V is received, its NO contact closes at its terminal (1).

The PN 3 converter is designed to convert AC voltage of an industrial network 220 V, 50 Hz to a stabilized DC voltage of 12 ± 0.5 V. PN 3 has an input (1) and an output (2) of power supply, and a common zero terminal (4).

Battery 1 is charged through a diode, and power to the units of the device for erasing the recording is supplied from the PN 3 converter when the NO contact of the KE 2 key is closed.

In the absence of voltage at terminal (1) KE 2, BUT the contact KE 2 is open, recharging the battery 1 does not occur. A DC voltage of 12 ± 0.5 V is supplied to the units of the device to erase the recording from battery 1 through the NC contact of the EC 2 key from terminal (3).

The switch VP 4 is designed to supply voltage to the units of the device to erase the recording from the magnetic storage medium 15 and has an input (1) and output (2) of the power.

The voltage divider DN 5 has an input (1) and two power outputs, the first (2) 5 ± 0.02 V and the second (3) 12 ± 0.5 V.

The pulse source IIP 6 (figure 2) contains the first Ecl1 24, the second Ecl2 27 and the third Ecl3 28 electronic keys, a current generator G 25 of rectangular pulses and a delay line LZ 26.

The first key EKl1 24 (Fig. 2,9) has a power input (1), a signal output (2) and a common zero terminal (4).

The second and third keys EKl2 27 and EKl3 28 (Fig.2, 11) have a first input (1) signal, a second input (3) power output (2) pulse power and terminal (4) common zero.

The current generator G 25 (Fig. 2.8) has a signal input (1), a power input (3), a rectangular pulse output (2) and a common zero terminal (4).

The delay line LZ 26 (figure 2) has a signal input (1) and output (2).

The first NE1 7 and the second NE2 8 energy storage devices (Figs. 1, 6) are designed to create a pulse voltage with an amplitude of 800-850 V and have an input (1) pulse low voltage, the first (2) and second (3) high pulse voltage outputs and a terminal (4) total zero. Energy storage devices NE 7 and NE 8 are made on capacitors.

The microcontroller MK 9 is designed to control a device for erasing recordings from magnetic media and forming, in accordance with the established program, devices connecting that provide control over the quality and uniformity of erasing information. MK 9 has a power input (1), three signal inputs (2), (5) and (6) and three signal outputs (3), (7) and (8), and a common zero terminal (4).

The first electronic switch EK1 10 is designed for short-term (pulse) switching of high voltage (800-850 V) and the creation of a pulse current of at least 50,000 A in the circuit between the NE1 7 storage device and the field-forming system PS1 13 and the second electronic switch EK2 11 is designed for short-term (pulse) ) switching high voltage and creating in the circuit between the drive NE2 8 and the field-forming system PS2 14 of the pulse current of at least 50,000 A.

Each switch EC1 10 and EC2 11 has a first power input (1) and a second signal input (2), and a common zero terminal (4).

The start-up control unit BUZ 12 is designed to generate and supply a signal for erasing information from the magnetic carrier of information МНИ 15, has a power input (1), a signal output (2) and a common zero terminal (4). The start control unit BUZ 12 (Fig. 16) contains the first and second resistors connected in series by the first terminals and DA1 (analog microcircuit). DA1 has an input that is connected to the connection point of the first resistor terminals, in addition, the second terminal of one resistor is the input of the start control unit, and the output DA1 is the output of the start control unit, and the grounded terminal DA1 is connected to the second terminal of the second resistor.

Field-forming systems PS1 13 and PS2 14 are designed to create pulsed magnetic fields, one of which is directed in parallel to the vector, and the second is perpendicular to the plane of the information carrier MNI 15 and has an input (1) and an output (2) of the pulse voltage, and each contains a solenoid. The solenoid of the first field-forming system PS1 13 is made in the form of a parallelepiped with a through hole of a rectangular cross-section from the end face of a smaller face to accommodate the information carrier MINI 15 (Fig. 15) and is designed to create a magnetic field with a tension vector parallel to the plane of the information carrier MINI 15, and has an input (1) and an output (2) of switching power supply. The turns of the solenoid are wound around a longitudinal axis. On the wide walls of the solenoid cavity, matrix transducers of magnetic fields MPMP 18 and MPMP 19 with magnetically sensitive elements MCHP1 16 and MCHP2 17 glued to them are placed.

The solenoid of the second field-forming system PS2 14 is made in the form of two ring coils connected in series and placed coaxially on the outer faces of the first solenoid parallel to the plane of the information carrier,

The magnetosensitive elements МЧП1 16 and МЧП2 17 are made in the form of packages of magnetosensitive films (Autost. St. USSR No. 711507, priority 14.06.77). Each magnetically sensitive film in a packet has a specific field of uniform nucleation. Packages of magnetic films are designed to analyze the parameters of the magnetic field by changing the nature of the domain structure and modifying the magnetic states of the thin-film layers of the magnetic carrier of information МНИ 15 after exposure to it by an external pulsed magnetic field.

The solenoid of the second field-forming system PS2 14 is designed to create a pulsed magnetic field with a strength vector directed perpendicular to the plane of the information carrier MNI 15, and has an input (1) and output (2) of the pulse power supply. This solenoid is made in the form of two ring coils placed coaxially with two wide external sides of the first PS 1 13 solenoid (Fig. 15), which ensures the perpendicularity of the intensity vector of the magnetic field of the plane of the information carrier created by it.

Matrix magnetic field transducers MPMP 18 and MPMP 19 (Fig. 14) are designed to obtain an electropotential relief of magnetic field strength on the surface of the magnetically sensitive elements MPP1 16 and MPP2 17. MPMP 18 and MPMP 19 are made in the form of matrices consisting of magnetically sensitive elements of magnetodiodes 46 (fig. .14a) or magnetotriodes 47 (Fig. 14b) and have a power input (1) and a signal output (2) (Fig. 1). In parallel with the magnetodiodes, storage capacitors 48 are connected, in the circuit with magnetotriodes, the capacitors 48 are connected to the emitter-base circuit, and a diode 49 is connected to the collector-base circuit, which sets the magnetotriode operation mode (bias). Capacitors 48 are charged to the maximum voltage value at the time of switching and are gradually discharged between switching to a voltage value depending on the magnitude of the magnetic field acting on the magnetically sensitive element.

The amplitude selector AC 20 is designed to determine the signal amplitudes between the commutations in the matrix magnetic field transducers 18 and 19 and convert them to a digital code with subsequent transmission to the output (3). The AC 20 selector has the first (1) and second (2) signal inputs, and the signal output (3). The amplitude selector AC 20 (Fig. 17) contains the first DU1 41 and the second DU2 42 differential amplifiers, each of which has an input (1) and an output (2), the first ADC1 43 and the second ADC 2 44 amplitude-to-digital converters, each of which It has an input (1) and an output (2), an INT 45 interface, which has two inputs, the first (1) and the second (2) and output (3). The inputs of the differential amplifiers are the inputs of the amplitude selector, and the interface output is the output of the amplitude selector, in addition, the output of the first differential amplifier is connected to the input of the first amplitude-to-digital converter, and the output of the second differential amplifier is connected to the input of the second amplitude-to-digital converter, the outputs of which are connected to corresponding interface input.

The SB 21 system unit is designed to process control signals from MK 9, information about signal amplitudes from AC 20 and transmit it to the visualization monitor M 22. The functions of the system unit 21 and the monitor M 22 can be performed by a laptop 23. The system unit 21 has two signal inputs (1) and (2), a signal output (3) and a common zero terminal (4).

Monitor 22 is designed to reproduce video images of the relief fragments of the magnetic state of thin-film layers of the magnetic carrier of information МНИ 15 before and after exposure to it by external magnetic fields created by the solenoids of the field-forming systems PS 13 and PS 14.

Electrical connections of the claimed device

The battery 1 input-output (1) of power is connected to the input-output (2) of the power of the electronic key 2, which is connected to the output (1) of the voltage converter 3, the input (2) of the power of which is connected to the industrial AC network current voltage of 220 V, 50 Hz.

Input (3) of power supply for electronic key 2 is connected to input (1) of power of power switch 4. Output (2) of power of VP 4 is connected to input (1) of power of voltage divider 5.

The first output (2) of power supply of the DN 5 is connected to the input (1) of the power supply of the microcontroller 9 and the input (1) of the power supply of the start control unit 12, the output of which is connected to the first input (2) of the signal MK 9. The second output (3) of the power of the DN 5 is connected with input (1) of power supply for switching power supply 6.

The first output (2) of the power supply of MPS 6 is connected to the input (1) of the power supply of the first energy storage device NE1 7, the signal output (3) of which is connected to the second input (5) by the signal MK 9. The output (2) of the pulse voltage NE1 7 is connected to the input ( 1) the pulse voltage of the field-forming system 13, the output (2) of which is connected to the signal input (1) of the first electronic switch EK1 10. The second input (2) of the signal electronic switch EK1 10 is connected to the first output (3) of the signal MK 9.

The output (2) of the pulse voltage NE1 7 is connected to the input (1) of the pulse voltage of the first field generating system PS 13, the output (2) of which is connected to the signal input (1) of the first electronic switch EK1 10. The second input (2) signal of the electronic switch EK1 10 connected to the first output (3) signal MK 9.

The second output (3) of the power supply of MPS 6 is connected to the input (1) of the power supply of the second energy storage device NE2 8, the signal output (3) of which is connected to the third input (6) of the signal MK 9.

The output (2) of the pulse voltage NE2 8 is connected to the input (1) of the pulse voltage of the second field generating system PS2 14, the output (2) of which is connected to the power input (1) of the second electronic switch EC2 11. The second input (2) of the signal switch EC2 11 is connected with the second output (8) signal MK 9.

The third output (7) signal MK 9 is connected to the inputs (1) of the matrix transducers of magnetic fields MPMP 18 and MPMP 19 and the input (1) of the signal system unit SB 21, the output of which is connected to the input of the monitor 11. Outputs (2) signal MPMP 18 and MPMP 19 are connected respectively to the first (1) and second (2) inputs of the amplitude selector AC 20, the signal output (3) of which is connected to the second input (2) of the signal system unit SB 21.

The magnetic carrier of information МНИ 15 interacts with the erasing magnetic fields of the field-forming systems ПС1 12 and ПС2 14 and with magnetically sensitive elements МЧП1 16 and МЧП2 17.

Operation of a device for erasing recordings from magnetic media

In the solenoid cavity of the first field-forming system PS 13, a magnetic carrier of information МНИ 15 is placed between the matrix transducers of magnetic fields MPMP 18 and MPMP 19 with magnetically sensitive elements MPP1 16 and MPP2 17 glued on them (FIG. 1 and FIG. 15), which are made in the form packages of magnetically sensitive films.

At the input (2) of the voltage converter PN 3, a supply voltage of 220 V, 50 Hz is supplied from the industrial network. This voltage is converted in the PN 3 converter to a stabilized DC voltage of 12 ± 0.5 V, which is supplied to its output (1), and from the output to the input (1) of the key of electronic KE 2. BUT the contact of KE 2 is closed. Power plus 12 ± 0.5 V is supplied to the input-output (2) of the FE 2 through the diode to the input-output (1) of the battery 1, which ensures recharging of the battery 1. At the same time, when the NO contact of the VP 4 power switch is turned on manually and through a closed NO contact KE 2 voltage DC power plus 12 ± 0.5 V is supplied to the input of the voltage divider DN 5.

From the first output (2) of the DN 5 divider, the supply voltage plus 5 ± 0.02 V is supplied to the inputs (1) of the MK 9 microcontroller and the starting control unit BUZ 12. From the second output (3) of the DN 5 divider, the supply voltage is plus 12 ± 0, 5 V is supplied to the input (1) of the pulse voltage source IIP 6.

In accordance with the program laid down, control signals are generated in the MK 9 microcontroller, which are fed from the output (7) of the MK 9 to the inputs (1) of the magnetic field transducers MPMP1 18 and MPMP2 19 with the first and second magnetosensitive elements 16 and 17 placed on them, tightly adjacent on both sides of the plate of the magnetic carrier of information MNI 15 (Fig.15).

Each magnetically sensitive film of magnetically sensitive elements MCHP1 16 and MCHP2 17 is characterized by a field of uniform nucleation, the value of which is determined by formula 1 (see RU, Aut. St. No. 842652 from 10.30.87)

where Q = Ki / 2P (Ms) ² ; λ = [A / 2P (Ms ² )] 1/2;

Ki is the uniaxial anisotropy constant of the magnetic film;

Ms is the saturation magnetization of the magnetic film;

A is the exchange constant of the magnetic film;

D is the thickness of the magnetic film.

Magnetosensitive elements 16 and 17, consisting of a set of magnetosensitive films, are included in the working volume of the solenoid cavity of the first field-forming system PS 13 of the field under study. Each film included in the packages of elements 16 and 17, has a certain field of uniform nucleation. An analysis of the magnetic field strength occurs by changing the nature of its domain structure (DS). In the initial state, the magnetically sensitive films of elements 16 and 17 have a labyrinth DS, after exposure to the investigated field on the plane of the disk of the magnetic carrier MNI 15 on the surface of MCHP 16 and MCHP 17 of the DS of their magnetic films transforms into DS corresponding to uniform nucleation, which differs qualitatively from the labyrinth DS .

The transition of the DS from the labyrinth to the DS corresponding to homogeneous nucleation occurs at strictly defined values of the external magnetic field applied in the plane of the element, i.e. the structure of the magnetic relief of the recording on the plate of the magnetic information carrier 15 is transferred to the magnetically sensitive films of packets 16 and 17. After the magnetic field on the packets of magnetically sensitive films, the DS corresponding to uniform nucleation remains in the magnetically sensitive films of packets 16 and 17 and can only change when exposed the vector of the magnetic field directed perpendicular to the plane of the magnetic information carrier 15, equal to the saturation magnetic field strength.

DS observation is carried out using matrix transducers of magnetic fields 18 and 19 (Fig. 14). When changing the configuration of the DS from the labyrinth in the DS corresponding to homogeneous nucleation, the magnitude of the external magnetic field strength is visually analyzed on the laptop monitor 22, since a certain value of the magnetic field strength corresponds to the moment of uniform nucleation.

Thus, under the action of an external magnetic field, the labyrinth DS of a magnetically sensitive film, which has a homogeneous nucleation field of a certain size, passes into the domain structure of the field of homogeneous nucleation, which differs qualitatively from the labyrinth DS. Knowing the magnitude of the field of homogeneous nucleation inherent in each magnetically sensitive film included in the package of magnetically sensitive elements 16 and 17, it is possible to determine the magnitude of the magnetic field and visually observe the magnetic relief of the plane of the disk portion on the monitor 22.

The magnetosensitive elements 16 and 17 of the magnetosensitive films placed on the matrix magnetic field transducers 18 and 19 transmit the spatial domain structure and magnetic relief of the recorded information from each side of the thin film plates of the disk of the magnetic information carrier 15 to the magnetically sensitive sides of the matrix magnetic field transducers 18 and 19.

Under the influence of a magnetic field, resistance changes, for example, magnetodiodes (Fig. 14), from which matrix transducers 18 and 19 are selected, which is caused by a change in the average concentration of charge carriers in the volume of the conducting channel, as a result of which an electropotential relief corresponding to the spatial the distribution of magnetic field strength on the surface of a magnetic information carrier that displays a magnetic relief. The use of magnetodiodes, whose sensitivity is ten times greater than the sensitivity of magnetoresistors, allows you to sharply increase the sensitivity of the matrix transducer of magnetic fields 18 and 19 and bring it closer to the sensitivity of a magneto-resonance transducer (see RU, Auth. St. No. 859904 of 08.30.81).

In the matrix converter of magnetic fields 18 and 19 (Fig. 14), the principle of accumulation is used to obtain maximum sensitivity. In this case, the magnitude of the current of the video signal coming from each magnetically sensitive magnetodiode 46 (Fig. 14a) or magnetotriode 47 (Fig. 14b) is proportional to the total magnetic flux acting on the element for a full period between switching, i.e. during the frame. Each capacitor 48, shunting the magnetodiode 46 or magnetotriode 47, is charged to the maximum voltage value at the time of switching and is gradually discharged between commutations to a voltage value that depends on the magnitude of the magnetic field acting on the magnetodiode, and therefore, depending on the resistance of the magnetodiode.

The microcontroller MK 9 sequentially connects the first matrix magnetic field transducer 18, and in it sequentially connects the magnetodiodes through the address buses and through the amplitude selector 20 to the input of the system unit 21, laptop 23 (Fig. 14a). At the same time, the system unit 21 simultaneously synchronizes the beam on the screen of the monitor 22, the brightness of the light spot of which is adjusted using the amplitude selector 20.

The optical image on the screen of the monitor 22 corresponds to the magnetic relief of the recording on the thin-film magnetic plate of the magnetic information carrier 15. A fragment of the relief of the recording on the disk plate with random information is presented in Fig. 10a, and with useful information in Fig. 10b.

An even greater increase in the sensitivity of the matrix magnetic field transducer can be achieved by using magnetotriodes as magnetosensitive elements, providing a higher amplitude of the output signal (Fig. 14b). For this purpose, bipolar triodes with a flat emitter and collector or unipolar field triodes with a gate can be used.

The use of a matrix transducer of magnetic fields 18 and 19, in which, for example, the matrix is made of magnetodiodes 46 or magnetotriodes 47, allows increasing the sensitivity of the transducer of magnetic fields by two orders of magnitude.

The magnetic relief of the recorded information on the thin-film plate of the magnetic information carrier 15 (Fig. 12c) from the side of the magnetically sensitive element 16 of the magnetically sensitive films is stored, and then the same operation with the plate of the magnetic information carrier located on the other side of the disk is repeated and determined magnetic relief of the plate using the second magnetically sensitive element 17 of the magnetically sensitive films and the second matrix transducer, magnetic fields 19, the results akzhe remembered.

Prior to forming the erase pulse magnetic field of the switching power supply SMPS 6 when the contacts are closed (1) and (2) a power switch 4 VP pulse current charges the capacitor energy storage NE1 NE2 7 and 8. During the origin t ⁰ adopted at the time when the capacitors energy storage NE1 7 and NE2 8 fully charged (figa).

From the start control unit BUZ 12 at time t ⁰ , a signal is sent to the microcontroller input (2) from the output (2) of the signal to the input (2) of the microcontroller, which opens the first electronic switch EK1 10, made, for example, in the form of a thyristor, after what begins the discharge of the capacitors of the drive NE1 7 to the coil of the solenoid of the field-forming system PS 13. The current in the coil of the solenoid PS 13, and, accordingly, the magnetic field strength begins to increase according to a sinusoidal law (figa). At time t ⁰ + τ / 2 (where τ is the period of natural oscillations of the solenoid circuit), when the current reaches a maximum (Fig. 4a), a signal is received from the output (3) of the signal NE1 7 to the input (5) of the signal microcontroller MK 9. This signal from the output (4) of the signal MK 9 receives a signal at the input (2) of the second electronic switch EC2 11. There is an opening of EC2 11, made, for example, in the form of a thyristor. Under the influence of this signal at time t ⁰ + τ / 2 (Fig. 4), arriving from MK 9, the discharge of NE2 8 capacitors to the solenoid coil of the PS 14 field-forming system begins. Then, the current in the PS 14 solenoid coil begins to increase (Fig. 5g ), and, accordingly, the magnetic field strength, the vector of which is perpendicular to the plane of the magnetic carrier of the MINI 15. At the same time, the magnetic field of the coil of the solenoid PS1 13 decreases. The vector of the total magnetic field rotates and reaches an angle of 90 ° relative to the plane of the MINI 15 at time t ⁰ + τ, when the current in the solenoid coil 13 PS1 is zero, and a solenoid coil 14 is maximal PS. Further, the current in the coil PS1 13 changes direction and begins to increase in amplitude, and the current in the coil PS2 14 decreases. In this case, the vector of the total magnetic field strength rotates in the same plane and reaches an angle of 180 ° at the time t ⁰ + 3τ / 2, when the current in the coil of the solenoid PS1 13 is maximum, and in the coil of the solenoid PS2 14 is zero. Further, the process of rotation of the decreasing vector of the total magnetic field strength continues for several more periods until complete dissipation of the energy stored in the capacitors of the first NE1 7 and second NE2 8 energy storage devices, or to a certain level. The level of energy dissipation stored in the capacitors NE1 7 and NE2 8 is recorded and induced by the signals received at the inputs (5) and (6) of MK 9 and at time t ⁰ + T + τ / 2 (where T is the oscillation period of the generator current 25). When the dissipated energy reaches the level of the set value h (Fig. 4a), a switching occurs, and from the output (3) of the signal to the output (2), the signal receives a signal to the first electronic switch EC1 10, which closes it at time T + τ, and capacitors the first energy storage device NE1 7 go into charge mode (accumulation) of energy (Fig.5g). At time T + 3 / 2τ, the level of energy dissipation on the NE2 8 capacitors reaches h, and by the signal from the output (4) of the signal MK 9 to the input (2) of the signal EC2 11, the contacts are closed, EC2 11 - the thyristor is closed. As a result, NE2 8 capacitors go into charge mode.

The charge occurs when a stabilized power supply plus 12 V is supplied (Fig. 5a) to the power input (1) of the voltage divider DN 5 and from its output (3) to the power input (1) of the switching power supply IP 6 (Fig. 1, 2), and accordingly, it goes to the input (1) of the power of the first electronic key EKl1 24 (Figs. 2, 4) and to the inputs (3) of the power of the current generator of rectangular pulses 25, the second EKL2 27 and the third EKLZ 28 of electronic keys.

When the switch VP 4 (Fig. 1), the electronic key ECl1 24 (Fig. 7) generates a control signal in the form of a rectangular pulse (Fig. 5b) at its output (2), which is received at the input (1) of the signal generator 25 ( Fig. 8), a rectangular signal is generated, for example, in the form of a “meander” (Fig. 5c). This signal is fed to the signal input (1) of the key ECL2 27 (Fig.9) and to the input (1) of the signal delay line LZ 26 (Fig.2).

At the output (2) of the signal LZ 26, a rectangular signal is generated, shifted by half the period τ / 2 of the “meander” of the signal of the current generator 25 (Fig. 5c), and is fed to the input (1) of the signal of the second electronic key EKl2 27, which at its output (2) the signal generates a rectangular waveform (Fig.5d). When signals are received at the inputs (1) of the keys EKl2 27 and EKl3 28, the current from the output (2) of the power supply of the VP 4 and through the voltage divider DN 5 is supplied to the input (4) of the power of the first and second keys EKl2 27 and EKl3 28 (Fig. 1, 2 and 5) and through the inductance coils L1 of the keys ECl2 27 and ECl3 28 (Fig. 9), and the open transistor VT3, and then to the common zero terminal (4). At the outputs (1) of the keys EKl2 27 and EKl3 28, the voltage is less than 0.7 V - TTL logic zero (transistor-transistor logic), while the transistor VT3 closes, and the current in the coil L1 cannot instantly decrease due to the small time constant her chains. As a result, a positive pulse in the form of a voltage surge appears at the drain of the transistor VT3.

At the output (2) of the ECl3 key 28, a signal (Fig. 5f) of positive polarity is generated with a delay of half the oscillation period T / 2 of the current generator 25 signal. These signals are transmitted through the diode VD1 (Fig. 9) from the outputs (2) of the pulse power supply of the ECl2 keys 27 and EKl3 28 (fig.5d, e) and the outputs (2) and (3) IIP 6 are fed to the input (1) of the power supply of the first energy storage device NE1 7 and to the input (1) of the power supply of the second energy storage device NE2 8 and charge them ( 5g) to a level of 800 V ± 5%. Upon reaching the required voltage level, for example, after 1.0 sec, from the output (3) of the signal storage devices NE1 7 and NE2 8, the signals are supplied to the outputs (5) and (6) of MK 9. At the same time, from the powered control unit for starting the BUZ 12 from the output ( 2) the signal signal is fed to the input (2) signal MK 9. From the outputs (3) and (8) of the signal MK 9 are fed to the inputs of the first EK1 10 and second EK2 11 electronic switches that provide the creation of field-forming systems PS 13 and PS 14 pulsed magnetic field (figure 4), since the discharge of capacitors energy storage and NE1 7 and NE2 8 through the solenoids PS 13 and 14 (Fig. 4, 5g).

The applicant considers it necessary to draw the attention of the examination to the following. As noted above, in the case of parallel recording on a magnetic storage medium 15 of a circular shape (a hard disk drive, diskette), the effect of an external demagnetizing field 29 in the plane of the base of the magnetic carrier 15 is not the same for its various sections (Fig. 12), namely, the direction the external demagnetizing field 29 in parallel with the direction of magnetization 30 of the magnetic carrier 15 in the upper and lower parts of the disk in the drawing, and the direction of the external demagnetizing field 29 perpendicular to the magnetization 31 is magnetically of the carrier 15 to the left and right portions of the disk drawing. The axis of rotation of the disk is indicated by 32. With a perpendicular action, incomplete demagnetization is possible in the left and right parts of the magnetic disk in the drawing, which leads to residual magnetization in other parts of the surface of the magnetic disk.

Using a magnetic field with a rotating vector of tension in a plane passing through the axis of rotation of the magnetic disk and perpendicular to the plane of the magnetic carrier solves the problem of improving the quality and reliability of erasing information on a magnetic carrier, as the magnetization reversal of cells with different initial magnetization orientations occurs in a symmetrical way, i.e. e. the angles between the directions of the rotating vector of the intensity of the erasing magnetic field and the directions of magnetization during rotation successively coincide and regardless of the rectangularity of the hysteresis loop of the magnetic carrier, magnetization occurs until half the revolution of the vector of the intensity of the erasing magnetic field until the magnetic medium is saturated, which reduces the erasure time of records by more than two times.

To erase information on a magnetic medium with an unknown longitudinal or transverse form of recording, it is proposed to use the scheme of interaction of magnetic fields directed with the intensity vectors horizontally and vertically of the plane of the information medium, shown in Fig.3. According to the scheme, the magnetic carrier 15 with the axis of rotation 32 has, in general, unknown longitudinal or transverse recordings with the directions of the magnetization vectors indicated by 33 and 34. The magnetic carrier is located in the action space of the pulsed magnetic fields 35 and pulsed magnetic fields 36. PS solenoids 13 and PS 14 of the field-forming system are placed in space at an angle to each other, for example, 90 ° and are characterized by the fact that they are capable of summing the stress vectors of the generated pulse x magnetic fields to form the total strength vector of the rotating magnetic field pulse. 4, reference numeral 37 denotes the time variation of the magnetic field generated by the PS1 13 system solenoid, and position 38 denotes the temporal change of the magnetic field generated by the PS2 solenoid coil 14. Summation of pulsed magnetic fields and the operation of the device were discussed in detail above.

The use of a magnetic field with a rotating vector of its intensity in a plane passing through the axis of rotation of the magnetic disk and perpendicular to the plane of the magnetic carrier solves the problem of improving the quality and reliability of erasing information on a magnetic carrier, since the magnetization reversal of cells with different initial magnetization orientations occurs symmetrically, t .e. the angles between the directions of the rotating vector of the intensity of the erasing magnetic field and the directions of magnetization during rotation successively coincide and regardless of the rectangularity of the hysteresis loop of the magnetic carrier, magnetization occurs until half the revolution of the vector of the intensity of the erasing magnetic field until the magnetic medium is saturated, which reduces the erasure time of records by more than two times, and the continuation of rotation and stopping the rotation of the magnetic field vector according to a predetermined value th counter threshold disorients the magnetization direction and eliminates the remanence.

According to the established program, the output from the output (7) of MK 9 is fed to the input (1) of the first and second matrix magnetic field transducers MPMP 18 and MPMP 19 with magnetically sensitive elements 16 and 17 placed on them.

Under the action of an external pulsed magnetic field, erasure with a strength equal to the saturation field strength created by the field-forming systems PS 13 and PS 14, the nature of the domain structure of the films has changed. The magnetically sensitive elements 16 and 17 at this moment transmit a spatial picture of the domain structure and the magnetic relief from the erased information from each side of the magnetic information carrier 15 (Fig. 11) and this information is transmitted to the magnetically sensitive sides of the MPMP 18 and MPMP 19 of the information carrier.

From the matrix magnetic field transducers, as described previously, the information is read using the amplitude selector AC 20 and system unit 21. On the monitor 22 of the laptop 23 information about the magnetic relief (Fig. 11a, b) is visually observed, stored and compared on each particular plot magnetic media 15.

The implementation of the invention

The device for erasing recordings from magnetic media is made in accordance with the block diagram of FIG. 1, the switching power supply is made in accordance with the block diagram of FIG. 2 and circuit diagrams of FIGS. 9, 10, 11, energy storage devices 7 and 8 are made in accordance with a principle electrical circuit the circuit of Fig. 8.

As a power source used battery type 1 DT 12022.

The electronic key 2 is based on the transistor BVZ 11.

As a voltage converter 3, a step-down transformer, a rectifier and a stabilizer are used.

The power switch is made in the form of a switch type TV 1-2.

The voltage divider 6 is made on resistors of type C2-33.

The first electronic key 24 is made on the KT315 transistor, the square-wave generator 25 is made on the KR1006 VI1 chip, the delay line 23 is made on the KR1006 VI1 chip, the second and third electronic keys 27 and 28 are made on the VT1-BC846, VT2-BC856, VT3-1RFL014N circuits VD-D220A.

Energy storage devices 7 and 8 are made on capacitors K50-77 and a resistor type C2-33.

The microcontroller 9 is made on a chip type ATMEGA8-16A1.

The electronic switches 10 and 11 are made in accordance with the circuit diagram of Fig.13 on the diode 39 type 2D1330500-26 and thyristor 40 type 2T143-500-16.

The startup control unit 12 is made in the form of a pulse generator on a chip of a 6.000 MHz crystal oscillator (TTL) and resistors C2-33.

The first field-forming system 13 is designed as an inductance coil in the form of a parallelepiped with an internal cavity for placing a magnetic information carrier 15 and on each of the wide sides of the matrix magnetic field transducer 18 and 19 with magnetically sensitive film packets 16 and 17.

The second field-forming system 14 is made of two annular solenoids, which are placed coaxially on both sides of the inductance coil of the first field-forming system. The distance between the chokes is equal to or greater than the size of the narrow wall of the inductor of the first field-forming system.

The magnetically sensitive packets 16 and 17 are made of ferrite garnet material and are magnetically sensitive elements consisting of thin magnetic films with a domain structure of uniform nucleation.

The first and second matrix converters 18 and 19 are made in the form of a matrix of magnetodiodes (Fig.14).

The amplitude selector 29 is made on chips AD8551AR, AD7896JR, MAX3161EAG. The outputs from the matrix matrix converter of magnetic fields are alternately connected through an amplitude selector 20 according to the program from the microcontroller 9 to the input of the system unit 21, which synchronously scans the beam on the monitor screen 22.

The use of the claimed technical solution solves the problem of improving the quality of erasing information on a magnetic medium 15, increasing uniformity with simultaneous instrumental control of the structure of thin-film material, the magnetic relief of the recording before erasing information and after an external pulsed magnetic field using visual observation of relief fragments on any part of the magnetic medium 15 without extract the magnetic information carrier 15 from the working volume of the field-forming system 13.

The limiting features of the claims

The control unit, two sensors of the magnetic field strength, a magnetic field recording device, two energy storage devices, two electronic switches, a power supply and two field-forming systems made on solenoids, the vectors of the magnetic fields created by them in the area of the magnetic storage medium are orthogonal.

Features of the claims

The key is electronic KE 2, which has a power input (1), the first terminal (4) of common zero, the second terminal (2) “plus”, the third terminal (3) power output.

A voltage converter PN 3 from alternating to direct voltage, which has an input (1) of alternating voltage and an output (2) of direct voltage, and a common zero terminal (4).

VP 4 power switch, which has an input (1) and an output (2).

The voltage divider DN 5, which has an input (1) and the first (2) and second (3) power outputs.

The source of the pulse voltage is IP 6, which has a power input, two pulse signal outputs and a common zero terminal.

Microcontroller MK 9, which has a power input (1), three inputs (2), (5), (6) signal and three signal outputs (3), (7), (8), and a common zero terminal (4).

The power source is made in the form of a battery A 1, which has a plus terminal - a power input / output (1) and a common zero terminal (4).

The control unit is made in the form of a start-up control unit for erasing information BUZ 12, which has a power input (1), a signal output (2) and a common zero terminal (4).

The solenoid of the first field-forming system PS1 13 is made in the form of a parallelepiped with a through hole from the end face of a smaller face, which forms a working volume, the dimensions of which are larger than the dimensions of the information carrier.

The solenoid of the second field-forming system PS2 14 is made in the form of two ring coils connected in series and coaxially placed on the outer faces of the first solenoid and parallel to the plane of the information carrier.

The magnetic field sensors are made in the form of two magnetically sensitive elements MCHP1 16 and MCHP2 17 and matrix transducers of magnetic fields MPMP18 and MPMP.

Each magnetically sensitive element with one surface is fixed on one of the surfaces of its matrix magnetic field transducer, and the other side is firmly adjacent to one surface of the magnetic disk with recorded information, the second surfaces of the magnetic field transducers are fixed on the upper and lower surfaces of the working volume of the solenoid of the first field-forming system.

The magnetic field recording device comprises an amplitude selector AC 20, which has a first (1) and second (2) signal inputs and an output (3) signal, a system unit SB 21, which has two signal inputs (1) and (2), an output ( 3) signal, common zero terminal (4) and monitor M 22, which has a signal input.

The battery 1 input-output (1) of power is connected to the input-output (2) of the power of the electronic key 2, which is connected to the output (1) of the voltage converter 3, the input (2) of the power of which is connected to the industrial AC network current.

The DC voltage output of the voltage transformer PN 3 is connected to the input (1) of the power supply of the electronic KE 2 key, and its AC voltage input is connected to the industrial network.

The output (3) of the power supply of the electronic key 2 is connected to the input (1) of the power supply of the VP 4 power switch, and its output (2) of the power is connected to the power input (1) of the voltage divider DN 5.

The first output (2) of power supply for the voltage divider DN 5 is connected to the input (1) of the power supply of the microcontroller MK 9 and the input (1) of the power supply to the launch control unit BUZ 12, the output of which is connected to the first input (2) of the signal microcontroller MK 9, the second output (3 ) the power supply of the voltage divider DN 5 is connected to the input (1) of the power supply of the switching power supply IIP 6.

The first output (2) of the power supply of the pulse power supply UPS 6 is connected to the input (1) of the power supply of the first energy storage device NE1 7, the signal output (3) of which is connected to the second input (5) by the signal MK 9, the output (2) of the pulse voltage of the first energy storage device NE1 7 is connected to the input (1) of the pulse voltage of the first solenoid 13, the output (2) of which is connected to the signal input (1) of the first electronic switch EC 1 10, the second input (2) of the signal electronic switch EC1 10 is connected to the first output (3) signal MK 9.

The second output (3) of the pulse power supply IIP 6 is connected to the input (1) of the power supply of the second energy storage device NE2 8, the signal output (3) of which is connected to the third input (6) of the signal microcontroller MK 9.

The output (2) of the pulse voltage of the second energy storage device NE2 8 is connected to the input (1) of the pulse voltage of the second solenoid PS2 14 of the field-forming system, the output (2) of which is connected to the power input (1) of the second electronic switch EK211.

The second input (2) signal of the electronic switch EC2 11 is connected to the second output (8) of the signal microcontroller MK 9.

The third output (7) of the signal microcontroller MK 9 is connected to the inputs (1) of the matrix magnetic field converters MPMP 18 and MPMP 19 and the input (1) of the signal system unit SB 21, the output of which is connected to the input of the monitor 11.

The outputs (2) of the signal matrix transducers of magnetic fields MPMP 18 and MPMP 19 are connected respectively to the first (1) and second (2) inputs of the amplitude selector AC 20, the output (3) of which is connected to the second input (2) of the signal system block SB 21 whose output is connected to the monitor input.

The switching power supply of energy storage devices NE1 7 and NE2 8 has a power input (1) and two outputs (2) and (3) of a pulse signal and contains: the first electronic key EKl1 24, which has a power input (1), an output (2) signal and a common zero terminal (4), a second ECl2 27 and a third ECl3 28 electronic keys that have a first input (1) signal, a second power input (3), a pulse power output (2) and a common zero terminal (4), a current generator G 25, which has a signal input (1), a power input (3), a rectangular pulse output (2) and a common zero terminal (4) and a delay line LZ 26, The one that has a signal input (1) and output (2), and the input (1) of the power source connected to the power inputs of the first, second and third electronic keys, the input of the current generator, in addition, the common zero terminals of all these devices are connected together, the output of the first the electronic key is connected to the signal input of the current generator, the output of which is connected to the signal input of the second electronic key and the input of the delay line, the output of which is connected to the input of the third electronic key, and the outputs of the second and third electronic keys are outputs of the switching power supply.

The energy storage device contains two series-connected capacitors, to a common point of which a resistor is connected, the free terminal of one capacitor being the first input of the pulse power supply and the output of the discharge current, the free terminal of the second capacitor is grounded, the free terminal of the resistor is a signal output.

The key is electronic KE 2, which has a power input (1), the first terminal (4) of common zero, the second terminal (2) plus, the third terminal (3) power output, in addition, it has a normally open (NO) contact between the second (2) and fourth terminals (1) and a normally closed (NC) contact between the second (2) and third (3) terminals and a diode that is connected to the fourth terminal (1) by one output and the second terminal (2) by the other ) key of electronic CE 2.

The start control unit BUZ 12 contains the first and second resistors connected in series by the first terminals and the analog circuit DA1, and it has an input that is connected to the connection point of the resistors, in addition, the second terminal of one resistor is the input of the start control unit, and the output of the analog circuit is the output of the start control unit, and the grounded terminal of the analog chip is connected to the second terminal of the second resistor.

The amplitude selector AC 20 contains the first ДУ1 41 and the second ДУ2 42 differential amplifiers, each of which has an input (1) and an output (2), the first ADC1 43 and the second ADC 2 44 amplitude-digital converters, each of which has an input (1) and output (2), the INT 45 interface, which has two inputs, the first (1) and second (2) and output (3), the inputs of differential amplifiers being the inputs of the amplitude selector, and the output of the interface is the output of the amplitude selector, in addition, the output the first differential amplifier is connected to the input of the first amplitude but-digital converter, and the output of the second differential amplifier is connected to the input of the second amplitude-digital converter, whose outputs are connected to the corresponding input interface.

The magnetosensitive elements МЧП1 16 and МЧП2 17 are made in the form of packets of magnetosensitive films with different values of the field of uniform nucleation.

Matrix converters of magnetic fields MPMP 18 and MPMP are made in the form of matrices consisting of magnetically sensitive elements of magnetodiodes 46 (Fig.14a) or magnetotriodes 47 (Fig.14b) and have a power input (1) and signal output (2) (Fig. 1) in addition, storage capacitors 48 are connected in parallel with the magneto-diodes, and in the circuit with magnetotrides, the capacitors 48 are connected to the emitter-base circuit, and a diode 49 is connected to the collector-base circuit, which sets the bias — the operation mode of the magnetotriode (47).

Claims (8)

1. A device for erasing records from magnetic media contains: a control unit, two sensors of magnetic field strength, a device for recording magnetic field strength, two energy storage devices, two electronic switches, a power source and two field-forming systems made on solenoids, vectors of magnetic intensities created by them fields are orthogonal in the area of the magnetic storage medium, characterized in that the following are entered: an electronic key that has a power input, a first common zero terminal, a second the plus terminal, the third terminal is the power output, an AC to DC voltage converter that has an AC voltage input and a DC voltage output and a common zero terminal, a power switch that has an input and an output, a voltage divider that has an input and the first and the second power outputs, a pulse voltage source, has a power input, two pulse signal outputs and a common zero terminal, a microcontroller that has a power input, three signal inputs and three signal outputs and a common terminal For that, in addition, the power source is made in the form of a battery, which has a “plus” terminal - a power input-output and a common zero terminal, and the control unit is made in the form of a control unit for launching an information erasing device that has a power input, signal output, and a terminal total zero, in addition, the solenoid of the first field-forming system is made in the form of a parallelepiped with a through hole from the end of the smaller face, which forms a working volume and the dimensions of which are larger than the dimensions of the information carrier, the solenoid of the second field the forming system is made in the form of two ring coils connected in series and coaxially placed on the outer faces of the first solenoid parallel to the plane of the information carrier, in addition, the magnetic field sensors are made in the form of two magnetically sensitive elements and matrix magnetic field transducers, each magnetically sensitive element being fixed to one surface on one of the surfaces of its matrix transducer of magnetic fields, and the other side is tightly adjacent to one turn the magnetic disk with recorded information, the second surfaces of the magnetic field transducers are mounted on the upper and lower surfaces of the working volume of the solenoid of the first field-forming system, in addition, the magnetic field recording device contains an amplitude selector that has first and second signal inputs and a signal output, system unit which has two signal inputs, a signal output, a common zero terminal and a monitor that has a signal input, and the battery connected to the input-output power of the electronic key, which is connected by its power input to the output of the voltage converter, the power input of which is connected to the industrial AC network, in addition, the DC voltage output of the voltage converter is connected to the power input of the electronic key, and the power output of the electronic key is connected to the power input of the power switch, and its power output is connected to the power input of the voltage divider, in addition, the first power output of the voltage divider is connected the power input of the microcontroller and the power input of the start control unit, the output of which is connected to the first input of the signal microcontroller, the second voltage divider power output is connected to the power input of the switching power supply, and the first power supply of the switching power supply is connected to the power input of the first energy storage device, the signal output of which connected to the second input of the signal microcontroller, the pulse voltage output of the first energy storage device is connected to the pulse voltage input with the lenoid of the first field-forming system, the output of which is connected to the signal input of the first electronic switch, the second signal input of which is connected to the first output of the signal microcontroller, in addition, the second output of the pulse power source is connected to the power input of the second energy storage device, the signal output of which is connected to the third signal input microcontroller, and the output of the pulse voltage of the second energy storage device is connected to the input of the pulse voltage of the solenoid of the second field generating system the output of which is connected to the power input of the second electronic switch, in addition, the second signal input of the second electronic switch is connected to the second output of the signal microcontroller, the third output of the signal microcontroller is connected to the inputs of the matrix magnetic field converters and the input of the signal system unit, the output of which is connected to the monitor input, in addition, the signal outputs of the matrix magnetic field converters are connected respectively to the first and second inputs of the amplitude projector of, the output signal of which is connected to the second input signal of the system unit whose output is connected to an input of the monitor. 2. The device for erasing records from magnetic media according to claim 1, characterized in that the switching power supply of the energy storage devices has a power input and two pulse signal outputs and comprises: a first electronic key that has a power input, a signal output and a common zero terminal, second and third electronic switches that have a first signal input, a second power input, a pulse power output and a common zero terminal, a current generator that has a signal input, a power input, a rectangular pulse output and a common zero terminal, and a delay line, which has a signal input and output, and the input of the power source is connected to the power inputs of the first, second and third electronic keys, the input of the current generator, in addition, the common zero terminals of all these devices are connected together, the output of the first electronic key is connected to the signal input a current generator, the output of which is connected to the signal input of the second electronic key, the input of the delay line, the output of which is connected to the input of the third electronic key, and the outputs of the second and third electronic keys are the outputs of the switching power supply. 3. The device for erasing records from magnetic media according to claim 1, characterized in that the energy storage device contains two series-connected capacitors, to the common point of which a resistor is connected, the free terminal of one capacitor being the first input of the pulse power and the discharge current output, a free terminal the second capacitor is grounded, the free terminal of the resistor is a signal output. 4. The device for erasing records from magnetic media according to claim 1, characterized in that the electronic key has a power input, a first common zero terminal, a second plus terminal, a third power output terminal, in addition, it has a normally open contact between the second and the fourth terminals, and a normally closed contact between the second and third terminals and a diode, which is connected to the fourth terminal with one terminal and the electronic key with the second terminal. 5. The device for erasing records from magnetic media according to claim 1, characterized in that the launch control unit comprises first and second resistors connected in series by the first terminals and an analog microcircuit, the analog microcircuit having an input that is connected to the connection point of the resistors, except in addition, the second terminal of one resistor is the input of the start control unit, and the output of the analog chip is the output of the start control unit, and the grounded terminal of the analog chip is connected to the second glue My second resistor. 6. The device for erasing records from magnetic media according to claim 1, characterized in that the amplitude selector contains a first and second differential amplifiers, each of which has an input and an output, first and second amplitude-digital converters, each of which has an input and an output , an interface that has two inputs, the first and second, and an output, and the inputs of the differential amplifiers are the inputs of the amplitude selector, and the output of the interface is the output of the amplitude selector, in addition, the output of the first differential amplifier The spruce is connected to the input of the first amplitude-to-digital converter, and the output of the second differential amplifier is connected to the input of the second amplitude-to-digital converter, the outputs of which are connected to the corresponding input of the interface. 7. The device for erasing records from magnetic media according to claim 1, characterized in that the magnetically sensitive elements are made in the form of packets of magnetically sensitive films with different values of the field of uniform nucleation. 8. The device for erasing records from magnetic media according to claim 1, characterized in that the matrix magnetic field transducers are made in the form of matrices consisting of magnetically sensitive elements of magnetodiodes or magnetotriodes and have a power input and signal output, in addition, capacitors are connected in parallel with the magnetodiodes, and in the circuit with magnetotrides, capacitors are connected to the emitter-base circuit, and a diode is connected to the collector-base circuit.

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