RU2232435C2 - Device for erasing records from magnetic medium - Google Patents

Abstract

FIELD: erasing records from magnetic data media, primarily from hard disks.

SUBSTANCE: device has two channels, each incorporating dc voltage supply, solenoid, storage capacitor bank, switch for connecting storage capacitor bank to solenoid capacitor, and damping diode connected in parallel with the latter. Newly introduced in each channel are controlled charge interrupter, voltage comparator, availability comparator, voltage divider, and switch triggering unit. Controlled charge interrupter is inserted in series with charging circuit of storage capacitor bank from dc voltage supply. Control input of charge interrupter is connected to output of voltage divider The latter is connected in parallel with storage capacitor bank. First input of availability comparator is also connected to voltage divider output. Second inputs of charge and availability comparators are connected to reference voltage sources. Inserted between control unit and switch is switch triggering unit. Control unit shared by both channels of device provides for erasing known and unknown records from magnetic medium.

EFFECT: enhanced erasing reliability without increasing time.

5 cl, 2 dwg

Description

The invention relates to techniques for magnetic recording and is intended to erase recording from magnetic storage media, mainly from hard drives, by magnetization.

A device is known for demagnetizing a magnetic information carrier (hereinafter referred to as a magnetic medium), preferably a hard magnetic disk, located in a feed system for hard magnetic disks, comprising a demagnetizing coil with a cavity in which a hard magnetic disk for demagnetizing is placed. The device has a capacitor, which together with the demagnetizing coil forms a resonant circuit. The parameters of the capacitor and demagnetizing coil are such that the resonant frequency of the oscillations of the circuit corresponds to the frequency of the alternating current (1).

The disadvantage of this device is that the generated magnetic field with a frequency of 50/60 Hz is uneven. The demagnetization time is determined by the repeated exposure to a magnetic storage medium by a resonant magnetic field. The direction of the demagnetization vector is constant and parallel to the plane in which the feed device with the hard magnetic disk is located. To create the maximum current I _max ) flowing through the demagnetizing coil of the circuit, a block of capacitors and a rheostat will be required to constantly adjust the resonance characteristic, since the leakage current is constantly present in the system.

Consider the disadvantages of this known device in more detail.

A hard magnetic disk is a massive metal object. Once placed in the resonant circuit, it will change the resonant frequency of the LC circuit. Therefore, for each type of hard magnetic disk, it will be necessary to adjust the resonant frequency of the circuit, which should be 50/60 Hz (frequency of the industrial network).

The resonant nature of the creation of a powerful magnetic field requires a high quality factor of the oscillatory circuit. The introduction into the oscillatory circuit of a metal object, which is a drive on a hard magnetic disk (hereinafter referred to as HDD), reduces the quality factor of the circuit, even if the object is made of a ferromagnet, since at the required field strengths it loses its ferromagnetic properties. Obtaining high quality factor in such conditions becomes almost a very difficult technical task, requiring a significant increase in inductance, and hence the mass and size of the solenoid coil. That is, this solution is optimally suited only for "open-frame" magnetic storage media that do not have a metal case (cassettes, floppy disks, etc.).

In order for the energy stored in the resonant circuit, and therefore the magnetic field, to reach a maximum, such an amount of oscillation is required that is not less than the quality factor of the oscillatory circuit. If the quality factor of the oscillating circuit is 200, it will take more than 200 periods of oscillation or more than 4 seconds after switching on the oscillatory circuit so that the magnetic field reaches its maximum value. Prolonged inclusion unnecessarily leads to increased energy consumption.

The magnetic field vector is directed along one straight line, which is ineffective for demagnetizing information carriers such as hard disk drives (HDD), when the orientation of the magnetization vector changes in different places. For guaranteed destruction of information, many times greater magnetic field energy is required if the magnetic field vector is perpendicular to the magnetization vector.

There is also known a device for erasing recordings on magnetic media, containing two channels, each of which includes a constant voltage source, a solenoid, a block of storage capacitors, a switch for connecting a block of storage capacitors to a solenoid, in parallel with which a damping diode is connected, as well as a control unit common to the channels (2). The device described in this source is adopted as a prototype of the claimed invention, since it is closest to it in terms of the combination of common essential features and the achieved result.

Consider this well-known technical solution to the problem in more detail. As follows from its description, this device must contain at least two oscillatory circuits. Each oscillatory circuit consists of a constant voltage source, a solenoid with a damping diode and a polar capacitor, which is connected through a two-position switch alternately to the source and the solenoid. The solenoids of the adjacent circuits are installed with the possibility of orientation of the intensity vectors of the created fields, rotated relative to each other by an angle not equal to 180 ° and 360 °. The magnetic storage medium is magnetized by a series of unipolar magnetic pulses.

The disadvantage of this known device is that it does not provide a sufficiently reliable and uniform erasure of the record. This is due to the fact that to erase the recording in this device, it is necessary to create a pulsed magnetic field of a certain value with a certain vector orientation in one oscillatory circuit formed by capacitor C1 and inductance L1, and to create a pulsed magnetic field with the same value and with the orientation of the vector changed to angle α, in another oscillatory circuit formed by capacitor C2 and inductance L2. However, due to the fact that both oscillatory circuits are located on the same frame, the angle α is several degrees, the capacitance values of the capacitors C1 and C2 and the values of the inductances L1 and L2 and their active resistances of the switching elements K1 and K2 are different and cannot be equal to each other (since commercially available capacitors that can be used in this device, for example K50-17, have deviations in capacitance values from + 50% to -10%, in leakage current up to 9 mA, in loss tangent up to 20%), then to create equal pulsed magnetic n For fields with vector orientations different by the angle α, capacitors are required whose storage capacity is large enough, because it is determined by the value of the generated pulsed magnetic fields in the solenoids to erase the recording, taking into account the nonlinearity of the fields throughout the volume of the hard magnetic information carrier and losses, which are determined by technological processes and materials from which hard magnetic media are made.

From the foregoing in the previous paragraph it follows that the known device does not provide the creation of equal in value of the intensity of the pulsed magnetic fields with the orientation of the vectors, which are changed by the angle α.

In addition, it should be noted that during operation of the device, the voltage across the capacitors of capacitive storage devices having, as noted above, capacities different in magnitude, is not always constant due to different values of leakage currents and due to the fact that the mentioned voltage across the capacitors of capacitive storage varies in time due to with instability of the voltage source.

The inclusion of capacitors of a capacitive storage device, as is the case in the prototype, limits the stored energy to the maximum voltage allowed for the capacitor. Therefore, to achieve the required value of the pulsed magnetic field to ensure reliable erasing of information from a hard magnetic carrier, a large capacitor with a high operating voltage will be required, and, as you know, large capacitors and high operating voltage have large dimensions and weight, which is impractical.

In addition, the source (2) indicates that two or more inductors are on the same frame. The shift of the magnetic field vector from coil to coil is carried out by changing the angle of winding of the coils. With this design, the angle between the vectors of the magnetic field strengths of the coils cannot be equal to 90 °, which does not allow the effective use of this device to destroy information by the same device as on hard disk drives (HDD) with surface (horizontal) magnetization, and on media with perpendicular (vertical) magnetization. The realistically achievable angle between the magnetic field vectors in this design is several degrees, which is not enough for reliable destruction of information in a hard disk drive (HDD) recorded using the vertical magnetization method.

Exposure to multiple series of sequentially generated magnetic fields only increases the energy consumption and complexity of the circuit, but practically does not improve the quality of information destruction due to the small angle between the magnetic field vectors between the coils, which does not allow maintaining the current in the solenoids necessary to obtain the magnetic field with the required to reliably erase the recording with the tension value.

The purpose of the claimed technical solution is to improve the quality of erasing recordings on a magnetic medium without deteriorating energy indicators and increasing the time spent on erasing a recording, carried out on the principle of magnetizing a magnetic medium until it is saturated with a magnetic field created by current pulses arising in solenoids when connected to storage capacitors, pre-charged through a key from a constant voltage source, due to voltage stabilization on capacitive storage Connected parallel to a direct voltage source by stabilizing the latter. In this case, before erasing a recording on a magnetic medium, it may be known or unknown what type of recording is on a magnetic medium, namely, a recording is made along or across the magnetic track on the hard disk.

Erasing the record can be carried out by a magnetic field, the solenoids of which are mutually perpendicular.

In addition, the claimed invention allows to achieve the goal, namely, that when you select the appropriate mode of the claimed device, you can erase the record as with a known or unknown type of recording on a magnetic disk.

The goals are achieved in that in a device for erasing recordings on a magnetic medium containing two channels, including a constant voltage source, a solenoid, a storage capacitor block, a switch for connecting a storage capacitor block to a solenoid, in parallel with which a damping diode is connected, as well as a common channel a control unit according to the invention, a controlled charge chopper, a voltage comparator, a ready comparator, a voltage divider and a switch trigger unit are introduced into each channel pa, and the controlled charge chopper is connected in series to the charge circuit of the storage capacitor unit from the constant voltage source, and the control input of the charge chopper is connected to the output of the voltage divider, which is connected in parallel with the storage capacitor unit, the first input of the availability comparator is also connected to the output of the voltage divider, the second inputs the charge comparator and the availability comparator are connected to voltage reference sources, and the start block is connected between the control unit and the switch ka switch.

The specific implementation of the individual nodes and elements of the claimed device may be different.

For example, in a particular embodiment, the DC voltage source of the device may comprise a rectifier, consisting of two diodes connected in series and increasing the winding of the network transformer, the bipolar outputs of the rectifier diodes being outputs for connecting to the plates of the corresponding capacitors of the storage capacitor unit, one of the terminals of the increasing winding of the network transformer is a terminal for connecting to the input of the rectifier through a charge chopper, and the other terminal of the winding with tevogo transformer is output for connection to a common connection point of the capacitor bank of storage capacitors.

In a particular embodiment of the device, a controlled charge chopper can be made on an opto-simmistor and have two inputs, a power and a control, and two corresponding outputs, the power input being an input for connecting to one of the taps of the boost winding of a network transformer, and the power output is an output for connecting to the common point of connection of the rectifier diodes, the control input is an input for connecting to the output of the voltage comparator, and the control output is an output for connecting to a common point connection of the rectifier diode and the capacitor plate of the storage capacitor unit with the common bus of the entire device.

In a particular embodiment of the device, the switch can be made on a thyristor and its power electrodes can be connected one to the first output of the solenoid, and the second to the common bus of the entire device, and the switch start unit can be made on a solid-state relay, the first and second taps of which are combined and through a resistor are connected to an additionally introduced low-voltage source, and a parallel-connected zener diode and capacitor of the switch trigger unit are connected between said resistor and it with the bus of the entire device, the third tap of the solid-state relay is connected to the output of the additionally introduced voltage regulator, the fourth tap is connected through the resistor divider to the control electrode of the divider, and the fifth tap is an input for connecting to the first output of the control unit.

In a particular embodiment of the device, the solenoids of both channels can be arranged so that their longitudinal axes are mutually perpendicular, and there is a cavity inside one of the solenoids to accommodate the magnetic carrier.

A comparison of the claimed device and the closest analogue (prototype) shows that the common essential features are the presence of two channels containing a constant voltage source, a solenoid, a capacitive storage in the form of a capacitor block, a switch for connecting a capacitive storage to a solenoid, in parallel with which a damping diode is connected, and a common control unit for channels.

Distinctive features are the introduction into each channel of a controlled charge chopper, a voltage comparator and a standby comparator, a voltage divider and their connections to each other and to the units included in the device as common with the closest analogue, and these connections are described in detail above.

The implementation of a charge chopper, a constant voltage source, a switch with a start block, a control unit and the relative position of the solenoids are claimed as particular significant distinguishing features.

The described sets of essential features provide in the inventive device a stabilized supply of solenoids from storage capacitors from constant voltage sources, and stabilization is carried out due to the fact that the units of the device form a constantly working closed-loop control circuit (the operation of which is described below), which characterizes the causal relationship between the essential signs and technical result in the proposed device.

The invention is illustrated by drawings.

Figure 1 shows a circuit diagram of the proposed device, the initial part;

figure 2 is the same ending.

The claimed invention contains a network transformer 1 with increasing windings 2 and 3, respectively, for the first channel 4 and the second channel 5, as well as a decreasing winding 6. The charge chopper 7 made on the opto-simistor has a first input that is connected to the first terminal of the increasing winding 2 of the network transformer 1. The second terminal of the boost winding 2 of the network transformer 1 is connected to a common connection point of the storage capacitor unit 8 of the first channel 4, connected in parallel to the rectifier 9 with its second terminals. The first output of the charge chopper 7 performed on the opto-simistor is connected to the common connection point of the rectifier diodes 9. The second output of the charge chopper 7 made on the opto-simistor is connected to the common bus of the entire device (ground), and the first input of the charge chopper 7 made on the opto-simistor is connected through a current-limiting resistor with a boost winding 2 of the network transformer 1.

The device also includes a voltage divider 10 connected in parallel with the rectifier 9 and the storage capacitor bank 8 of the first channel 4. The voltage divider 10 has a high voltage arm 11 and a low voltage arm 12. The voltage comparator 13 is made on a microcircuit 14 and has terminals 15, 16, 17, 18, 19, 20, 21 and LED 22. Terminal 15 is connected to the common bus of the entire device (ground), terminal 16 is connected to the second branch of the low-voltage arm 11 of voltage divider 10, terminal 17 is connected through a resistor 23 to LED 22, which is connected to the second terminal to second input interrupt charge of Tell 7, terminal 20 - first finger to the low voltage leg 12 of the voltage divider 10, elbows 18 and 21 are connected with the resistor divider at resistors 24, 25 and 26 to a source of DC stabilized voltage. Resistor 24 is variable. A terminal 19 of the microcircuit 14 of the voltage comparator 13 is connected to its engine through a resistor 27. A capacitor 28 is connected between the terminal 19 and the common bus of the entire device (ground).

The availability comparator 29 is identical to the voltage comparator 13 and is connected in parallel with it. The design of the availability comparator 29 includes an LED 30, a resistor 31, a microcircuit 32, resistors 33, 34, 35, capacitors 36 and 37. The microcircuit 32 has pins 38, 39, 40, 41, 42, 43, 44. All of these elements of the availability comparator 29 are connected similarly to voltage comparator 13, with the exception of capacitor 37. Capacitor 37 is connected between the low voltage arm 12 of voltage divider 10 and the common bus of the entire device (ground). From the above it follows that the voltage comparator 13 and the availability comparator 29 are made according to known schemes for comparing DC voltage signals on chips of the KR1006VI1 type, in the output circuit of which indicators on the LEDs are included. The device also contains a block 45 of the switch, containing the actual switch 46 on the thyristor connected between the first tap of the solenoid 47 and the common bus of the entire device (ground). In parallel with the solenoid 47, a damping diode 48 is connected. The second tap of the solenoid 47 is connected to a common connection point of the rectifier 9, the storage capacitor unit 8 of the first channel 4 and the voltage divider 10. The switch unit 45 includes a switch start circuit made on a solid state relay 49 having taps 50, 51, 52, 53, 54, and the tap 52 through the resistor divider, consisting of resistors 55.56, connected to the control electrode of the thyristor 46, the taps 53 and 54 are interconnected and connected through a resistor 57 to the diode bridge 58 of the source 26 low power supply (voltage stabilizer), taps 53 and 54 through a parallel-connected circuit of the zener diode 59 and capacitor 60 are connected to the common bus of the entire device (ground), tap 50 is connected to the diode bridge 58 of the constant voltage source 26, and tap 51 is connected to the output of the unit control 61. It should be noted that, in particular, the switch start-up unit can be made on a solid-state relay, for example, КР293КП11АП, and the charge interrupter 7 - on an opto-simmistor, for example, MOS3063. We now consider the control unit 61. It contains three on-off buttons 62, 63, 64, an LED 65 connected between the button 64 and the resistor 66, which is connected to a constant voltage source 26. The control unit 61 has two outputs for connecting to the tap 51 of the start circuit of the switch made on the solid-state relay 49 of the first channel 4 and to the identical start circuit of the switch of the second channel 5. These two outputs of the control unit 61 through the resistors 67 and 68 are respectively connected to the power buttons off 62 and 64. Resistors 67 and 68 through counter-on diodes 69 and 70 are connected to the on-off button 63.

The device also contains a solenoid 71 of the second channel 5 and a block of storage capacitors 72 of the second channel 5. The solenoids 47 and 71 can be made, for example, as follows: solenoid 47 is a winding wound on a hollow frame of rectangular cross section, into the cavity of which a magnetic information carrier is installed subject to exposure to a pulsed magnetic field, i.e. magnetic media, the recording on which is subject to erasure. The solenoid 71 consists of two semi-windings, each of which is wound on a circular cross-section of the frame, the longitudinal axis of which is perpendicular to the longitudinal axis of the rectangular frame of the first solenoid 47. The frames of the solenoid 71 are coaxially placed above and below the rectangular frame of the first solenoid 47. This embodiment creates a magnetic field whose tension vectors are mutually perpendicular.

The device operates as follows.

Since it contains two identical channels for the formation of a magnetic field, we first consider the operation of one channel.

An alternating voltage of 315 volts from the mains transformer 1 is supplied to the rectifier 9 through a charge chopper 7 on the opto-simistor. The rectified voltage is supplied to the storage capacitor unit 8 of the first channel 4. The voltage divider 10 provides a proportional voltage division across the storage capacitor unit 8 of the first channel 4 to ensure operation comparators. The voltage comparator 13 compares the voltage from the voltage divider 10 with the reference voltage, and when the voltage at the storage capacitor bank 8 of the first channel 4 reaches a value of approximately 810 volts, it sends a signal to the charge chopper 7 made on the opto-simulator, which stops the charge. After that, the discharge of the block of storage capacitors 8 of the first channel 4 begins through the voltage divider circuit 10 and due to leakage currents. When the voltage at the block of storage capacitors 8 of the first channel 4 is reduced to a value of about 800 volts, the voltage comparator 13 generates a signal to turn on the charge chopper 7 made on the opto-simistor and the charge resumes. When the voltage at the block of storage capacitors 8 of the first channel 4 reaches a value of about 810 volts, the charge again ceases. This process is repeated continuously until disconnected from the mains.

The availability comparator 29 compares the voltage from the voltage divider 10 with the specified one. When the voltage at the storage capacitor bank 8 of the first channel 4 reaches a value of about 805 volts, the availability comparator 29 turns on the ready indicator on the LED 30. The ready comparator 29 turns off when the voltage at the storage capacitor bank 8 of the first channel 4 is about 795 volts. Thus, with a constant change in voltage at the storage capacitor unit 8 of the first channel 4 during recharging, the ready indicator on the LED 30 does not go out.

The exact adjustment of the comparators to the given operating voltages is provided with the help of the adjustment elements of the resistors 24 and 34.

When the start button is pressed, the block of the switch 45 is activated and the block of storage capacitors 8 of the first channel 4 is discharged through the switch to a solenoid 47, in which a pulsed magnetic field is formed due to the flowing current. Consider this device operation in more detail.

When the opto-simistor of the charge interrupter 7 is open, the storage of the storage capacitor unit 8 of the first channel 4 begins. Consider this process relative to the midpoint of the storage capacitor unit 8 of the first channel 4, to which one of the terminals of the winding of the network transformer 1 is connected. The voltage wave from the network transformer 1 passes through a current-limiting resistor and optosimistor of the charge interrupter 7 to the common point of connection of the diodes. Further, after passing through the rectifier 9, a positive half-wave through one diode charges one of the capacitors of the storage capacitor unit 8 of the first channel 4 positively, and a negative half-wave through the other diode charges the other capacitor of the storage capacitor unit 8 of the first channel 4 negatively. Thus, the voltage of the charges of the capacitors is equal in amplitude, but opposite in sign, regardless of the variation in the capacitance values of these capacitors. Since the capacitors are connected in series, the total voltage on the block of storage capacitors 8 of the first channel 4 is equal to twice the charging voltage and is about 800 volts.

The high voltage arm 11 of the voltage divider 10 is connected in parallel to one capacitor of the storage capacitor unit 8 of the first channel 4, therefore, a signal proportional to the total voltage of the storage capacitor unit 8 of the first channel 4 is supplied from it to the voltage comparator 13, which is compared with the reference voltage. The reference voltage is generated using the internal divider of the microcircuit 14 and an external divider, consisting of resistors 24, 25, 27. A tuned resistor 24 allows changing the reference voltage within ± 5% to fine tune the voltage on the block of storage capacitors 8 of the first channel 4. Capacitors 36 and 28 eliminate false positives from interference.

The effective value of the alternating voltage on the boost winding of the network transformer 1 at a rated voltage of the supply network is 315 volts, therefore, the amplitude value of the voltage is 445 volts. This voltage is used to charge the block of storage capacitors 8 of the first channel 4. The voltage divider 10 provides a proportional decrease in voltage by 100 times. The voltage comparator 13 compares the voltage from the voltage divider 10 with the reference voltage (about +8 volts). At the beginning of the charging process, when the voltage at the block of storage capacitors 8 of the first channel 4 is small, at the output of the chip 14 (pin 17), the voltage is close to +12 volts. The current from the output of the microcircuit 14 flows through a circuit consisting of a resistor 23, an LED 22, an optosimistor of the charge interrupter 7, a common bus of the entire device (earth). As a result, the LED 22 is lit, the opto-simistor of the charge interrupter 7 is open, the storage capacitor bank 8 of the first channel 4 is charging. When the voltage at the storage capacitor bank 8 of the first channel 4 reaches 810 volts at the output of the microcircuit 14 (terminal 17), the voltage becomes close to zero volts . The LED 22 goes off, the opto-simistor of the charge interrupter 7 closes, the charge of the capacitors of the storage capacitor unit 8 of the first channel 4 stops. After that, the discharge of the block of storage capacitors 8 of the first channel 4 begins through the voltage divider circuit and due to leakage currents. When the voltage on the block of storage capacitors 8 of the first channel 4 decreases to a value of about 800 volts at the output of the microcircuit 14 (pin 17), the voltage again becomes close to +12 volts. The charge of the storage capacitor unit 8 of the first channel 4 is resumed. This process is repeated continuously until the device is disconnected from the mains.

The microcircuit 32 of the availability comparator 29 is connected by inputs in parallel to the microcircuit 14 of the charge comparator 13 to a common voltage divider. The circuit diagram of the comparators is identical except that the ready indicator, made in the form of an LED 30, located on the front panel, is connected to the output of the microcircuit 32. To fine-tune the response voltage of the availability comparator 29, a tuning resistor 34 is used.

When the voltage at the block of storage capacitors 8 of the first channel 4 is reached, the value is approximately 805 volts at the output of the microcircuit 32 (terminal 44), the voltage is close to +12 volts. The ready indicator on the LED 30 lights up. The turn-off indicator on the LED 30 is turned off when the voltage at the storage capacitor unit 8 of the first channel 4 is approximately 795 volts. Thus, with a constant change in voltage at the storage capacitor unit 8 of the first channel 4 during recharging, the ready indicator on the LED 30 does not go out.

A voltage of +21 volts from the diode bridge 58 of the low-voltage power supply 26 through a resistor 57 is supplied to the capacitor 60 and charges it. The voltage on the capacitor 60 in standby mode is +15 volts due to the limitation of the zener diode 59. This is necessary to eliminate the effect of voltage changes in the supply network on the start circuit.

When you press the on / off button 62 (otherwise it is called the "Start 1" button), the current from the constant voltage source 26 flows through the solid state relay 49, resistor 67, the on / off button 62 to the common bus of the entire device (ground). In this case, the solid-state relay 49 is turned on, the capacitor 60 is discharged through the current-limiting resistor 55 of the resistor divider to the control transition of the thyristor of the switch 46, which opens. The discharge of the storage capacitor unit 8 of the first channel 4 begins along the circuit: the positive output of the first capacitor of the storage capacitor unit 8 of the first channel 4, the solenoid 47, the thyristor of the switch 46, the negative output of the second capacitor of the storage capacitor unit 8 of the first channel 4. As the current increases in this In the circuit, the voltage decreases on the block of storage capacitors 8 of the first channel 4. At the moment of reaching the maximum current, the electromotive force of the solenoid 47 changes polarity. This opens the damping diode 48 (then the current flows through the circuit of the solenoid 47, the damping diode 48), the thyristor of the switch 46 closes and the charge of the storage capacitor unit 8 of the first channel 4 starts again. The current flowing through the solenoid 47 creates a magnetic field.

Both channels of the solid state relay 49 are connected in parallel to reduce losses and increase the permissible current strength of the switched current.

Counter diodes 69 and 70 enable either of both channels 4 and 5 to be turned on simultaneously from the on / off button 63 (otherwise it is called the “Start 2 ″ button) or each channel separately from the on / off button 62 (otherwise it is called the“ Start ”button 1 ") or on / off buttons 64 (otherwise this button is called" Start 3 ").

Thus, the solenoids 47 and 71 of the two channels 4 and 5 provide the formation of two mutually perpendicular magnetic fields due to the pulsed currents supplied to each solenoid through the corresponding switch from the corresponding capacitor of the storage capacitor unit 8 of the first channel 4. The record deposited on a magnetic medium placed in the cavity of the coil of the solenoid 47 is erased by a magnetic field whose vector is directed along the magnetic carrier or perpendicular to the plane of the magnetic carrier, with a known direction behind writing information. If the direction of recording is unknown, then erasing (magnetization) is carried out by acting on the magnetic medium with both fields simultaneously.

Depending on the type of recording on the hard magnetic disk that you want to erase, there are three buttons in the control unit of the device — two of them allow you to turn on the channels separately — the on / off button 62 (otherwise this button is called “Start 1”), the on / off button 64 (otherwise it is a button called "Start 3"), and the third on-off button 63 (otherwise it is a button called "Start 2") turns on both channels at the same time, which increases the reliability of erasing the recording and economy.

It should be noted that the capacitors of the storage capacitor unit 8 of the first channel 4 are connected in parallel-series, which makes it possible to create a directly proportional dependence of the required value of the pulsed magnetic field on the voltage across the capacitors of the storage capacitor unit 8 of the first channel 4.

This inclusion of capacitors makes it possible to use capacitors with an operating voltage half that of the voltage taken from the storage capacitor unit 8 of the first channel 4, and to transfer all the energy of the storage capacitor unit 8 of the first channel 4 to the solenoid coil in a shorter period of time, since the quality factor circuit with decreasing capacitance increases and increases the amplitude value of the pulsed magnetic field.

The above operation shows that in the proposed device, on the capacitors of the storage capacitor bank 8 of the first channel 4, voltage stabilization is performed, which allows the solenoids to create a magnetic field with the calculated value of the voltage required for reliable erasure of the magnetic recording.

Reliable erasure of information recording on rigid and flexible magnetic media is achieved in this device by creating equal in value pulsed magnetic fields in solenoids 47 and 71, with the vectors oriented 90 ° relative to each other, and pulsed magnetic fields of a certain value, necessary for reliable erasure of the recorded information on the entire area and volume occupied by a magnetic medium on a hard magnetic disk (HDD), taking into account different values of capacitors in the block of storage capacitors 8 the first channel 4 and in the block of storage capacitors 72 of the second channel 5, the variation in the parameters of capacitors and other electrical radio products, as well as leakage currents. Equality of pulsed magnetic fields is also achieved at different capacitor charge times in the storage capacitor bank 8 of the first channel 4 and capacitors in the storage capacitor bank 72 of the second channel 5. The charge and the degree of charge are controlled by a voltage divider 11, voltage comparator 13, and a charge chopper made on an opto-simulator 7 s simultaneous indication in the process of charging by the LED 22. The value of the stored energy necessary to create a pulsed magnetic field for reliable destruction of information ation on the magnetic medium by (HDD) hard disk, also indicated readiness indicator formed through the LED 30, and via comparator readiness 29 which compares the voltage with a predetermined voltage divider. With a constant change in voltage within the permissible limits on the block of storage capacitors during recharging, the ready indicator, which is an LED 30, does not go out.

In the second channel 5, the same process takes place, but it can differ in charge time from the process in the first channel 4. The charge, recharge, and display circuits bring the voltage of the stored energy to the desired value, creating a pulsed magnetic field with a different vector orientation for reliable information erasure in a magnetic medium on a hard magnetic disk (HDD), recorded, for example, by the method of vertical magnetization.

In addition, in the proposed device, the capacitors of each block of storage capacitors in each channel 4 and 5 are connected in parallel-series, which allows you to remove the voltage from the block of storage capacitors, which is twice as high (compared to turning on the capacitors in the prototype), and therefore, get the necessary value of the pulsed magnetic field to erase information from a magnetic medium with lower energy costs.

Sources of information

1. German patent No. 19736383, CL G 11 B 5/02, published. 1999 year

2. Patent of the Russian Federation No. 2144223, cl. G 11 B 5/024, published. 2000 (prototype).

Claims (5)

1. A device for erasing recordings on a magnetic medium containing two channels, including a constant voltage source, a solenoid, a storage capacitor unit, a switch for connecting a storage capacitor unit to a solenoid, in parallel with which a damping diode is connected, as well as a control unit common to the channels, characterized in that a controlled charge chopper, a voltage comparator, a ready comparator, a voltage divider and a switch trigger unit are introduced into each channel, and the controlled chopper is charged yes it is connected in series to the charge circuit of the storage capacitor unit from a constant voltage source, and the control input of the controlled charge chopper is connected to the output of the voltage divider, which is connected in parallel with the storage capacitor unit, the first input of the availability comparator, the second inputs of the charge comparator and comparator are also connected to the output of the voltage divider the readiness is connected to reference voltage sources, and between the control unit and the switch, the switch start-up unit is included. 2. The device according to claim 1, characterized in that the DC voltage source includes a rectifier, consisting of two series-connected diodes, and increasing the winding of the network transformer, the bipolar outputs of the rectifier diodes being outputs for connecting to the plates of the corresponding capacitors of the storage capacitor unit, one of the leads of the boost winding of the network transformer is a terminal for connecting to the input of the rectifier through a charge chopper, and the other terminal of the winding of the network transformer The ator is an output for connecting to the common connection point of the capacitors of the storage capacitor unit. 3. The device according to p. 1 or 2, characterized in that the controlled charge chopper is made on an opto-simistor and has two inputs, a power and a control, and two corresponding outputs, and the power input is an input for connecting to one of the taps of the boost winding of the network transformer, and the power output is the output for connecting to the common connection point of the rectifier diodes, the control input is the input for connecting to the output of the voltage comparator, and the control output is the output for connecting to the common point of connection the rectifier diode and capacitor plates of the storage capacitor unit with the common bus of the entire device. 4. The device according to claim 1, characterized in that the switch is made on a thyristor and its power electrodes are connected one to the first output of the solenoid, and the second to the common bus of the entire device, and the start-up unit of the switch is made on a solid-state relay, the first and second taps of which are combined and through a resistor are connected to an additionally introduced low-voltage voltage source, and a parallel-connected zener diode and capacitor of the switch trigger unit are connected between the resistor and the common bus of the entire device, the third twater solid state relay connected to the output voltage regulator is further inputted, the fourth tap is connected via a resistor divider to the control electrode of the divider, and the fifth tap is input for connecting to the first output of the control unit. 5. The device according to claim 1, characterized in that the solenoids of both channels are located in such a way that their longitudinal axes are mutually perpendicular, and inside one of the solenoids there is a cavity for accommodating a magnetic carrier.

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