RU2291500C1 - Device for erasing records on a magnetic medium - Google Patents

Abstract

FIELD: instrument engineering; erasing of records on magnetic medium.

SUBSTANCE: device contains constant voltage source with two outputs, actuator with two control inputs and one signal input, unit with reservoir capacitors with two terminals, two commutators with two control inputs, control unit with input and output, controllable charge breaker with control and signal inputs and output, two commutator start units, voltage divisor, charge signal unit with signal outputs and control inputs, pulse forming units with control inputs and one output, pulse signal generator, timer with two signal inputs and one output.

EFFECT: reduced power consumption during record erasing from magnetic mediums without worsening of erasing quality.

9 cl, 12 dwg

Description

The invention relates to techniques for erasing records on magnetic media, in particular hard and flexible disks, magneto-optical disks, magnetic tapes, etc.

It is known that the 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 M _n ⁰ and unit M _n ¹ are oriented parallel to the magnetic field _Hz , which records information (hereinafter is the recording vector), but in opposite directions. Moreover, all magnetic cells are in stable magnetic states. Two types of recording the most common - parallel and perpendicular differing orientation vector H _of the recording medium relative to the plane. Typically, media such as hard disks manufactured before 2000, floppy disks, magnetic tapes are recorded in parallel, and modern hard disks and magneto-optical disks are recorded perpendicularly.

The most common methods of erasing magnetic recordings are demagnetization and magnetization of a magnetic carrier by exposing it to an external magnetic field.

A device for erasing recordings from magnetic media [1], including a control unit and at least first and second circuits, each of which contains a solenoid, capacitor, power source and key. The control input of the key of the second circuit is connected to the output of the control unit. The solenoids are arranged so that the vectors of the magnetic fields created by them in the region of the magnetic carrier are perpendicular. The device contains a sensor of the amplitude-time parameters of the magnetic field generated by the solenoid of the primary circuit. The output of the sensor is connected to the input of the control unit, while the solenoid of the first circuit is set so that the vector of the magnetic field created by it in the area of the magnetic carrier is perpendicular to the direction of the recording vector of the magnetic carrier. The sensor of the amplitude-time parameters of the magnetic field is made on the solenoid in the form of a voltage sensor.

Common features of this device and the claimed invention are: control unit, circuit, solenoid, capacitors, power source, key. The control input is connected to the output of the control unit. The solenoids are arranged so that the vectors of the magnetic fields created by them in the region of the magnetic carrier are mutually perpendicular. To create a magnetic field in the area of the magnetic carrier, polar capacitors were used in the circuits and in the key control of the second circuit of the control unit. Polar capacitors are fully charged to the required voltage value, ensuring the creation of a unipolar pulse. At the time of erasing the recording from the magnetic medium, the energy accumulated at the polar capacitors when the first and then the second key is turned on is not fully used, since the values of the useful energy for erasing information are only in the range of the coercive force of the magnetic medium. Polar capacitors are discharged through the solenoid, partially creating magnetic field pulses with a positive sign, and the rest of the energy is dissipated.

The operation of the known device is based on the method of erasing recordings on a magnetic medium, in which, to act on the magnetic medium, a first circuit with a polar capacitor is switched on, which is discharged through a solenoid and creates a pulse of positive polarity. Then, after a time interval from τ _max to τ, the voltage sensor mounted on the solenoid of the first circuit is activated and turns on the second circuit, the polar capacitor of this circuit through its solenoid creates a second pulse of positive polarity too. The inclusion of the key in the second circuit is carried out through the control unit at the moment the time derivative of the sensor signal passes through zero. The response level of the first and second keys is determined relative to the level of the coercive force of the magnetic medium in the direction of the recording vector N _s . By choosing the number of ampere turns in the first and second solenoids, the required value of the current generating a magnetic field is established, the amplitude value of which in the first circuit exceeds the coercive force, and in the second circuit it is equal to the coercive force of the carrier in the direction of the recording vector _Hz . To create an external magnetic field with a coercive force exceeding the coercive force of the material of the magnetic carrier, it is necessary to expend energy. The energy efficiency in this device is characterized by a coefficient determined by the ratio of the usable used energy of the magnetic part of the electromagnetic wave in the circuit to the spent electrical energy of the storage capacitors obtained from the network during the charge process. Useful magnetic energy is the sum of the magnetic energy obtained from the first and second half-cycles of the oscillation process when creating a pulsed magnetic field during the discharge of capacitors and overcharging EMF capacitors by self-induction of a solenoid, followed by a discharge on the solenoid.

A disadvantage of the known device is the low energy efficiency of erasing due to the fact that only part of the charge energy of the polar capacitors is used to create a pulsed magnetic field in the solenoids. Another large part of the remaining energy in the attenuation mode is dissipated as heat on the circuit elements. The self-induction energy that occurs in the solenoids of the device with the opposite sign is not used at all to create a pulsed magnetic field, to erase information and is also dissipated in the form of heat on the circuit elements. The value of the current generating the magnetic field is determined by the number of ampere-turns. To erase records from various media, rigid, flexible, magneto-optical, etc., which have different diameters and magnetic structures, it is necessary to increase the values of the generated magnetic field, which leads to additional energy losses, and the use of a polar capacitor, power source, two solenoid coils leads to additional energy costs and costs for components and materials, and accordingly, to increase the cost of the device.

Distinctive features of the invention in comparison with the described device [1] are: two switches, a voltage divider, two switch start blocks, a charge signal block, the first and second pulse generation blocks, a timer, a generator. The input of the control unit is connected to the output of the charge signal block, the other two outputs are connected to the first inputs of the pulse forming blocks, the second inputs of which are connected to the generator output connected to the second timer input, the first timer input is connected to the first charge signal block, the second input of which is connected with timer output. The outputs of the first and second pulse shaping units are connected to the inputs of the switch start blocks, respectively, the outputs of which are connected to the control inputs of the switches. The block of storage capacitors by the second input is connected to the cathode of the first switch and the anode of the second switch, the anode and cathode of which are connected to the first and second outputs of the solenoid, the third input of which has a common point with the block of storage capacitors and a voltage divider, and the third input of the second formation block has a common point with the anode of the first switch and the first output of the solenoid.

The loop solenoid is made of three electromagnetic coils with the same number of ampere turns. Two coils are cylindrical, and one is rectangular. The inner diameter of the cylindrical coils is equal to or greater than the diameter of the disk of the magnetic carrier. The rectangular coil of the solenoid is made with a cavity for accommodating a magnetic disk. This coil is installed in the gap between the cylindrical coils. The connection point in the solenoid of cylindrical and rectangular coils is the connection point of the storage capacitor unit.

The solenoid coils are connected in series and connected at the resonant frequencies of the circuit with positive and negative polarity of the voltage occurring on the capacitor due to self-induction in the solenoid.

The block of storage capacitors is made of non-polar capacitors. The solenoid circuit is made of six coils in the form of two sections of three coils. Each of the sections consists of two cylindrical coils with a gap between them, in which a rectangular coil is placed.

It is also known a device for erasing recordings on a magnetic medium [2], containing two main and additional circuits. The circuits consist of a constant voltage source, a solenoid and a capacitor connected alternately to a constant voltage source and a solenoid through a two-position switch. The additional circuit has at least two damper diodes, each of which is connected in parallel with the circuit solenoid. The solenoids of the main and additional circuits are installed with the possibility of orienting the intensity vectors of the generated magnetic fields, rotated relative to each other by an angle α not equal to 180 ° and 360 °, and the moments of connecting the capacitors to the solenoid in the main and additional circuits are shifted relative to each other.

A device consisting of oscillatory circuits, the capacitors of which are connected alternately to power sources through on-off switches and are charged and then discharged, forming damped sinusoidal oscillations. However, connecting the damper diodes in parallel to the polar capacitors ensures the preservation of unipolar pulses during the discharge of the capacitors. The energy of a different polarity, when a capacitor is discharged, is not used in the device and is scattered by the structural elements in the decaying field mode.

The basis of the operation of this device is the method of erasing recordings on magnetic media, in which at least two circuits consisting of a constant voltage source, a solenoid, a polar capacitor and a two-position switch connected alternately to the source and the solenoid create a series of unipolar pulses, discharge of polar capacitors that create magnetic fields in the solenoids, which act on the magnetic carrier until it is saturated.

A disadvantage of the known device is the low energy efficiency of erasing, since the device is characterized by high energy costs. Of all the accumulated energy at the polar capacitors, only part of the energy is used, which ensures the creation of unipolar pulses for erasing information. The self-induction energy arising in the circuits on the solenoids and capacitors in the form of a voltage of negative polarity is not used to create pulsed magnetic fields and is dissipated in the form of heat on the resistances of the damper diodes and other circuit elements. The use of polar capacitors and damping diodes ensures the conservation of only pulses of positive polarity. Additional energy costs are associated with the need to create a magnetic field with an amplitude exceeding the saturation field of the magnetic material of the carrier, as well as to create a series of pulses due to the need to charge and discharge polar capacitors each time, which still leads to additional energy costs. The presence of the second circuit and its compensating radioelements leads to an increase in the cost of the device.

Common features of this device and the invention are: an oscillating circuit consisting of a constant voltage source, a solenoid and a capacitor connected via a key. The solenoids of the circuits are installed with the possibility of orienting the vectors of the generated magnetic fields rotated relative to each other, and the moments of connecting the capacitors to the solenoid are shifted relative to each other.

Distinctive features of the invention are: a voltage divider, two switch triggering blocks, a charge signal block, the first and second pulse shaping blocks, a timer, a generator. The control input of the controlled charge chopper is connected to the output of the control unit, the input of which is connected to the output of the charge signal block, the other two outputs of which are connected to the first inputs of the signal conditioning blocks, the second inputs of which are connected to the second inputs of the timer, the first timer input is connected to the first input of the signal block charge, the second input of which is connected to the output of the timer. The outputs of the first and second pulse shaping units are connected to the inputs of the switch start blocks, the inputs of which are connected to the control inputs of the switches. The block of storage capacitors is connected by an input to the cathode of the first switch and the anode of the second switch, the anode and cathode of which are connected to the first and second outputs of the solenoid, the third input of which has a common point with the block of storage capacitors and a voltage divider. The third input of the pulse forming unit has a common point with the anode of the first switch and the first output of the solenoid. The solenoid consists of three coils connected in series. Solenoid coils are connected at the resonant frequencies of the circuit. The connection occurs with a positive and negative polarity of the voltage occurring on the capacitor due to self-induction in the solenoid, when the voltage values on non-polar capacitors are modulo maximum, but opposite in sign. This ensures the creation in different coils of a single solenoid of pulsed magnetic fields whose vectors can be oriented in any direction depending on the location of the coils in the solenoid. In addition, the applicant considers it necessary to further develop and / or clarify the totality of the common essential features of the device related to particular cases of its implementation or use.

The loop solenoid is made of six coils, for example, with the same number of ampere turns, four coils of them are cylindrical of small height. Each pair of coils is located on the same axis with a gap between them. The inner diameter of these coils is equal to or greater than the diameter of the disk of the magnetic carrier, and the other two coils of the solenoid are made rectangular with cavities in them to accommodate the magnetic disk. These coils are mounted in the clearance of cylindrical coils. The connection point in the solenoid of cylindrical and rectangular coils is the connection point of the storage capacitor unit. The block of storage capacitors is made of non-polar capacitors.

The loop solenoid has six coils, structurally made in the form of two sections. Each section consists of two cylindrical coils with gaps between them to accommodate rectangular coils.

Closest to the claimed device according to the technical nature and technical result is a device for erasing recordings on a magnetic medium - a prototype [3]. The prototype contains two channels, including 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. A controlled charge chopper, a voltage comparator, a ready comparator, a voltage divider, and a switch trigger unit are introduced into each channel. A controlled charge chopper is connected in series to the charge circuit of the storage capacitor block from a constant voltage source. 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. The output of the standby comparator is also connected to the output of the voltage divider, the second inputs of the charge comparator and the standby comparator are connected to voltage reference sources. Between the control unit and the switch, the switch start unit is included. The solenoids of both channels are arranged in such a way that their longitudinal axes are mutually perpendicular, and there is a cavity inside one of the solenoids to accommodate the magnetic carrier.

A disadvantage of the known device is the low energy efficiency due to the incomplete use of storage energy on capacitors and the need to create a magnetic field in each solenoid of a two-channel device with an amplitude exceeding the magnetic field of saturation of the magnetic material of the carrier and maintaining a constant charge level in the block of storage polar capacitors. Additionally, a two-channel device determines the need to have two blocks of storage polar capacitors, which leads to an increase in the cost of the device.

A common drawback of the devices described above is the low energy efficiency of erasing records from magnetic media due to the incomplete use of the energy stored on the capacitors, and due to the need to create a magnetic field with an amplitude exceeding the saturation field of the magnetic material of the carrier, which is created by two unipolar magnetic pulses. The main part of the energy is spent on the charge of polar capacitors, the constant maintenance of a charge level on them, the value of which decreases due to leakage currents. On polar capacitors at the time of erasing the recording from magnetic carriers, only a part of the accumulated energy is discharged, and the rest of the residual energy of the order of 30% in the decaying field mode is dissipated in the form of heat on the resistances of the damper diodes and other circuit elements.

The results of experimental studies have confirmed that the residual voltage after the discharge of polar capacitors is at least 80 V (24% of the nominal value) on the storage capacitor bank.

Common with the claimed invention are the following features: a constant voltage source, a solenoid, a storage capacitor unit, two switches for connecting a storage capacitor unit to a solenoid, a control unit, a controlled charge chopper, a voltage divider, and two switch startup units. A controlled charge chopper is connected in series to the charge circuit of the storage capacitor block from a constant voltage source. The channel solenoids are arranged in such a way that their longitudinal axis is perpendicular. Inside one of the solenoids there is a cavity for accommodating a magnetic carrier.

Distinctive features of the invention in comparison with the prototype are: a charge signal block, the first and second pulse shaping blocks, a timer, a generator. The control input of the controlled charge chopper is connected to the output of the control unit, the input of which is connected to the output of the charge signal block. The other two outputs of which are connected to the first inputs of the pulse forming units, the second inputs of which are connected to the output of the generator connected to the second input of the timer. The first timer input is connected to the first input of the charge signal block, the second input of which is connected to the timer output. The outputs of the first and second pulse shaping units are connected to the inputs of the switch trigger units, the outputs of which are connected to the control inputs of the switches. The storage capacitor unit with its second input is connected to the cathode of the first switch and the anode of the second switch, the anode and cathode of which are connected to the first and second outputs of the solenoid, the third input of which has a common point with the storage capacitor unit and voltage divider, and the third input of the second pulse generating unit has a common point with the anode and the first output of the solenoid. The solenoid consists of three coils connected in series.

The applicant considers it necessary to highlight the following development and / or refinement of the totality of the common essential features related to particular cases of performance or use. The contour solenoid is made in the form of two sections of six coils, four of which are cylindrical of small height, and two rectangular. Each pair of cylindrical coils has an inner diameter equal to or greater than the diameter of the disk of the magnetic carrier, and the two sides of the rectangular coils of the solenoid are equal to the diameter of the magnetic disk. The connection point in the solenoid of cylindrical and rectangular coils is the connection point of the storage capacitor unit. The block of storage capacitors is made of non-polar capacitors.

The basis of the operation of this device is the method of erasing recordings on magnetic media, in which unipolar pulses of perpendicular magnetic fields are created in each of the two channels simultaneously shifted in time, which act on the magnetic medium until it is saturated. With constant current leakage currents occurring in any electrical circuits, to maintain a constant charge level in the block of storage polar capacitors, a controlled charge chopper, voltage comparator, ready switch, voltage divider are introduced into each channel. These devices, when the voltage across the polar capacitors is reduced, connect the power source and charge the polar capacitors to the set level.

The problem solved by the proposed device is to increase the energy efficiency of erasing records from magnetic media without compromising the quality of erasing records on a magnetic medium by magnetizing the magnetic medium with a magnetic field. Magnetic fields are created by current pulses arising in the coils of the solenoids when they are sequentially connected to the storage capacitor. At this moment, charge and recharge by self-induction of the non-polar capacitor solenoid are carried out to the maximum voltage value in the circuit. This is explained by the fact that when the current strength in the solenoid changes, the magnetic flux generated by this current changes. A change in the magnetic flux penetrating the solenoid causes an induction EMF in the electric circuit of the circuit; as a result of a change in the current strength, the self-induction EMF appears in this circuit. The self-induction EMF that occurs in the solenoid when the circuit is closed or opened for a certain time, maintains the current in the circuit. The self-induction EMF is many times higher than the EMF formed by the storage capacitor [4].

The extract is recharging the storage capacitor modulo to a charge voltage value or more, but with the opposite sign. The discharge of the residual voltage and the voltage of the storage capacitor charged by the extracurrent in the solenoid creates a second pulsed magnetic field, the value of which and its amplitude is equal to the value of the coercive force of the material of the magnetic carrier in a direction parallel to the direction of the recording vector.

The technical result of the invention is to reduce energy costs, a more complete use of the energy stored on the capacitor and when it is recharged with the self-induction energy generated by the EMF in the solenoid. An additional reduction in energy costs is achieved by the fact that in one of the coils the vector of the pulsed magnetic field is oriented parallel to the recording vector, and its amplitude is set equal to the value of the coercive force of the material of the magnetic carrier. At the same energy costs, the constructive implementation of the solenoid in the proposed device in the form of two sections ensures the destruction of information on two magnetic media at the same time.

The technical result of the invention is achieved in that it contains: a constant voltage source, a solenoid, a storage capacitor unit, two switches for connecting a storage capacitor unit to a solenoid, a control unit, a controlled charge chopper, a voltage divider, two switch start sides. A controlled charge chopper is connected in series to the charge circuit of the storage capacitor block from a constant voltage source, and the channel solenoids are arranged so that their longitudinal axes are perpendicular. Inside one of the solenoids there is a cavity for accommodating a magnetic carrier. A charge signal block, a first and second pulse forming blocks, a timer, a generator are additionally introduced into the device. The control input of the controlled charge chopper is connected to the output of the control unit, the input of which is connected to the output of the charge signal block, the other two outputs of which are connected to the first inputs of the pulse forming units, the second inputs of which are connected to the generator output connected to the second timer input. The first timer input is connected to the first input of the charge signal block, the second input of which is connected to the timer output, and the outputs of the first and second pulse shaping units are connected to the inputs of the switch start blocks, the outputs of which are connected to the control inputs of the switches. The block of storage capacitors with its second input is connected to the cathode of the first switch and the anode of the second switch, the anode and cathode of which are connected to the first and second outputs of the solenoid, the input of which has a common point with the block of storage capacitors and a voltage divider. The third input of the second pulse forming unit has a common point with the anode of the first switch and the first output of the solenoid. The solenoid consists of three coils connected in series.

In a particular embodiment, the charge signal block comprises a conversion device, a level recording device, a time interval meter, a charge signal conditioner, and an output signal conditioner. The conversion device, the level recording device, the time interval meter and the charge signal generator are connected in series, and the output of the charge signal generator is connected to the second input of the level registration device, the second output of which is connected to the input of the output signal generator.

In a particular embodiment, the first pulse generating unit comprises a signal recording device, a generating device, and a signal generating device. The first inputs of the signal recording device and the shaping device are interconnected respectively, and their outputs are connected to the signal issuing device, the output of the first pulse shaping unit is the input-output of the shaping device and the signal issuing device, and the inputs are the common points of the first and second signal recording inputs and forming devices.

In a particular embodiment, the second pulse generating unit comprises a level former, a comparison device, a conversion device, a signal recording device, a forming device, and a signal issuing device. The level shaper, the comparison device, the conversion device are interconnected in series. The output of the conversion device is connected to the third input of the signal recording device, the first and second inputs of the signal registration device and the shaping device are interconnected, and their outputs are connected to the signal issuing device, the output of the second pulse shaping unit is the input-output of the shaping device and the signal issuing device. Their inputs are the common points of the first and second inputs of the signal recording device and the shaping device, as well as the input of the level former and the connection point of the threshold voltage of the comparison device.

In a particular embodiment, the solenoid is made in the form of two sections of six coils, of which four coils are cylindrical of small height and two are rectangular. Each section consists of two cylindrical coils and one rectangular. Cylindrical coils are installed with a gap between them, in which a rectangular coil is placed.

The cylindrical coils have an inner diameter equal to or greater than the diameter of the disk of the magnetic carrier, and the two sides of the rectangular coils of the solenoid are equal to the diameter of the magnetic disk.

In a private embodiment, all six solenoid coils are interconnected sequentially and sectionally, one consists of two cylindrical coils of the first section and one rectangular second section. The other section consists of two cylindrical coils of the second section and one rectangular - the first section.

The connection point in the solenoid of cylindrical and rectangular coils is the connection point of the storage capacitor unit. The block of storage capacitors is made of non-polar capacitors.

The solenoid circuit of six coils is structurally made in the form of two sections. In one section, during the first half-period of voltage, a field is formed perpendicular to the plane of the magnetic carrier, and in the second section, parallel to its plane. In another section, during the second voltage half-cycle, a field is formed perpendicular to the plane of the magnetic carrier, and in the first section, parallel to its plane.

The invention is illustrated by drawings.

1 illustrates orientation erasing magnetic field perpendicular (H _trans) and parallel (N _pairs) relative to the vector H _of recording information on magnetic media, as well as the orientation of the magnetization vectors corresponding to zero M _n M ⁰ and unit ¹ for the case _{of n} parallel records.

Figure 2 shows part of a block diagram of the inventive device.

Figure 3 shows the second part of the block diagram of the inventive device.

Figure 4 shows the time sequence for the inclusion of the first and second pulses of the erasing magnetic fields.

Figure 5 shows a block diagram of the implementation of the block of charge signals.

Figure 6 shows a block diagram of a first pulse forming unit for activating a cylindrical coil.

7 shows a block diagram of a second pulse forming unit for activating a rectangular coil.

On Fig shows the location and form of the coils in one section of the solenoid, consisting of three coils.

Figure 9 shows a circuit diagram of the solenoid, consisting of two sections and six coils.

Figure 10 shows an electrical diagram of the implementation of the signal charge unit.

11 shows an electrical diagram of an implementation of a pulse forming unit for activating a cylindrical coil.

On Fig shows an electrical diagram of the implementation of the pulse forming unit to turn on the rectangular coil.

A device for erasing recordings on a magnetic medium (Fig.2, 3) contains a constant voltage source (IPN) 1 with two outputs, a solenoid (C) 2 with two control inputs 40, 41 and one signal 42, a block of storage capacitors (BNC) 3 with two terminals, the first 4 and second 5 switches with control inputs 37 and 38, respectively, with anodes and cathodes, control unit (CU) 6 with input 18 and output 17, controlled charge chopper 7 with control input 16 and signal input-output 25 , the first 8 and second 9 switch starting blocks (BPC) with outputs 35 and 3 6 and inputs 33 and 34, respectively, a voltage divider 10 with input and output, a charge signal block (BSZ) 11 with three signal outputs 19, 20 and 21 and two control inputs 28 and 29, the first pulse forming block (BFI) 12 with two control inputs 23 and 25 and with one output 31, a second BFI 13 with three control inputs 22, 24 and 43 and output 32, a pulse signal generator 15 with one output, a timer 14 with two signal inputs 26, 27 and one output 30.

Solenoid 2 can have two options.

In the first embodiment, the solenoid 2 (Fig. 8) is made of three electromagnetic coils 44, 45 and 46. The coil 44 is made in the form of a parallelepiped with a height much smaller than two other sizes and with an internal cavity for accommodating the magnetic carrier 47 (Fig. 1). Coils 45 and 46 are cylindrical with a height much smaller than the diameters and are placed coaxially at a distance from each other equal to or greater than the thickness of the coil 44.

In the second embodiment (Fig. 9) of the solenoid 2, it is made in the form of two sections. One section consists of: a rectangular coil 44 and two cylindrical coils 45 and 46. The second section of the solenoid 2 consists of similar coils 48, 49 and 50. A magnetic carrier 47 is located in the cavity of the coil 44, and a second magnetic carrier 51 is located in the cavity of the coil 48, moreover, all coils of the solenoid 2 are connected in series. Cylindrical coils 45, 46, 49 and 59 are placed coaxially, the axis of which is perpendicular to the axes of the coaxial coils 44 and 48. The axes of all coils lie in the same plane.

The first output of the DC voltage source 1 (FIG. 2) is connected to the signal input of a controlled charge chopper (USP) 7, the output of which is connected to the input of the voltage divider (BDN) 10, and its output is connected to the common terminal of the coils 44 and 45, and one terminal block 3 storage capacitors (NK). The control input of the USP 7 is connected to the output of the control unit (BU) 6. The second output of the IPN 1 is connected to the anode of the first switch (PC) 4, to the cathode of the second switch (VK) 5 and the second terminal of BNK 3. The cathode of PC 4 is connected to terminal 40 of the coil 46, which is connected in series with coil 45. The anode of VK 5 is connected to terminal 41 of coil 44, the second terminal of which is connected to second terminal of coil 45 and terminal 42 of BNK 3. Control input 37 of PC 4 is connected to output 35 of the first switch start-up block (BPC) (figure 3), and the control input 38 of the PC 5 is connected to the output 36 of the second block of the run as a switch (BPC) 9, the input 18 of the BU 6 is connected to the output 19 of the charge signal block (BSZ) 11, and the terminal 40 of the coil 46 is connected to the input 43 of the pulse forming unit (BFI) 13, the output of which 32 is connected to the input 34 of the BPC 9, and the input 22 of the BFI 13 is connected to the output 20 of the BSZ 11, the output 21 of which is connected to the input 23 of the first 12 pulse forming unit (BFI), and the output 31 of the first BFI 12 is connected to the input 33 of the BPC 8. Terminal 27 is connected to the input of the timer 14 (T ) and the input 28 BSZ 11, and the output 30 T 14 is connected to the input 29 BSZ 11. The input 26 T 14 is connected to the output of the generator (G) 15, input 25 BFI 12 and input 24 of the second B And 13.

The device (Fig. 2 and 3) works as follows. In the magnetic carrier (1), with any orientation and direction of the vector H _of the recording action of the first magnetic field pulse H _lane, which is supplied during the positive half-cycle values of the first sine wave voltage fluctuations formed in the circuit. The amplitude of H _per exceeds the coercive force of N _{s, pairs} (N _{s, per} ) of the magnetic medium in the recording direction. This field momentum transfers all magnetic cells to an unstable state with almost identical directions of the magnetization vectors along the direction of the applied field H _per . Then, a second pulse of the opposite sign of the magnetic field H _pairs , which is formed by the self-induction of the solenoid, automatically acts on the magnetic carrier 47. The vector of this pulse can be oriented in any direction, but perpendicular to the vector of the previously applied field H _per . The on time of the second pulse is determined by the parameters of the circuit formed by the solenoid 2 and the block of storage capacitors 3. The device for erasing records on a magnetic medium is in one of three mutually exclusive states. When turned on, it automatically switches from one state to another and third. The first, initial state (FIGS. 2 and 3) is the state of charge of the block of storage capacitors 3. In this state, the controlled charge chopper 7 is closed, and the switches 4 and 5 of the circuit are closed. The current through the coils 46, 45 and 44 of the solenoid 2 does not flow, at this moment the capacitors charge. The activation of the coils 46 and 45 of the solenoid 2 occurs at a time determined by the positive half-wave circuit (figa). At this time, the device transitions from the charge state of the storage capacitor unit 3 when a start signal is applied to terminal 27, the first input of the timer 14 and the first input 28 of the charge signal unit 11 (Fig. 46), from which the generated signal from the first output 19 enters the input 18 of the control unit 6, in which the control signal is generated, and from the output 17 it is fed to the input 16 to the controlled charge chopper 7. The signal “charge” at the moment of opening of the contacts of the controlled charge chopper 7 becomes equal to “zero” in voltage (Fig. 4c), and at this moment nt from the third output 21, the charge signal 11 to the first input 23 of the pulse forming unit 12, for switching on the start block of the switch 8 and supplying a control signal from the output 35 to the control input 37 of the switch 4, is supplied (Fig. 4d) to activate the cylindrical coils 46 and 46 solenoid 2. As a result, at the moment of opening the contacts of the controlled charge chopper 7, the control pulse is supplied to the control input 37 of the switch 4 (for example, the thyristor control electrode), which opens. The discharge of the block of storage capacitors 3 begins through the field-forming coils 46 and 45 of the solenoid 2 during the action of the positive half-wave formed by the circuit (Fig. 4a). At this time, the “charge” signal is “zero” (Fig. 4c). As the current strength in the circuit of the coils 45 and 46 increases, the voltage at the block of storage capacitors 3 decreases (Fig. 4a). As a result, in the formed circuit, consisting of a block of storage capacitors 3 and coils 46 and 45 of the solenoid 2, a process occurs that can be described as a pulsed damped oscillation formed from a positive half-wave of alternating voltage (Fig. 4a). This pulse activates in the coils 46 and 45 of the solenoid magnetic field pulse 2 H _{lane-oriented,} for example, the vector perpendicular recording H _s (1) on the magnetic recording medium 47. However, this process is automatically completed after a first half-wave period of the oscillation circuit when the current through the coils 46 and 45 of the solenoid 2 and, accordingly, when the current through the switch 4 becomes close to "zero". Switch 4 closes and opens the loop circuit. At the moment of reaching the maximum current strength, the resulting EMF of the solenoid 2 due to self-induction changes the sign of the voltage. The block of storage capacitors 3 will be recharged, and the voltage on it will change sign and increase modulo (Fig. 4a) due to self-induction. The activation of the coil 44 of the solenoid 2 occurs at a time determined by the negative half-wave voltage on the circuit. The transition to this state is carried out automatically after the end of the previous phase. The switching moment is fixed by analyzing the voltage at switch 4. When the switch 4 is closed, the voltage on it changes sharply from almost zero to the value of the self-induction voltage of the solenoid on the block of storage capacitors 3, which generates a control signal (Fig. 4e) coming from terminal 40 43, the input of the second block of pulse formation 13, the inclusion of a rectangular coil 44 of the solenoid 2. The input 22 and input 24 of the second block of pulse formation 13 receive signals from the signal block of the charge 11, and the generator 15 respectively generates a pulse for supplying from the output 32 to the input 34 of the starting block of the switch 9 and then to the control input 38 of the switch 5. Switch 5 (Fig. 4f) and the discharge of the self-induction energy accumulated on the block of storage capacitors 3 through the coils 44 of the solenoid 2 begins.

The process continues until the current value through the coil 44 and, accordingly, through the switch 5 becomes close to "zero". After that, the switch 5 is closed and the third phase of the device is completed. Note that the process of the block of storage capacitors 3 through the coil 44 can also be characterized as a pulsed damped oscillation formed from a negative half-wave of an alternating voltage of self-induction (figa, e). This impulse in the coil 44 of the solenoid 2 activates the pulse magnetic field H oriented _pairs, e.g., parallel to the vector H _of the magnetic recording medium, but in the opposite direction (Figure 1).

The transition to the initial (first) state is carried out by applying the active signal "charge" (Fig.4c) to the controlled charge chopper 7 from the charge unit 11 through the control unit 6. The total time of the active automatic cycle of erasing records from magnetic media is determined by the duration of the time interval, in during which the signal "charge" has an inactive value.

The claimed device can be performed as described below.

The block of the charge signal (BSZ) 11 can be performed according to the scheme of figure 5 which contains: a device for converting an analog signal to digital 52 with input and output, a device for recording the signal level 53 with two signal inputs and two signal outputs, a time interval meter 54 with two signal inputs, the second of which has a terminal 29, and one output, a charge shaper 55 with an input and an output, an output signal shaper 56 with one input and three outputs 19, 20, and 21.

The conversion device (UP) 52 (Fig. 5) with the input 28 of the BSZ 11 is connected by its output to the first input of the level recording device (URU) 53, the output of the charge signal shaper (FSZ) 55 is connected to its second input, and the output of the FSZ 55 is connected to the output of the time interval meter (IVI) 54, the first input of which is connected to the first output of the URU 53, and the second input to the terminal 29, and the second output of the URU 53 is connected to the input of the output signal shaper (FVS) 56, the outputs of which are first, second and third respectively connected to terminals 19, 20 and 21.

The charge signal block 11 (Fig. 5) is intended for timing and signaling to the control unit 6, for the transition of the controlled charge 7 from the state of charge and signaling to the first and second pulse generation blocks 12 and 13.

At the input 28 of the signal block of the charge 11 (Fig. 10), which is, for example, the input (UP) of two flip-flops 57, at the same time the timer 14 receives a signal at the input 29 (IVI), which is, for example, the input of a four-bit binary counter 58. He counts the time from the supply of signals from the output of the inverter 62 (figure 10). This is the moment of opening the contacts of the charge interrupter 7 and the transition of the block of storage capacitors 3 from the state of charge, i.e. the beginning of the time of the active cycle of the supply of pulses from the inverter 62 of the output 21 (Fig.4 c, d). The time interval meter 54, made on several four-digit binary reversible counters 58-60, counts until the decaying process after the positive half-wave of oscillations on the circuit expires automatically, i.e. the current through the coils 45 and 46 and switch 4 will become close to zero and switch 4 will close. He will open the circuit circuit, as was said earlier, and at the moment of the second half-wave of the oscillation period of the circuit (voltage value with the opposite sign), a signal is sent from the counter to inverter 61, and then to trigger 57. Trigger 57 gives a pulse to the microcircuit (inverter) 62 representing six logical elements. From its output 20, the signal enters the input 22 of the second pulse forming unit 13 to activate the coil 44 of the solenoid 2.

The first pulse shaping unit (BFI) 12 can be performed according to the scheme of FIG. 6 which comprises: a signal recording device 63 with two control inputs 25 and 23 and with one output and one input - output 31, a signal generating device 65 with two signal inputs and one input - output 31.

Terminal 25 of the first BFI 12 (FIG. 6) is connected to the first inputs of the signal recording device (URS) 63 and the forming device (UV) 64, and its terminal 23 is connected to the second inputs of the URS 63 and UV 64. The output of the URS 63 is connected to the first input signal output device (UVS) 65, the second input of which is connected to the output of UV 64, and the input is the output of UV 64 and UVS 65 is connected to terminal 31.

The first pulse shaping unit (BFI) 12 (Fig.6) works as follows: signals from the generator 15 (Fig.2, 3) are fed to input 25 of the signal recording device 63 and to input 23 signals from the signal block of the charge 11, after registration with of the device 63, the signals are fed to the first input of the signal issuing device 65, to the second input of which the generated pulses are received by the generating device 64 and lasting for one period of the signal of the generator 15, the signal issuing device 65 at the input 31 generates a single pulse, which is fed to the input 33 of the block start switch 8.

The second BFI 13 can be performed according to the scheme of Fig. 7, which contains: a signal level former 69 with an input 43 and one output, a comparison device 70 with an input, output, and a threshold voltage connection terminal, a conversion device 71 with input and output, a signal recording device 72 with three inputs, the first signal, the second 22 and the third 24 control with one output, the forming device 73 has inputs 22 and 24, one output and one input - output 32, the signal output device 74 with two signal inputs and one input - output 32.

Terminal 43 of the second BFI 13 (Fig. 7) is connected to the input of the level former (ФУ) 69, the output of which is connected to the input of the comparator 70, to which the terminal (- Uп) for connecting the threshold voltage is connected, and its output is connected to the input conversion device (UP) 71, the output of UP 71 is connected to the first input of the signal recording device (URS) 72. Terminal 22 is connected to the second input of URS 72 and the first input of the forming device (UV) 73, and terminal 22 is connected to the third input of URS 72 and the second input of UV 73, and terminal 24 is connected to the third input of URS 72 and the second input of UV 73. The output of URS 72 is connected to the first input of the signal issuing device (UVS) 74, the second input of which is connected to the output of UV 73, and the input - output of UV 73 and UVS 74 are connected to terminal 32.

The second block forming pulses 13 (Fig.7) works as follows. The voltage from the output of the switch 4 is supplied to the input 43 of the pulse forming unit 13 (Fig. 7), which is the input of the level driver 69, intended to limit the voltage to the voltage value acceptable for the operation of the comparison device 70, to the input of which the signal from the driver 69 The comparison device 70 compares the voltage of the input signal with a negative voltage, the threshold - Uп. At the output of the comparison device 70, a positive difference is formed, which, passing through the conversion device 71, is recorded and matched with digital logic. The signals from the conversion device 71 and the generator 15 (Fig. 3) from the input 24 are sent to the signal recording device 72 and the forming device 73. The circuit generates a single pulse with a duration of one signal period of the generator 15. This pulse from the signal issuing device 74 from the output 32 is used as a manager for supplying to the start-up unit of the switch 9 (Fig. 2) and then to the input 38 of the switch 5 to activate the coil 44 of the solenoid 2 (Fig. 4e). After the formation of this pulse, the circuit is blocked until the circuit is reset to zero by the “charge” signal supplied to the input terminal 22 of the forming device 73 from the charge signal block 11 (Fig. 12).

The electrical circuit of the charge signal block (BSZ) 11 is shown in Fig. 10, can be implemented on well-known serial microcircuits, for example, two-digit binary reversible counters IE7 are connected to two triggers of the TM2 type (series 133, 134, K155, K531, KM555, etc.) , for example, 113, K155, KM155, etc., at the output of which inverters are installed, for example, of type LN1, six logic elements (series 133, K155, KM155, 531, K531, KM555) [5]. The control unit 6 and the controlled charge chopper 7 are carried out in any known manner, for example, in the form of electronic controlled switches, relays, for example, type KP293 polarized relay, which are switched by the signal received from the output 19 of the charge signal block 11. The start blocks of the switches 8 and 9 are made on solid state relay, for example, type КР293КП11АП, outputs 35 and 36 of which are connected respectively to the control electrode 37 and 38 of the corresponding switches 4 and 5, and outputs of the solid state relay КР293КП11АП 33 and 34 are connected to outputs 31 and 3 2 corresponding pulse forming units 12 and 13.

The first pulse shaping unit 12 (Fig. 6) can be implemented (Fig. 11), for example, using two triggers 66, 67 of type TM 2 and element 68 "I", for example, type K155LI, manufactured by the industry. An example implementation of the circuit shown in Fig.11. The circuit generates a single pulse, the duration of the signal of the generator 15, which is fed to the input of the start block of the switch 8 for connecting the coils 45 and 46 of the solenoid 2 (FIGS. 2 and 3), during a positive value of the first half-cycle of the voltage generated by the oscillations on the circuit, and when the sectional execution of the solenoid 2 coils 45, 46 and 48 (Fig.9).

The second pulse shaping unit 13 (Fig. 7), like the previous circuit, is implemented using devices manufactured by the industry. An example implementation of the circuit shown in Fig.12. For example, the limiter 75 is made on resistors C2-33, the comparator 76 - on a type 554CA2 chip. The switches 4 and 5 (figure 2) are made on thyristors, for example, type 2T143-500-16. Block storage capacitors 3 is made in the form of a set of non-polar capacitors connected in parallel, for example, type K50-15; K50-6.

Thus, the claimed technical solution allows to increase the energy efficiency of erasing records from magnetic media by using the energy of self-induction in the circuit. When the current strength in the solenoids changes, the magnetic flux generated by this current changes. A change in the magnetic flux penetrating the circuit causes an induction emf in the electric circuit. As a result of a change in the current strength in this circuit, the self-induction EMF appears. The self-induction EMF arising in the solenoid during circuit closing or opening maintains current [6]. This current, when the circuit is opened, the extra charge recharges the storage capacitor of the circuit to a charge voltage value or more, but with the opposite sign. The discharge of the storage capacitor charged by the extracurrent in the solenoid creates a secondary pulsed magnetic field to erase the recording on a magnetic medium without increasing the power consumption from the power source.

The value of the extracurrent in the circuit modulo many times greater than the current generated by the power source. The self-induction EMF is also many times higher than the EMF formed by the power source or the storage capacitor circuit. This ensures, without compromising the quality of recording erasure, the creation of a pulsed magnetic field with a magnetic field strength equal to the coercive force of the magnetic material of the carrier in a direction perpendicular or parallel to the direction of the recording vector.

In addition, the use of self-induction energy in the circuit, provided that the solenoid is in the form of a section, as described in the description, at the same energy costs allows you to erase records from two magnetic carriers.

Information sources

1. Certificate of the Russian Federation No. 24746, G 11 B 5/024, 2002

2. RF patent No. 2144223, G 11 B 5/024, 2002

3. RF patent No. 2232435, G 11 B 5/024, 2002

4. Mustafaev R.A., Krivtsov V.G. Physics, ed. Higher School, Moscow, 1989, pp. 150-253.

5. Design of electronic equipment on integrated circuits. "Analog and Digital Integrated Circuits", reference manual, second edition, edited by S.V. Yakubovsky, ed. Radio and Communications, Moscow, 1985, pp. 77-82.

6. Kabardin O.F. Physics, ed. "Enlightenment", Moscow, 1991, pp. 190-192.

Claims (9)

1. A device for erasing recordings on a magnetic medium containing a constant voltage source, a solenoid, a storage capacitor unit, a control unit, two switches for connecting a storage capacitor unit to a control unit solenoid, a controlled charge chopper, a voltage divider, a switch trigger unit, and a controlled chopper charge is connected in series to the charge circuit of the block of storage capacitors from a constant voltage source, and the solenoid coils are located in such a way that the longitudinal axes are mutually perpendicular, and inside one of the coils of the solenoids there is a cavity for placing a magnetic carrier, characterized in that a charge signal block, a second switch trigger block, a first and second pulse shaping block, a timer, a pulse signal generator, and a controlled input are introduced into it a controlled charge chopper is connected to the output of the control unit, the input of which is connected to the output of the charge signal unit, the other two outputs of which are connected to the first inputs of the pulse forming units, second whose inputs are connected to the output of the pulse generator and to the second timer input, the first timer input is connected to the first input of the charge signal block, the second input of which is connected to the timer output, and the outputs of the first and second pulse generation blocks are connected to the inputs of the switch trigger blocks, the outputs which are connected to the control inputs of the switches, and the block of storage capacitors by its second input is connected to the cathode of the first switch and the anode of the second switch, the anode and cathode of which are connected are connected with the first and second outputs of the solenoid, the input of which has a common point with the block of storage capacitors and a voltage divider, and the third input of the second pulse forming unit has a common point with the anode of the first switch and the first output of the solenoid, which consists of three electromagnetic coils connected in series. 2. The device according to claim 1, characterized in that the charge signal unit comprises a device for converting an analog signal to digital, a level recording device, a time interval meter, a charge signal generator, an output signal generator, the device for converting an analog signal to digital, a level recording device , the time interval meter and the charge signal generator are connected in series, and the output of the charge signal generator is connected to the second input of the level recording device The second output of which is connected to the input of the output signals. 3. The device according to claim 1, characterized in that the first pulse generating unit comprises a signal recording device, a generating device, a signal issuing device, wherein the first and second inputs of the signal recording device and the generating device are interconnected, respectively, and their outputs are connected to the device signal output, the output of the first pulse shaping unit is the input-output of the shaping device and the signal issuing device, and the inputs are the common points of the first and second inputs of the register device uu signals and forming apparatus. 4. The device according to claim 1, characterized in that the second pulse generating unit comprises a level shaper, a comparison device, an analog to digital signal conversion device, a signal recording device, a formation device, a signal output device, the level shaper, a comparison device, a conversion device the analog signal in digital are interconnected in series, and the output of the conversion device is connected to the signal registration device, the first and second inputs of the device are reg the signal traction and the shaping device are interconnected respectively, and their outputs are connected to the signal issuing device, the output of the second pulse shaping unit is the input-output of the shaping device and the signal issuing device, and the inputs are the common points of the first and second inputs of the signal recording device and the shaping device , as well as the input of the level shaper and the connection point of the voltage threshold of the comparison device. 5. The device according to claim 1, characterized in that the cylindrical electromagnetic coils have an internal cavity whose diameter is equal to or greater than the diameter of the disk of the magnetic carrier, and the two inner sides of the rectangular coils of the solenoid are equal to the diameter of the magnetic disk. 6. The device according to claim 1, characterized in that all the electromagnetic coils of the solenoid are connected in series and in sections, one section consists of two cylindrical coils of the first section and one rectangular second section, the other consists of two cylindrical coils of the second section and one rectangular first section. 7. The device according to claim 5, characterized in that all the electromagnetic coils are interconnected sequentially and in sections, one section consists of two cylindrical coils of the first section and one rectangular second section, the other section consists of two cylindrical coils of the second section and one rectangular first section. 8. The device according to claim 5, characterized in that the connection point in the solenoid of cylindrical coils and rectangular electromagnetic coils is the connection point of the storage capacitor unit. 9. The device according to claim 8, characterized in that the block of storage capacitors is made of non-polar capacitors.

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