SU1007137A1 - Method and apparatus for demagnetizing ferromagnetic bodies - Google Patents

Abstract

1. The method of demagnetizing ferromagnetic tep by acting on them by magnetic field pulses with alternating polarity and with decreasing amplitude to zero, differs Ayush and with the fact that, with an improvement in the quality and performance of demagnetization, the duration of each demagnetizing field pulse is equal to the change time magnetic flux body.

Description

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2. The method according to claim 1, wherein the amplitude of the strength of the demagnetizing field is reduced so that the decrease in the magnetic flux of the body does not exceed the specified value, and each decrease in the amplitude of the intensity does not exceed its magnitude decrease in the previous pulse.

3. A device for demagnetizing ferromagnetic bodies containing a series-connected direct current source, a current controller, a polarity switch and a demagnetizing winding, characterized in that, in order to achieve quality and demagnetization performance, it has a neutral winding body that has a demagnetized body, a nude, demagnetized body, and body

Isofelling relates to instrument making and can be used to demagnetize various ferromagnetic parts, as well as samples of ferromagnetic materials, before measuring the magnetic characteristics.

There is a known method of demagnetization of ferromagnetic bodies, which consists in reversing their magnetic field with alternating polarity and killing amplitude ij to zero to zero.

In the known technical solution, the frequency of polarity change of demagnetized field and the duration of the demagnetization process are selected before demagnetization. The frequency is selected from the condition of providing a complete mass of the body to be demagnetized, or, if a constant frequency is used, for example 5O Hz, the maximum thickness of the body to be demagnetized is determined from this condition. The time of complete magnetization depends on the material and body size; it can also vary depending on which particular hysteresis loop of the prog magnetization reversal occurs. Therefore, it is almost impossible to accurately calculate it to determine the required frequency of polarity variation of the demagnetizing field. Incomplete magnetization leads to uneven proabss

an integrator with an integrating capacitor, a frequency divider by two, a key, a subtraction element, a regulative control unit with a motor and a voltage source, while the measuring winding of the flow of the demagnetized body is connected to the input of the zero-organ and the integrator input, the output of which is through the subtraction element and the regulator control unit is connected to the control input of the current regulator, the output of the zero-organ is connected to the control input of the polarity switch and, through a frequency divider by two, to the control input of the key, The pinouts of which are connected to the integrator capacitor of the integrator, and the source of the reference voltage is connected to the second input of the subtraction element.

thickness demagnetization, which reduces the quality of demagnetization.

The most technically advanced invention of the invention is a demagnetization method, ferromagnetic bodies by acting on them with magnetic field pulses with alternating polarity and amplitude of 2j, which kill to zero. Moreover, the frequency of polarity change of the demagnetizing field is controlled depending on the size and mass (or physical parameters depending on these values) of the demagnetized body.

The known method is implemented by a demagnetization device, which contains a series-connected DC source, a current controller, a polarity switch and a demagnetizing winding 21,

The device also contains a variable frequency generator connected to a part of the demagnetized coils of the winding. The generator contains a high frequency stabilizer, a resistor, an expander, and a voltage-to-frequency converter.

In the known technical solution, the duration of the pulses of a demagnetizing field is determined by the frequency of the variable frequency generator signal, which depends on the inductance of the demagnetizing winding with the demagnetized body placed into it, and the role of the ferromagnetic core. The inductance of such a winding depends on the size and magnetic properties of the core However, this dependence differs from the dependence of the magnetization time on the same parameters. In addition, the full magnetising time is increased for materials with a higher electrical conductivity of the material, while the winding inductance decreases due to a decrease in the equivalent magnesium permeability of the material. Consequently, the frequency of the generator increases with, although it must be reduced from the condition of complete magnetization. The inductance of the winding is also largely determined by the number of its turns and configuration, which reduces the degree of dependence of the inductance of the size of the core, especially when windings with different numbers of turns are used for different types of materials. All this leads to the fact that complete magnetization is provided not for all types and sizes of ferromagnetic materials, but only for those for which the variable frequency generator was pre-calibrated. Consequently, the known technical solution does not provide high quality magnetising for different types and sizes of materials, or has a low productivity due to the need for preliminary calibration of the generator. In the well-known solution, there is also no criterion for choosing the number of demagnetized pulses, which leads either to an unreasonable increase in the demagnetization time or to a decrease in the quality of demagnetization if you choose an insufficiently large number of these pulses. Thus, the disadvantages of the known technical solution include the low quality and low demagnetization performance of ferromagnetic bodies. The aim of IZO fetine is to improve the quality and performance of the demagnetization of ferromagnetic bodies. This goal is achieved by the fact that according to the method of demagnetization of ferromagnetic bodies by applying magnetic field pulses with alternating polarity on them and with decreasing amplitude to zero amplitude, the longevity of each demagnetizing field pulse is set equal to. Changes in body flux. Moreover, the amplitude of the demagnetizing field intensity is reduced after each magnetization reversal in such a way that the decrease in the magnetic flux of the body does not exceed a specified value, and each decrease in the amplitude of the intensity does not exceed the magnitude of its decrease in the previous pulse. The proposed method can be implemented using a device for demagnetizing ferromagnetic bodies containing a series-connected direct current source, a current regulator, a polarity switch and a demagnetizing winding, which is equipped with a measuring winding of the demagnetized body, zero-body, integrator with an integrating capacitor, divider two frequencies, a key, a subtraction element, a control unit & laziness regulator, and a source of reference voltage, while the measuring winding p The magnetizable body is connected to the input of the nutt-organ and to the input of the HHTei patopa, the output of which is connected to the control input of the polarity switch and through the divider through the subtractive element and the controller control unit to the current controller | two frequencies to the control input of the switch, the short-circuits of which are connected to the integrator's capacitor integrator, and the source of the reference voltage is connected to the second input of the subtraction element. This technical solution makes it possible to eliminate the non-uniformity of demagnetization across the thickness of the ferromagnetic body due to its incomplete magnetization and to ensure the optimal demagnetization time for various types of material and geometrical dimensions of bodies. The drawing shows the block diagram of the device. The device contains a series-connected direct current source 1, a current regulator 2, a polarity switch 3 and a demagnetizing winding 4 into which the demagnetized body 5 is prevented, as well as a measuring winding 6 of the flow of the demagnetized body 5, the zero-organ 7, the integrator 8 with an integrating a condenser with an athera 9, a frequency divider 10 into two, a key 11, a subtraction element 12, a regulator control unit 13, and a source 14 of the reference voltage. The measuring winding 6 of the flow of the demagnetized body 5 is connected to the input of the zero-organ. The tick is the input of the integrator 8, the output of which through the subtraction element 12 and the controller control unit 13 is connected to the control input of the current regulator 2. The output of the zero-organ 7 is connected to the control the input of the polarity switch .3 and through :; divider 10, frequencies two by two; control; Key of key 11. The outputs of key 11 are connected to integrator 8 of integrator 8. Reference voltage source 14 is connected to the second input of subtraction element 12 The method is implemented using this device in the following way. When current is passed through the demagnetizing winding 4 from the direct current source 1 through the current regulator 2 and the polarity switch 3 in the demagnetizing winding 4, a magnetic field is created which magnetizes the demagnetized body 5. The intensity of this field is determined by the value of the current in the demagnetizing winding 4 At the moment a switching signal is received from the zero output of the organ 7 in the polarity switch 3, the connection of the ends of the winding 4 to the current controller 2 changes, so that the direction of the current in the winding 4 and polarity changes s magnetic field is reversed. The demagnetized body 5 is re-magnetized, and in the measuring winding 6 an impulse EMF2 is induced, the duration of which is equal to the time of change of the magnetic flux F of the body. This pulse arrives at the zero-body 7, in which the switching signal is produced at the moment when the EMF in the measuring winding 6 becomes equal to zero, i.e. at the moment when the body is fully magnetized. The switching signal, the access to the control input of the polarity switch 3, determines the moment of the next current change in the winding 4 and the polarity of the pulse of the magnetic field. The EMF pulse from the measuring winding 6 is also fed to the input of the integrator 8, and the EMF pulses induced by two adjacent reversal magnetizations have opposite polarity, –fia The output of the integrator 8 after two magnetization reversals is the voltage Uv (), where K is the other side of the integrator 1O; Magnetic flux increase over two cycles of magnetized V-This voltage, proportional to the increment of the magnetic flux of the body during two cycles of magnetization reversal, is fed to the input of subtraction element 12, to the second. The input of which receives the voltage from the output of the source 14 of the reference voltage (this voltage is set in accordance with the desired magnitude of the decrease in the flux of the demagnetized body at each magnetization reversal). A signal from the output of the subtraction element 12, proportional to the defrosting of the voltages Uu and and Q from the outputs of the integrator 8 and the source 14 of the reference voltage, arrives at the flow of the block 13 by the regulator, where the current regulating regulator 2 is generated. Moreover, if Inequality, the current flowing through the winding 4 is reduced by the same amount as in the previous remagnetization. If, however, the inequality Uu U о is satisfied, then the current is reduced by a smaller value than in the previous reversal, in accordance with the magnitude of the difference (Vc - UQ) so that the inequality (C (j) is fulfilled. Switch signal from the bypass of the null organ 7 It is also fed to frequency input 10 by two, at the output of which a signal is generated after every two polarity switches of the field.This signal controls key 11 that is used to reset integrator 8 by shorting the integrating capacitor 9 and preparing it for to determine the next increment of the magnetic flux of the body 5. Thus, the magnetisation of the demagnetized body by 5 impulses of the magnetic field alternates with an alternating polarity, the duration of each of which is equal to the time of change of the magnetic flux of the body. The amplitude of the demagnetized field intensity, demagnetizing winding 4, decreases

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to zero, and the nature of the decrease Ieoburenne provides an increase

The first step is that the magnetics of magnetism demagnetizing due to the sweat of the body do not exceed the specified irregularity of the magnitudes, and each decrease in the body's amplitude in thickness, but the strength of the magnitude does not exceed the magnitude of the demagnetization

due to the reduction of time spent

Pulse.

Claims (3)

IN FOR ITS IMPLEMENTATION. 1. The method of demagnetization of ferromagnetic bodies by exposing them to magnetic field pulses with alternating polarity and with amplitude decreasing to zero, distinguished by the fact that, in order to improve the quality and performance of demagnetization, the duration of each pulse of the demagnetizing field is set equal to the time of change of the magnetic flux of the body. > 1007187 2. The method according to claim 1, which is unsuccessful in that the amplitude of the demagnetizing field is reduced so that the decrease in the magnetic flux of the body does not exceed a predetermined value, and each decrease in the amplitude of the intensity does not exceed the value of its decrease in the previous pulse. 3. A device for demagnetizing ferromagnetic bodies, containing a DC source, a current regulator, a polarity switch and a demagnetizing winding, connected in series, characterized in that, in order to improve the quality and performance of demagnetization, it is equipped with a measuring winding of the flux of a demagnetized body, zero an organ, an integrator with an integrating capacitor, a frequency divider into two, a key, a subtraction element, a control unit for the regulator and a reference voltage source, while changing the total winding of the flow of the demagnetized body is connected to the input of the zero-organ and to the input of the integrator, the output of which through the subtraction element and the control unit of the regulator is connected to the control input of the regulator, so that the output of the zero-organ is connected to the control Input of the polarity switch and through the frequency divider into two to the control input of the key, the closing terminals of which are connected to the integrating capacitor of the integrator, and the reference voltage source is connected to the second input of the subtraction element.