RU37836U1 - DEVICE FOR MEASURING MAGNETIC CHARACTERISTICS OF FERROMAGNETIC MATERIALS - Google Patents

Abstract

A device for determining the magnetic characteristics of ferromagnetic materials, containing a serially connected AC source, voltage regulator, magnetizing coil, resistor, the first scalable amplifier, the output of which is connected to the inputs of the phase shifter and the horizontal channel of the oscilloscope beam and the first input of the label former, the second input of which is connected to an adjustable reference voltage source, and the output - with the input of the channel of the brightness modulation of the oscilloscope beam, measuring cat an ear, a second scalable amplifier, an integrator connected in series with it, the first input of which is connected to the output of the second scalable amplifier, the second input - with the output of the phase shifter, and the output - with the input of the vertical channel of the oscilloscope beam, characterized in that the magnetizing magnetization coil is made two-section with diversity sections one from another at a distance equal to their radius, contains an additional compensation winding, powered by an adjustable constant current source and equipped with a re magnetic axis alignment, the measuring coil is wound on two frames located respectively within the length of the test sample, the windings of which are connected in series with the input of the second scalable amplifier, and the magnetic axes are perpendicular to the axis of the magnetizing coil, the voltage regulator and the reference voltage source contain analog-to-digital converters and digital indicators of the amplitude of the magnetization reversal field and the instantaneous value of the magnetization reversal field corresponding to the brightness

Description

A device for measuring the magnetic characteristics of ferromagnetic materials.

The utility model relates to measuring technique, namely, to measuring the magnetic properties of samples made mainly on the basis of thin magnetic films (TMP), with the help of hysteresis curves.

A device (1) is known for measuring the characteristics of single-layer TMP in local areas of a sample using a magneto-optical polarimeter.

The measurement process with its application is time-consuming and complicated, since in order to achieve sufficient accuracy it is necessary to make a large number of measurements at various points of the sample and determine the average values of the measured TMP parameter. In addition, the measurement of the parameters of multilayer magnetic films is fundamentally not possible due to the screening of the lower layers by the upper ones.

In another known device (2), an induction method is used to measure magnetic characteristics, in which a hysteresis curve is displayed on the oscilloscope screen, which displays the magnetic state of a sample subjected to cyclic magnetization reversal in a low-frequency magnetic field.

The measuring part of the device provides measurement of the coercive force of the sample along the axes of easy and difficult magnetization of the TMP, anisotropy field, and saturation field. The device allows you to observe and determine the presence of defects in individual sections of the magnetization curve, negatively affecting the correct functioning of the magnetic core as part of its application.

However, no measures were taken in this device to eliminate the influence on the measurement accuracy of external magnetic fields of interference, integrator zero drift, type 1 / F noise, and there is no visual control

MPK7S01KZZ / 12.33 / 14.

the position of the strobe pulse on the hysteresis loop, which is important from the point of view of efficiency and reliability of the measurement results.

The closest to the technical essence of the proposed utility model is a device for determining the magnetic characteristics of ferromagnetic materials (3), containing a series-connected AC source and voltage regulator connected to the output of the voltage regulator and series-connected resistor and magnetizing coil connected to the measuring coil and in series connected first amplifier, integrator and nerve stroboscopic transducer, first scale installation unit ba connected to a resistor and connected in series to a second amplifier, a second stroboscopic converter, a second scale setting unit, a first phase shifter and a first pulse amplifier connected in series, connected to the second inputs of the first and second stroboscopic converters, a mixer connected to the outputs of the pulse amplifiers, the second phase shifter connected by the input to the output of the AC source, and vkodom - to the input of the first phase shifter, connected to the output of the second phase a rotator and a second pulse amplifier, a third stroboscopic converter and a subtraction unit connected in series, moreover, the second input of the third stroboscopic converter is connected to the output of the integrator, the second input of the absorption unit is connected to the output of the first stroboscopic converter, the output of the subtraction unit is connected to the input of the first scale setting unit, and mixer outputs - with outputs of the first and second pulse amplifiers.

In this device, at the inputs of the first and second stroboscopic converters, there are voltages, Un, proportional to the values of the induction of the samples and the magnetizing field, respectively.

By applying these voltages to the horizontal and vertical inputs of the oscilloscope, an image of a hysteresis loop is obtained on its screen.

Stroboscopic transducers make it possible to fix the instantaneous values of u and Un at the points of interest in the hysteresis loop and, using external measuring instruments, measure their values. Luminance modulation of the oscilloscope beam by pulses from

the output of the mixer, allows you to highlight the position of the label on the interesting sections of the hysteresis loop. The double gating of the signal U and the application of the subtraction “signal 1+ interference minus” signal2 + interference reduces the influence on the accuracy of measurements of low-frequency noise of the form 1 / F and the zero drift of the integrator. However, in the above device, interference with a frequency equal to the frequency of the magnetization reversal of the sample is not suppressed, the effect on the sample of the Earth's geomagnetic field and constant magnetic fields of the metal structures of production facilities and equipment is not compensated, the influence on the measurement accuracy of the magnetization remagnetization field created by the magnetization magnet is not taken into account.

The purpose of this utility model is to create a device for measuring the magnetic characteristics of a ferromagnetic material with high measurement accuracy.

This goal is achieved by the fact that in a device for measuring the magnetic characteristics of ferromagnetic materials,

containing a serially connected AC source, voltage regulator, magnetizing coil, resistor, the first scalable amplifier, the output of which is connected to the inputs of the phase shifter, the horizontal channel of the oscilloscope beam and the first input of the label former, the second input of which

connected to an adjustable reference voltage source, and the output to the input of the channel of the brightness modulation of the oscilloscope beam, a measuring coil, a second scalable amplifier, an integrator connected in series with it, the first input of which is connected to the output of the second scalable amplifier, the second input to the output of the phase shifter, and the output - with the input of the vertical channel of the oscilloscope beam, according to the new utility model, the magnetizing coil is made of two sections with

spacing the sections one from the other at a distance equal to their radius, contains an additional compensation winding, powered by an adjustable constant current source and equipped with a magnetic axis control mechanism, the measuring coil is wound on two frames located within the length of the test sample, the windings of which are connected in opposite-sequence

They contain analog-to-digital converters and digital indicators of the magnetization reversal field amplitude, as well as the instantaneous value of the magnetization reversal field, corresponding to the position of the brightness mark on the magnetization reversal curve of the magnetic circuit sample.

New in the proposed device for measuring the magnetic characteristics of ferromagnetic materials, is that the magnetizing coil is made two-sectional with spacing the sections one from another to a distance equal to their radius, contains an additional compensation winding, powered by an adjustable constant current source and equipped with a mechanism for regulating the magnetic axis, the measuring coil is wound on two frames located respectively within the length of the test sample, the windings of which are included finite in series with the input of the second scalable amplifier, and the magnetic axes are perpendicular to the plane of the sample and the axis of the magnetizing coil, the voltage regulator and the voltage reference source contain analog-digital converters and digital indicators of the magnetization reversal field amplitude and instantaneous value, magnetization reversal field corresponding to the position of the brightness mark on the magnetization reversal curve sample magnetic circuit.

The figure 1 shows the structural diagram of the proposed device for measuring the magnetic characteristics of ferromagnetic materials.

Figure 2 shows a magnetizing magnet with a test sample placed in a pei.

A device for measuring the magnetic characteristics of ferromagnetic materials contains a serially connected alternating current source 1, voltage regulator 2, magnetization reversal field amplitude indicator 3 and magnetizing magnetization coil 4 with a test sample 5 placed in it. Compensation coil 6 is connected to a direct current source 7. Resistor 8 is connected to the first scaling amplifier 9, the output of which is connected to the phase shifter 10, with the horizontal input X of the oscilloscope beam 11 and the first input of the shaper threads 12. The second input of the label former 12 is connected to the output of the adjustable voltage reference 13, the second output of which is connected to

reference voltage indicator 14. The output of the label driver 12 is connected to the input Z of the brightness modulation of the beam of the oscilloscope 11.

The measuring coil 15 is connected to the second scaling amplifier 16, and through the integrator 17 with the input "Y of the channel of the vertical deflection of the beam of the oscilloscope 11.

The integrator 17 interacts with the phase shifter 10 and is equipped with a device 18 for automatic compensation of zero drift.

The device operates as follows.

Alternating current from the AC source 1 through the voltage regulator 2 flows through the magnetizing coil 4 and the resistor 8. A sample 5 placed in the magnetizing coil 4 is magnetized and induces in the measuring coil 15 EMF proportional to the speed of measurement of induction in the test sample 5.

This signal is fed to the input of the second scaling amplifier 16 and then to the first input of the integrator 17, and from the output of the integrator to the input of the oscilloscope 11.

When the inputs X and Y of the oscilloscope 11 are turned off, a light spot of the beam is set in the center of the screen. Turning on the inputs X and Y of the oscilloscope 11 and receiving a horizontal scan of the beam using an amplifier 9 sets the horizontal deviation of the beam, approximately within 2/3 of the width of the screen.

Then, using the phase shifter 10, the ellipse of the forward and reverse beam paths is eliminated and, using the mechanism for adjusting the axis position of the magnetizing magnet 4, the alignment of the beam line with the horizontal axis of the screen is achieved.

Since the magnetization reversal field in coil 4, the voltage across the resistor 8 and at the output of the first scalable amplifier 9 will change in direct proportion to the magnetization reversal current, the instantaneous voltage values at the first input of the label former 12 reflect the instantaneous magnetization reversal field. At the moment when the voltage at the first input of the shaper becomes equal to the reference, the logical state of the comparator, which is part of the shaper of the label 12, changes and a short pulse is generated, which is used to illuminate the beam of the oscilloscope 11.

in sample 5, established by the working volume

magnetization coil, under the influence of the magnetization field changes its magnetic state. Moreover, the field lines of the induced field of the sample penetrate both windings of the measuring coil 15 in opposite directions. Since the windings are turned on in series, the induced EMF is added up. The signal of the measuring coil is amplified by a scaler1; it is amplified by 16 and, after integration, from the output of the integrator 17 is fed to the input U of the vertical beam of the oscilloscope 11.

The integration operation is necessary to convert the signal into a form that reflects changes in the magnetic induction of the magnetic circuit, depending on the magnitude of the magnetization reversal field.

Further, by using a second scaling amplifier 16, a beam deflection of approximately 2/3 of the screen height is established by adjusting the current from the current source 7 to compensate for the constant magnetic field. This ensures a symmetrical position of the observed magnetization reversal curve relative to the vertical axis of the screen of the oscilloscope 11.

Then, by changing the magnitude of the reference voltage of the source 13, a light mark is set at a characteristic point of the magnetization reversal curve, and the value of the measured parameter of the sample is counted using indicator 14, calibrated in units of magnetic field strength.

The implementation of the device is carried out on a modern elemental base and does not cause any significant difficulties. In this case, the voltage regulator 2, the reference voltage source 13, scalable amplifiers 9.16 and integrator 17 can be performed on operational amplifiers, the label former 12 can be used on digital logic ICs, field indicators 13, 14 on seven-segment luminescent or liquid crystal ICs that are compatible with analog -digital converter, for example on ZLS 324B1 and 572 PV, respectively.

The implementation of the magnetizing coil in the form of two sections,

The presence of an additional compensation winding, powered by an adjustable DC source, allows you to compensate for the geomagnetic field and the field of metal structures of industrial premises.

The mechanism for controlling the direction of the magnetic axis eliminates the direct effect of the magnetizing field on the measuring coil.

The constructive placement of the measuring coil on two frames and the opposite-sequential inclusion of their windings allows you to neutralize the influence of an alternating field with a frequency equal to the frequency of the magnetization reversal field created by interference sources located outside the magnetic system of the device.

The use in the device of digital indicators of the magnetization reversal field amplitude and the measured instantaneous field value corresponding to the position of the brightness mark at the point of interest in the magnetization reversal curve of the sample ensures the efficiency of measurements and eliminates the operator error that occurs when arrow measuring devices are used for these purposes.

The above signs make it possible to provide high accuracy in measuring the magnetic characteristics of samples of magnetic cores with low magnetic mass.

Sources of information.

1.V.D. Molchanov “Magnetic microelectronics. J. "Soviet Radio, M. 1997, p. 223.

2. “The current state and development of methods and equipment for the study of ferromagnetic materials. Proceedings of the metrological institutes of the USSR, M.-L, Publishing House of Standards, 1967, vol. 95 (155) p. 33.

3. Description of the invention to the copyright certificate of the Russian Federation No. 1112328 “Device for determining the magnetic characteristics of ferromagnetic materials, cl. G01R 33/12, G01R33 / 14, publ. 09/07/84

Claims (1)

A device for determining the magnetic characteristics of ferromagnetic materials, containing a serially connected AC source, voltage regulator, magnetizing coil, resistor, the first scalable amplifier, the output of which is connected to the inputs of the phase shifter and the horizontal channel of the oscilloscope beam and the first input of the label former, the second input of which is connected to an adjustable reference voltage source, and the output - with the input of the channel of the brightness modulation of the oscilloscope beam, measuring cat an ear, a second scalable amplifier, an integrator connected in series with it, the first input of which is connected to the output of the second scalable amplifier, the second input - with the output of the phase shifter, and the output - with the input of the vertical channel of the oscilloscope beam, characterized in that the magnetizing magnetization coil is made two-section with diversity sections one from another at a distance equal to their radius, contains an additional compensation winding, powered by an adjustable constant current source and equipped with a re magnetic axis alignment, the measuring coil is wound on two frames located respectively within the length of the test sample, the windings of which are connected in series with the input of the second scalable amplifier, and the magnetic axes are perpendicular to the axis of the magnetizing coil, the voltage regulator and the reference voltage source contain analog-to-digital converters and digital indicators of the amplitude of the magnetization reversal field and the instantaneous value of the magnetization reversal field corresponding to the brightness marks on the sample magnetization reversal of the magnetic curve.