SU1495727A1 - Device for measuring specific magnetic energy of ferromagnetic materials - Google Patents

Abstract

The invention can be used in mechanical engineering and instrument making in the control and manufacture of ferromagnetic materials (FMM). The device is designed to measure the specific magnetic energy of the FMM and contains a master oscillator 1, a differential amplifier 2, an integrator 3, a power amplifier 4, a horseshoe core 15 with a magnetizing winding 13, a recording device 9. Introduction to the device of power amplifier 5, resistor 6 and windings 14, the number of turns of which is identical to the number of turns of the magnetizing winding 13 makes it possible to increase the measurement accuracy and broaden the dynamic range. 1 il.

Description

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1, an animal belongs to magnetic engineering technology and can be used in mechanical engineering and instrument making in the control and manufacture of ferromagnetic materials.

The purpose of the invention is to show measurement accuracy and expand the dynamic range.

The lia drawing shows a structurally functional device diagram.

The device consists of a master oscillator 1, a differential amplifier 2, an integrator 3, a first 4 and a second 5 power amplifiers, per resistor 6, a voltage divider 7, a multiplier 8, a recording device 9, a limiting amplifier 10, a magnetic field induction sensor 11, a sensor 12 the intensity of the magnetic field 5 magnetizing 13 and the additional 14 windings, the horseshoe-shaped core 15 and the test ferromagnet 16.

In the device, a master oscillator 1, differential amplifier 2 (non-inverting input), integrator 3, power amplifier 4, resistor 6, and magnetizing winding 13 of horseshoe 15, which is located on sample 16, are connected in series. The first input of the second power amplifier 5 is connected parallel to the serially connected windings 13 and 14 of the horseshoe-shaped core 15, and the second parallel to the serially connected resistor 6 and the magnetizing winding 13, the output is loaded on the resistor 6. The sensor 11 is magnetic induction The field is connected to the inverting input of the differential amplifier 2 and the voltage divider 7, the multiplier 8 and the recording device 9, connected in series. Magnetic field strength sensor 12 is connected via a limiting amplifier 10 to the second input of the multiplier 8.

The device works as follows.

The magnetization reversal of the test ferromagnet 16 is carried out by means of a core 5, the magnetizing winding 13 of which is powered from the first power amplifier 4 through a resistor 6, to the input of which a signal determining the given magnetic field induction law is applied, from the master oscillator 1 through non-invertiou

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The iii input of the differential amplifier 2 and the integrator 3. Due to the nonlinear dependence of the tested ferromagnet 16 on the intensity, the given law of induction of the magnetic field is distorted. In order to eliminate this, the signal from the output of the induction sensor 11 of the magnetic field is applied to the inverting input of the differential amplifier 2, as a result of which a deep negative feedback is provided and the induction in the sample more closely approximates the given law. However, as the ferromagnet is approached due to the nonlinear inductance of the magnetizing winding in the magnetization circuit, the efficiency of the negative feedback circuit decreases due to the occurrence of phase distortions and an increase in the distorting signal, which can be seen from the analysis of the magnetization circuit differential equation, and the dynamic and frequency are reduced. by increasing the ratio of the scattering fields to the field in a ferromagnet with increasing frequency) ranges and the accuracy in measuring magnetic parameters of a ferromagnet.

In order to eliminate these undesirable effects, it is necessary to eliminate the influence of the nonlinear inductance of the magnetizing winding, which is most important as follows: the input of the second power amplifier 5 sends a signal from the resistor 6 of the magnetizing circuit and the additional winding 14, with careful fitting of the identity of the windings 13 and . 14, they have equal inductances; the flux passing through core 15 induces equal emf in them. The amplified signal is applied in antiphase to the magnetizing circuit resistor 6. If a significant transmission coefficient of the second power amplifier 5 is ensured, the equilibrium of this system will be achieved if the absolute values of the voltages on the winding 14 and resistor 6 and the opposite of their signs are equal, despite the flow of current through the magnetized winding. In this way, the voltage drop across the reactive component of the magnetizing winding will be compensated, the efficiency of the negative feedback circuit will increase) A9

Z and induction in a ferromagnet will have a given law regardless of the degree of saturation of the ferromagnet.

The measurement of specific magnetic energy is conducted in the usual way. . The voltage from induction sensor 11 allows, taking into account the thickness and specific gravity of the tested ferromagnet 16, to provide a direct reading of the measured value.

Claims (1)

Invention Formula A device for measuring the specific magnetic energy of ferromagnetic materials, containing a series-connected master oscillator, a differential amplifier, an integrator, a power amplifier, as well as a cohesive core with a magnetizing winding, magnetic induction sensor, the output of which is connected to the second input of the differential amplifier and through a divider the voltage is at the first input of the multiplier. 0 7 2 7 the second input of which is connected via a limiting amplifier to the output of the intensity sensor magnetic. (; the second field, the multiplier output to the registering device, which is due to the fact that, in order to improve the measurement accuracy, to expand the dynamic range, a second power amplifier, a resistor and an additional winding were introduced into it, mounted on a horseshoe-shaped core, the output of the first power amplifier connected to the first output of the input and the first output of the second power amplifier and through a resistor to the second output of the second power amplifier and to the first terminals of the magnetizing and additional windings, Ora output pre- polnitatgnoy secondary winding is connected to the input terminal of the second power amplifier vgood ,, and the second field winding - a common bus, with the number of turns and wire thickness and further ob- magnetizing coil of identical. five 0 five