SU953605A2 - Constant magnetic field measuring device - Google Patents

Description

The invention relates to magnetic measurements and can be used to measure magnetic fields in a wide range of variations in ambient temperature. According to the main auth. No. 892383, a device for measuring a constant magnetic field, comprising an amplifier connected in series, a recording device and induction coils wound on a magnetic field magnetic hub, with a magnetic resistor between them, and a voltage divider are known. To increase the sensitivity and accuracy of measurements with a wide range of ambient temperature changes, the ferromagnetic magnetic field concentrators are made covering on both sides only a part of the surface of the magnetoresistor, the third electrode of which is located in the area of the magnetoresistor. and the output of the amplifier is connected to the third electrode of the magnetoresistor and the midpoint of the voltage divider 11. top and bottom of the magneto resistor. This is due to the fact that the thermal conductivity of air is much less than the similar coefficient of a ferromagnetic concentrator magnetic field, and as a result, the dissipative thermal power from the part of the magnetoresistor covered by air is less than from the part of the magnetoresistor covered by the ferromagnetic concentrator. Therefore, when measuring small values of constant magnetic fields with a significant change in ambient temperature, this error is comparable with the useful CI-HaJiOM. . The purpose of the invention is to increase the measurement measurement over a wide range of ambient temperature variations. This goal is achieved by the fact that a device for measuring a constant magnetic field containing a series-connected amplifier, a recording device and induction coils wound around magnetic ferromagnetic magnetic hubs (Euler positioned between the magnetoresistor, as well as a voltage divider and ferromagnetic centralizers of the magnetic field covering in both sides a part of the surface of the magnetoresistor whose third electrode is located on the boundary of the area of the magnetoresistor covered ferromagnetic concentrators, the first output of the amplifier is connected to the third electrode of the magnetoresistor, and the second to the midpoint of the voltage divider, non-magnetic rods are introduced, covering on their sides a part of the surface of the magnetoresistor, and the other The magnetoresistive electrode is located at the boundary of the magnet resistor areas covered by ferromagnetic concentrators and rods of a nonmagnetic material. The drawing shows the principal electrical circuit of the proposed device. A three-electrode magnetoresistor 1 is placed in the gap between the ferromagnetic concentrators 2, which consist of two halves. The nonmagnetic rod 3 also consists of two halves with a close heat transfer coefficient of ferromagnetic rods. The ferromite aluminum concentrators 2 are made in such a way that they cover only half of the surface of the magnetoresistor 1, the other half of the surface of which covers nonmagnetic rods 3. The third electrode is soldered to the center of the magnetic resistor 1 at the boundary of the areas covered by ferromagnetic concentrators 2 and nonmagnetic rods 3 of non-magnetic material. At half of the ferromagnetic concentrators 2, induction windings k are located, which are connected to the output of amplifier 5 in series with a recording device 6, the readings of which are proportional to the measured magnetic field. The output signal of the amplifier is removed from the middle electrode of the magnetoresistor 1 and the midpoint of a voltage divider made of thermostable resistors 7 and 8. The magnetoresistor 1 and the voltage divider are connected to the output of the power supply 9. The device works as follows. In the absence of a measurable magnetic field, the bridge, the arms of which are thermostable resistors 7 and 8 and the resistance of the upper and lower parts (from the middle electrode) of the resistor 1, is balanced and there is no signal at the input of the amplifier 5. When a magnetically sensitive element is placed in a measured magnetic field, the equilibrium of the bridge is disturbed, since the magnetic flux will mainly penetrate only the upper part of the resistor 1 and, consequently, the resistance of the upper part of the resistor will increase. At the same time, the signal at the input of the amplifier 5, whose output signal through the recording device 6 is fed to the induction windings k, appears. The field created by these windings is used to compensate for the measured magnetic field. The current in the induction windings k will increase until the measured magnetic field in the gap is equal to the current field of the induction windings and, therefore, the bridge is not balanced. When the ambient temperature changes, the total total resistance of the magnetoresistor 1 changes. However, due to the fact that as the ambient temperature changes, the resistances of the upper and lower I vary almost equally from the middle electrode of the resistor, the ratio of these resistances does not change over a wide range of ambient temperature ere

Claims (1)

SUMMARY OF THE INVENTION A device for measuring a constant magnetic field, according to Auth. No. 892383, characterized in that, in order to increase the measurement accuracy over a wide range of ambient temperature changes, non-magnetic rods are introduced into it, covering part of the magnetoresistor surface on both sides, ferromagnetic concentrators and the third electrode are covering the other part of the magnetoresistor surface on both sides The magnetoresistor is located on the border of the magnetoresistor areas covered by ferromagnetic concentrators and rods of non-magnetic material.