SU1048434A1 - Device for measuring ferromagnetic material static magnetic parameters - Google Patents

Abstract

1. A DEVICE FOR MEASURING THE STATIC MAGNETIC PARAMETERS OF FERROMAGNETIC MATERIALS, containing a sequentially connected control unit, a current and a magnetizing winding, and also a measuring winding and a two-coordinate registration r .. r-i have a go. Tt-SK: rf. {-. G | CH7 f. .1 SftyJsbilf k1., (B / .: device, one input connected to the second output of the current generator, characterized in that, with the aim of improving the measurement accuracy, a field coil connected in parallel with the measuring winding, teslameter, one of the series-connected primary transducer located inside the coil of the field, and the measuring unit, the series-connected amplifiers and the compensation winding, as well as the series-connected differentiating unit and the zero-organ, while the differentiating unit is connected to the teslameter output, to the second input of the registering device and from (L input of the amplifier, and the zero-organ output to the input of the control unit, 2. The device according to claim 1, characterized in that the field coil and measuring gauge are made superconducting 4 00 4 00

Description

The invention relates to magnetic measurements and can be used to measure static magnetic measurements. parameters of ferromagnetic materials. A device for measuring the static magnetic parameters of ferromagnetic materials is known, comprising a current generator, a control unit connected to it and a magnetizing wind of a test sample, a measuring winding. sample, integrator, and coordinate recorder. The magnetic parameters in the device are measured in a quasi-static magnetization mode, i.e. with continuous to slow change in the intensity of us nichivayuschego sex. In this case, the sample magnetic flux is measured by the integrator by continuously measuring the volt-second EMF area, which is induced in the measuring winding of the IjLJ sample in the magnetic winding of the sample. However, this device is characterized by low accuracy and sensitivity, due to the need for long-term integration of small EMF values that are closest in technical essence to the proposed is a device for measuring the static magnetic parameters of ferromagnetic materials, containing a current generator, The magnetizing winding of the test specimen and the control unit, the emrigible winding of the test specimen and the control unit, a two-coordinate recording instrument and an integrator made in the form of a voltage-frequency converter and a pulse counter, are given to it. In the device, the magnetic parameters are measured by magnetizing the test sample and a pulse counter. mi magnetic field and measured increments of the magnetic flux of the sample corresponding to each step. Magnetic flux increments are measured by converting EMF shaken in the sample sample winding to frequency and counting the number of pulses in the process of changing the intensity of the magnetic field of level J2. However, the accuracy of static magnetic parameters of materials is also characteristic of the known device. The purpose of the invention is to carry out measurements of measurement points. The goal is achieved by the fact that a device for measuring static magnetic parameters of ferromagnetic materials, containing serially connected control bpok, current generator and magnetizing winding, also measuring winding and two-coordinate recording device, one input connected to the second you -> current generator, in addition, there is a coil field connected to the auxiliary measuring winding, a teo-meter consisting of a series-connected primary transducer located inside the coil field, and the measuring unit, the amplifier and the compensation winding connected in series, as well as the nullorgan differentiating unit connected in series, the input of the differentiating unit connected to the output of the teslameter, to the second input of the recording device and to the input of the amplifier, and the output zero-to-device - with control unit input. In this case, the coil floor and the measuring winding are made superconducting. The drawing shows a diagram explaining the operation of the device. The device contains a current generator -1, a control unit 2 connected to it, and a magnetizing winding 3 of test sample 4, a two-coordinate recording device 5, a measuring winding 6 of sample 4, a coil 7 connected to it, a cryostat 8 in which measuring winding 6 and coil field 7, teslameter 9, COCTOS from primary converter Yu and measuring unit 11, amplifier 12 and compensating winding 13 of sample 4, Measuring winding 6 and coil floor 7 made of special wire, for example from an alloy of tin and iobil Measuring winding 6 is made in the form of a detachable coil, covering test sample 4, and a primary device of 10 Teslameter 9 is placed in the rolling field 7 and Output 9 of the meter is connected to one of the inputs of the recording device 5 and through amplifier 12 to the compensation winding 13, and the second input of the registering device 5 to the measuring output of the current generator 1, the device also contains a series-connected differentiating unit 14 and a null organ 15, the output of which is connected to the input of the control flea 2, and in (Sch. Dif. The transmitting transmitter 14 to the output of teslameter 9. The device operates as follows. Measuring & 6 of sample 4 and coil field 7 forms a circuit placed in a cryostat 8 filled with liquid helium. When skipping tsk, from the current generator 1 through the magnetizing winding 3 It creates a magnetic field that magnetizes the sample under test 4, the intensity of this field is unambiguously determined by the value of the current in the magnetizing o (coil 3. The nature of the current change corresponds to the shape of the signal applied to the current generator 1 s control lock 2. When the current changes. in the magnetizing winding 3, and sequentially, and the intensity of the magnetizing sample 4, the magnetic field in the measuring winding 6 induces a current. This current, which is proportional to the sample flow to sample 4, has flowed across the coil of field 7, creates Majv in it. The induction field whose measurement is measured by a teslameter 9, the primary transducer 1O-of which is placed in the coil of the field 7. The signal at the output of the measuring unit 11 of the teslameter 9 is proportional to the magnetic flux pattern 4, arrives at the recording device 5, which simultaneously receives the signal from the measuring from the generator of current 1, is proportional to the intensity of the magnetizing field. The registering device 5 records the dependence of the magnetic flux of the sample on the intensity of the magnetizing field in the form of the main magnetization curve or hysteresis loops in accordance with the shape of the signal of the control unit 2 "This dependence gives the static characteristic of the material of the sample 4, which determines all its static cue magnetic parameters. The signal from the output of the teslameter 9 travels through the amplifier 12 to the compensating winding 13 in which a magnetic field is created that is proportional to the current in the measuring winding 6 and compensates for the change in the magnetizing field of the winding 3i caused by the own field of the measuring winding 6 when current flows through it. When samples of an electrically conductive material are tested in the control unit 2, at the moment of arrival of a pulse from an additionally introduced null organ 15, a signal is generated which causes a stepwise change in the current flowing through the magnetizing winding 3 in the current generator 1 to change leads to a change in the superconducting circuit. During the imputation flow time, the signal at the output of teslameter 9 is changed; This signal post also goes to the input of the additional input,. differentiating unit 14, at the output of which the voltage Urf- is different from zero: where Uf is the voltage at: output teslameter E | f is the constant of differentiating unit 14. At the moment of transfer of sample 4 to new. The static magnetic state corresponding to the new value of the field magnetizing field, the voltage Ug becomes equal to zero level n at the output of the null organ 15, the pulse arrives and the input of the control unit 2 causes a step change in the current in the current generator 1, In registering the device 5 also phyto-static static material of sample 4, but in discrete form

Claims (2)

1. DEVICE FOR MEASURING STATIC MAGNETIC PARAMETERS OF FERROMAGNETIC e MATERIALS, containing a serially connected control unit, a current generator and a magnetizing winding, as well as a measuring winding and a two-coordinate recording device, one input connected to the second output of the current generator, characterized in that, p. In order to increase the accuracy of measurements, a field coil connected in parallel to the measuring field is additionally introduced into it. casing, a teslameter consisting of a series-connected primary transducer located inside the field coil, and a measuring unit, series-connected arrays and a compensation winding, as well as series-connected differentiating unit and zero-organ, while the input of differentiating> unit is connected with the output of the teslameter, with the second input of the recording device and with the input of the amplifier, and the output of the zero-organ with the input of the control unit. 2. The device according to π. 1, featuring e e c i the fact that the field coil and due * q measuring coil is made superconducting ^with conductive. > 1 1048434 2