SU792180A2 - Apparatus for measuring statistic magnetic characteristics of ferromagnetic materials - Google Patents

Description

one

This invention relates to the field of magnetometry, in particular to measurement; magnetic characteristics of ferromagnetic materials in constant magnetic fields and can be used to measure the magnetization of the tested ferromagnetic materials.

According to the main author. St. No. 558235, a device for measuring the static magnetic characteristics of ferromagnetic materials when testing core samples in an open-loop magnetic field is known. chains sh.

The device contains a magnetizing coil and a measuring coil connected via a synchronous detector to the input of a two-coordinate plotter, another input of which is connected to the output of an adjustable DC source through a magnetizing coil, as well as series-connected control voltage generator connected to the second input of the synchronous detector. , and the mechanism of angular oscillations. The measuring coil is made in the form of a rectangular frame, the plane of the coils of which is parallel to the direction of the magnetizing field and the axis of the mechanism

angular oscillations, and the large side of the measuring coil, coinciding with the direction of the magnetizing field, is chosen from the condition A / B,

5 where A is the large side of the measuring coil; in - the smaller side of the measuring coil.

This device allows measurements of a magnetic hysteresis loop over the magnetization averaged over the entire volume of the test specimen (i.e. magnetic moment) as a function of the intensity of the external magnetic field. However as

} 5 It is known that the magnetic characteristics measured in an open magnetic circuit are not material characteristics due to the influence of the sample shape. One of the ways to approximate the measurement results to the material characteristics, i.e. understanding the accuracy of measurements of the characteristics of the material is the measurement of the magnetic characteristics in the central part

25 core sample with a large ratio of length to diameter.

In order to increase the accuracy, a device has been introduced into the device for measuring the static gage characteristics of ferromagnetic materials.

-ir

792180

The measuring coils connected in series and in accordance with the main measuring coil and located symmetrically relative to the main measuring coil so that the sides of the main and additional measuring coils are mutually parallel, and the projection of the sample onto the plane of the turns of the additional coils intersects their sides.

FIG. 1 and 2 schematically show the location of the measuring coils relative to the sample, the direction of the magnetic field and the axis of the angular oscillation mechanism.

Additional measuring coils 1 are located symmetrically with respect to the main measuring coil 2, for which they are symmetrically shifted along the axis Y, perpendicular to the direction of the magnetic field H and axis 3 of the mechanism of angular oscillations. Additional measuring coils 1 are made so that their sides parallel to the large sides of the main measuring coil 2 and, therefore, to sample 4 are less than the length of sample 4. As can be seen from the frontal projection, additional measuring coils 1 are arranged so that the projection of sample 4 to the plane of the turns additional measuring coils 1 crosses their sides.

Sample 4, mounted on the axis 3 of the mechanism of angular oscillations, makes an angular oscillation, while in

the main 2 and additional 1 measuring coils emf occurs. The magnitude of the emf in this case is directly proportional to the magnetization of the central part of the sample 4.

The resulting magnetic characteristics (magnetization as a function of the field) correspond with great accuracy to the characteristics of the sample material and make it easier to take into account the influence of the shape of the sample on the measurement result.

Claims (1)

1. USSR author's certificate No. 558235, cl. G 01 R 33/02, 1978.