SU568917A1 - Three-component magnetic inductance transducer - Google Patents

Description

The invention relates to the field of measurement technology and can be used to simultaneously measure the orthogonal components of a variable magnetic induction vector in a given volume of a ferromagnet, arising, for example, from Barkgausen jumps.

The sintered-component magnetic induction sensors are known, consisting of a core of ferromagnetic material with excitation excitation located inside the mutually orthogonal measuring windings 1.

Three-component magnetic induction sensors are also known, consisting of a ferromagnetic toroidal warp sorter, on which exciting excitation is wound. Three mutually orthogonal measuring windings are located on top of the core with the exciting winding on a non-magnetic KapiKace of special shape 2.

However, these sensors have low sensitivity.

The aim of the invention is to increase the sensitivity of the sensor.

This goal is achieved in that in a three-component magnetic induction sensor comprising three mutually orthogonal ferromagnetic cores, one excitation winding and three measuring windings, each of the three measuring windings is located

on one of the cores made with gaps that form a cavity of cubic shape, and the exciting winding is located on one of the cores. FIG. Figure 1 shows the design of a three-component magnetic induction sensor, in which 1 is a ferromagnetic sample, 2-4 are magnetic conductors, 5-7 are measuring rpm, coils, 8 is field winding; in fig. 2 is the vector diagram, in which X, y, Z is the coordinate system, a, p, are the guiding angles, t is the vector of the magnetic moment, t, hpu, t are the vectors along the coordinate axes.

The device works as follows.

When current flows in the excitation winding 8, sample 1 is magnetized, which is accompanied by jumps in magnetization (the Barkhausen effect). The Barkhausen jump can be considered as a variable magnetic dipole with a magnetic moment m m (t). In general, the vector

t in a polycrystalline ferromagnet can be decomposed into components along the axes X, y, Z of the chosen coordinate system. These components will be proportional to the cosines of the direction angles a, p, and Y formed by the magnetic moment vector with the axes of the selected coordinate system. These components of the magnetic moment will be closed through the corresponding magnet drives 2, 3 n 4 n and induce AND (MP1 pulses edc in the corresponding measuring windings 5, 6 I 7 with amplitude proportional to the magnitude of the corresponding component of the magnetic moment of the magnetization jump.

Claims (2)

1. USSR author's certificate number 445620, cl. G 01 R 33/02, 1974 2. US patent number 3800213, cl. 324-43, 1974 ".-,. 7