SU842658A1 - Method of measuring coercive force - Google Patents

Description

The invention relates to a measuring technique and can be used to measure the coercive force of permanent magnets and samples in coercimeters with an incompletely closed magnetic system. A number of methods for measuring the coercive force implemented in devices are known. When these methods are implemented, the influence of the transverse magnetic field of the magnetic system on the measurement results is eliminated by compensation with two sensors and 12. However, the use of these methods for the implementation of devices leads to the complication of the design of coercimeters and a decrease in measurement accuracy. There is also known a method implemented in a device in which a sample is placed in a magnetic field, the vertical and horizontal components of the resulting magnetic field of the specimen and the sample are measured, and the determination of the ramp moment of the sample producing the vertical component of the magnetic field 3. However, this The method is also complex because it is necessary to compensate for the vertical component of the magnetic system of the system, which leads to complication. The purpose of the invention is to simplify the measurement method. This goal is achieved by the fact that in the method consisting in that the test sample is placed in a permanent magnetic field, the vertical and horizontal components of the resulting magnetic field of the magnetic system and the sample are measured, the sample is demagnetized before the disappearance of the vertical component, and the coercive force is judged by the horizontal component at this moment, the measurement of the vertical component of the resulting field is made near the transverse axis of the megaiti system at the point where there is no uet vertical component of the magnetic roll system, and the sample is placed so that its transverse axis is offset from ho otnoscheniya to the axis of the magnetic systems. FIG. 1 shows a coercimeter that implements the proposed method; in fig. Figure 2 shows schematically the ratio of the strength vectors of the demagnetizing field and the magnetic sample. ; the co99 coercitime contains a magnetic system 1, placed in the gap itTeNW the test sample. 2, the sample magnetization sensor 3, located on the transverse axis of the 4 magnet system and connected to the measuring device 5, the magnetic field strength sensor 6 connected to the measuring device 7. At point O (figure 2) corresponding to the center of the magnetization sensor, vectors 8 and 9 — The strengths of the demagnetizing field and the magnetic field of the sample (having horizontal and vertical components of 10 and 11), the tangent, respectively, of the power lines of the magnetic field 12 and the field 13 of the magnetic system l.

The method is carried out as follows.

The test sample 2 is placed into the gap of the magnetic system 1, its Hc1 magnetization is performed, and in the process of demagnetization it is determined by the device 7 connected with the sensor 6, the intensity of the demagnetizing field at the moment when the reading of the measuring device 5 connected to the sensor 3 reaches zero. Due to the symmetry of the magnetic field lines of the system 1, the strength of the demagnetizing field at point O is determined only by the longitudinal component of vector 8, since the transverse component of the voltage at this point is zero and does not affect the measurement result. At the same time, due to the asymmetric arrangement of the sensor 3 relative to the ends of the sample (Fig. 1) at the point O (Fig. 2), a vertical component 11 of the magnetic field of the sample is present, due to its magnetization. In the event that the absorption meter is tuned, i.e. Sensor 3 is not affected by the longitudinal component of the voltage vector and the demagnetized field, the readings of instrument 5 will be proportional only to the magnetization of the sample.

The coercimeter is configured as follows.

In the absence of a test specimen with a demagnetizing field strength in the magnetic system gap equal to or greater than its coercive force, zero reading of the measuring device 5 is achieved by changing the orientation of the sensor 3 pattern, for example, rotating the sensor in a plane passing through the longitudinal axial magnetic system and sensor center, In this case, when the sensor center is located on the transverse axis of the magnetic system, the influence of the transverse and longitudinal components of the demagnetizing intensity vectors the floor is completely excluded from the measurement result of the coercive force.

The proposed method for measuring the coercive force makes it possible to simplify the design of devices for measuring the coercive force.

Claims (3)

1. USSR author's certificate  345459, class G 01 R 33/12, 1970.. 2. Andrievsky E.A., Forester L.N., Uncovered L.F. Compensation of the vertical component of the demagnetizing field in devices with a partially closed magnetic system. Kiev, Haykova Dumka Technical issues 40 Electrodynamics 1973, p. 89 3. USSR author's certificate 410344, cl. G 01 R 33/12, 1972 (prototype). -BUT D