SU949563A1 - Magnetometer - Google Patents

Description

(54) MAGNETOMETER

one

The invention relates to the design of devices for determining the magnetic properties of ferromagnetic materials and products from them and can be used in the metallurgical and chemical industries.

A magnetometer is known which contains a magnetizing device, a sample holder, induction sensors and a galvanometer, which is a simple and reliable instrument.

The disadvantages of this magnetometer are the visual readout of readings and the frequency of measurements. With it, you can study only slow processes.

Closest to the invention is a vibrating sample magnetometer, comprising a compensation coil, a sample holder, a magnetizing device, a measuring coil, and a measuring circuit 23, containing a vibrator.

The disadvantage of the known magnetometer is the impossibility of determining the volume of the ferromagnetic phase if its specific magnetization is unknown or the volume is unknown. Measurement of these quantities is possible only with simultaneous measurement

magnetic and torsional moments of the sample.

The vibration magnetometer does not allow measuring the sample torque, which necessitates the use of additional devices, in particular, anisometers.

The need to measure the magnetic and torque on two instruments increases the errors, since errors occur when measuring the magnetic field, temperature, and heating rate at each individual installation (instrument).

The purpose of the invention is to improve the measurement accuracy.

The goal is achieved by the fact that a magnetometer containing a sample holder, a rod connecting the holder with a vibrator, a magnetizing unit in which the sample is placed, the measuring windings connected to the measuring Elm unit, is equipped with a torque sensor, and the rod is detachable, while one its part is connected to the sample holder, the other to the vibrator, and the middle part of the rod is placed in 30 coaxial bearings and connected to

torque sensor connected to the measuring unit.

The drawing shows a schematic diagram of the proposed magnetometer.

The magnetometer contains a sample holder placed between the measuring windings 2 and connected to the vibrator 3 by means of a stud 4. The rod 4 is made detachable at. In this case, one of its parts is connected with the sample holder 1, the other with a vibrator 3, and the middle part is placed in coaxially mounted sub-heaters 5 and connected by a pull 6 with a torque sensor 7. The sensor 7 is connected to the measuring unit 8. The magnetic moment of the sample is recorded. The measuring windings 2 located between the poles of the magnetizing unit 9 and connected to the measuring unit 8 are recorded.

The magnetometer works as follows.

The test sample is placed at an angle, for example, 15-45 to the direction of the magnetic field between the poles of the magnetizing unit 9, which ensures that when the device is turned on, the sample is turned on (creating a torque). Then, the torque is transmitted to the sensor 7 by means of the rod 4 and t gi. The EMF is amplified and recorded by the measuring unit 8. OD: at the same time as the sample torque arises, due to the influence of the vibrator 3 on the sample, EMF is created measuring windings The magnitude of the induced EMF is proportional to the magnetic moment of the sample, amplified and recorded by the measuring unit 8.

Thus, the invention makes it possible to measure simultaneously the torque and magnetic moments of the sample, which makes it possible to obtain data on the volume and specific magnetization of the ferromagnetic phase.

Claims (2)

1.Chechernikov V.I. Magnetic measurements. Moscow, Moscow State University, 1963, p. 54. 2. The author's certificate of the USSR 783732, cl. G 01 R 33/12, 1979. 7 S