RU108626U1 - DEVICE FOR LOCAL MEASUREMENT OF FERROMAGNETIC PHASE OF MATERIALS - Google Patents

Abstract

 1. A device for local measurement of the ferromagnetic phase of materials, including a magnetic system, a primary transducer for measuring the magnetic field and a measuring device associated with the primary transducer, characterized in that the magnetic system is made in the form of a hub made of a material with high saturation magnetization, on each a non-working surface of which a high-energy magnet is installed so that the poles of the same name magnets are directed inside the hub, the primary transducer is made in ide sensor for measuring magnetic field and located on the working surface of the concentrator. ! 2. The device according to claim 1, characterized in that the concentrator can be made of permendura or any other material with a saturation magnetization greater than the measured dynamic range of saturation magnetization of the investigated materials. ! 3. The device according to claim 1, characterized in that the NdFeB or SmCo magnet can be taken as a high-energy magnet. ! 4. The device according to claim 1, characterized in that as a sensor for measuring the magnetic field, a Hall sensor or a magnetoresistor can be used. ! 5. The device according to claim 1, characterized in that a permanent magnet with a high magnitude of remanent magnetization and high coercive force can be used as a concentrator when measuring materials with a low content of the ferromagnetic phase.

Description

The utility model relates to measuring technique for non-destructive testing in structural-phase analysis and can be used to determine the saturation magnetization of magnetic bulk materials, which can be used to judge the content of the magnetic phase.

Today, materials and alloys are widely used in industry, high requirements are imposed on their magnetic properties.

Determination of the phase composition of materials is necessary when assessing the changes that occur in this composition as a result of thermal and deformation effects when determining the concentration of the magnetic phase in non-ferromagnetic materials, pore volume and non-ferromagnetic inclusions in a ferromagnetic matrix.

One of the methods of phase analysis is a method based on the determination of saturation magnetization.

A known installation for measuring the saturation magnetization by the differential method [Scherbinin V.E., Gorkunov E.S. Magnetic quality control of metals. Publishing House: Ural Branch of the Russian Academy of Sciences IFM, 1996. - p.221-222]. This installation contains an electromagnet, ballistic galvanometer and patch coils. Two samples - standard and test - are fixed between the poles of an electromagnet. The measuring windings of these samples include counter. The internal fields of the standard and test samples are measured using patch coils. The saturation magnetization is determined by the formula:

Where - saturation magnetization of the test sample;

- saturation magnetization of a standard sample;

c _b - constant ballistic galvanometer;

Δα - galvanometer readings;

µ ₀ is the magnetic constant;

ω is the number of turns in the measuring windings of the standard and test samples;

S _cm is the cross-sectional area of the standard sample.

The main disadvantages of this setup are the need to use two samples - standard and test, insufficient accuracy in the case of field inhomogeneity in a plane perpendicular to the axis of the poles of the electromagnet, as well as the need for a ballistic galvanometer with a long oscillation period and cumbersome.

Also known is a setup for measuring the saturation magnetization according to the Shteblein method [Shcherbinin V.E., Gorkunov E.S. Magnetic quality control of metals. Publishing House: Ural Branch of the Russian Academy of Sciences, IPM, 1996. - p.223-224], which includes an electromagnet, a galvanometer, a non-ferromagnetic holder, and two measuring coils. The standard and test samples are fixed end-to-end in a non-ferromagnetic holder, which is moved when the electromagnet changes in the channel. Between the poles of the electromagnet are two measuring coils with a different number of turns, which include so that the emf induced in them are in the opposite direction. The difference between the saturation magnetizations of the standard and the investigated samples is determined by the deviation of the galvanometer pointer when moving them in the gap of the electromagnet. The saturation magnetization is calculated by the formula:

Where - saturation magnetization of the test sample;

- saturation magnetization of a standard sample;

c _b - constant ballistic galvanometer;

Δα - galvanometer readings;

µ ₀ is the magnetic constant;

(ω ₁ -ω ₂ ) is the difference between the turns of two coils.

The saturation magnetization of a standard sample is determined by the absolute method when moving it in the field of an electromagnet and is calculated by the formula:

where S _cm is the cross-sectional area of the standard sample.

The disadvantages of this setup are cumbersome, the inability to measure massive samples of materials in view of the fact that such samples cannot be magnetized to saturation in this setup. With the aid of the Steblein method for measuring saturation magnetization, only samples that are similar in shape to a standard sample can be measured.

The closest analogue of the claimed device is a ferrite phase content meter - FM-3 ferritometer [Rigmant MB, Gorkunov ES, Ponomarev B.C., Chernova GS Measurement of the content of the ferritic phase ferritometer FM-3. Publishing House: Ural Branch of the Russian Academy of Sciences Defectoscopy, No. 5, 1996, pp. 78-83], including a magnetic system consisting of a permanent magnet, a primary transducer for measuring the magnetic field, which is used as a flux-probe sensor placed in a non-magnetic protective case, in which the magnetically sensitive elements of the sensor are located in the plane of the neutral section of the magnet on its opposite sides orthogonal to its longitudinal axis, coaxial to each other. The device also contains a measuring device, to the electrical measuring unit of which the magnetically sensitive elements of the sensor are connected according to a gradiometric circuit, which eliminates the influence of an external constant magnetic field, for example, a geomagnetic field, a workshop field, etc.

When the device is installed on the surface of a ferromagnetic material, the area of material under the sensor is locally magnetized and creates an additional magnetic field acting on this sensor. The magnitude of the measured magnetic field is proportional to the amount of the α phase in the locally magnetized region.

The disadvantage of this device is the inability to magnetize the local area to saturation, since a magnetic system consisting of a permanent magnet creates an insufficient magnetic field. In the case of magnetization of the local area itself before saturation, the regions adjacent to this local area are not magnetized before saturation. The sensor readings are affected by both the local area magnetized to saturation and the areas adjacent to it. This in turn affects the accuracy of the measurement.

In addition, the tangential component of the magnetic field of scattering of the inhomogeneity of the material is measured, the value of which establishes the ferromagnetic phase of austenitic steels.

The utility model is based on the task of increasing the accuracy of determining the content of the ferromagnetic phase by measuring the normal component of magnetic induction, corresponding to the saturation magnetization.

The problem is solved in that in a device for local measurement of the ferromagnetic phase of materials, including a magnetic system, a primary transducer for measuring the magnetic field and a measuring device associated with the primary transducer, according to a utility model, the magnetic system is made in the form of a concentrator made of a material with high saturation magnetization, on each non-working surface of which a high-energy magnet is installed, so that the poles of the same name magnets are directed inside the concentrator, between primary transducer is a sensor for measuring the magnetic field and located on the working surface of the concentrator.

Wherein

- the concentrator can be made of a material with a high saturation magnetization, for example, permendera, and this material should have a saturation magnetization greater than the estimated measured dynamic range of saturation magnetization of the measured material;

- a NdFeB or SmCo magnet can be taken as a high-energy magnet;

- as a sensor for measuring the magnetic field using a Hall sensor or a magnetoresistor;

- as a concentrator when measuring materials with a low content of the ferromagnetic phase, a permanent magnet with a high value of the residual magnetization and coercive force can be used.

The inventive device due to the implementation of the magnetic system in the form of a hub made of a material with high saturation magnetization, on each non-working surface of which a high-energy magnet is installed, so that the magnet poles of the same name are directed inside the hub, allows you to create a large amplitude of the normal component of the magnetic field on the surface of the magnetized material and magnetize this surface to induction corresponding to saturation magnetization, and allows you to measure the normal composition yayuschuyu magnetic induction on the surface of the magnetized material.

The normal component of induction on the surface of the material and in the air is continuous, therefore, the measurement of magnetic induction in air on the surface of the material corresponds to induction in the surface layer of the material.

The proposed device due to its portability allows you to easily and quickly determine the saturation magnetization based on the measured values of the normal component of the magnetic field induction of bulk materials. By the value of the saturation magnetization, one can judge the ferromagnetic phase.

When measuring the saturation magnetization in materials with a low content of the ferromagnetic phase, the concentrator can be replaced by a permanent magnet with a high value of the residual magnetization. In this case, the magnetizing field near the working surface is greater than with a concentrator with a high saturation magnetization. This makes it possible to more accurately measure the saturation magnetization in materials with a low content of the ferromagnetic phase.

Thus, the new technical result achieved by the claimed model is to localize the surface of the bulk material in the normal direction to magnetic induction, corresponding to saturation magnetization, and measure the normal component of this induction with a portable device that does not require large energy consumption.

Figure 1 shows a diagram of the inventive device.

Figure 2 presents a side view of the magnetic system.

A device for local measurement of the ferromagnetic phase of materials (figure 1) is a portable device that contains a magnetic system 1 (figure 2) and a primary transducer 2 for measuring the magnetic field, placed in a protective housing 3, and a measuring device 4 for recording primary readings transducer 2. Magnetic system 1 includes a concentrator 5 of magnetic material with a high saturation magnetization, on each non-working surface of which a high-energy magnet 6 is installed, for example, NdFeB Do SmCo. As the magnetic material of the concentrator 5, a permendure or any other material of a material with a saturation magnetization greater than the expected measured dynamic range of the saturation magnetization of the measured material can be used, and as a primary transducer 2, a Hall sensor, a magnetoresistor, or other sensors for measuring the magnetic field can be used.

The device operates as follows.

When placing the device on the surface of the material, the magnetic system 1 interacts with the material, magnetizing the local area of the material with a field perpendicular to the surface of the material itself. Under the influence of this field, the material is magnetized to saturation magnetization.

The primary transducer 2 captures the value of the normal component of the magnetic induction corresponding to the saturation magnetization during magnetization of the local area of the material ≥500 A / cm, and transmits this value to the digital screen of the measuring device 4.

The device allows you to determine the magnetic induction corresponding to the saturation magnetization in the local region of the massive product in the range from 0 to 2.3 T. The upper limit of the dynamic range of the device for local measurement of the ferromagnetic phase of materials is determined by the saturation magnetization of the material of the concentrator.

Claims (5)

1. A device for local measurement of the ferromagnetic phase of materials, including a magnetic system, a primary transducer for measuring the magnetic field and a measuring device associated with the primary transducer, characterized in that the magnetic system is made in the form of a hub made of a material with high saturation magnetization, on each a non-working surface of which a high-energy magnet is installed so that the poles of the same name magnets are directed inside the hub, the primary transducer is made in ide sensor for measuring magnetic field and located on the working surface of the concentrator. 2. The device according to claim 1, characterized in that the concentrator can be made of permendura or any other material with a saturation magnetization greater than the measured dynamic range of saturation magnetization of the investigated materials. 3. The device according to claim 1, characterized in that the NdFeB or SmCo magnet can be taken as a high-energy magnet. 4. The device according to claim 1, characterized in that as a sensor for measuring the magnetic field, a Hall sensor or a magnetoresistor can be used. 5. The device according to claim 1, characterized in that a permanent magnet with a high magnitude of remanent magnetization and high coercive force can be used as a concentrator when measuring materials with a low content of the ferromagnetic phase.