RU187070U1 - UNIVERSAL MAGNETOELECTRIC MEASURING CELL - Google Patents

Abstract

The utility model relates to the field of measurement and can be used to measure the magnitude of the magnetoelectric effect in ferrite-piezoelectric composites in the field of low frequencies and electromechanical resonance. A universal magnetoelectric measuring cell contains a housing, a solenoid and a sample holder, while the holder with the sample installed in the seat is fixed due to the grooves inside the solenoid frame located inside the cell body, with miniature permanent magnets mounted on the ends of which, the sample holder consists of two parts which are interconnected using a spike groove system. The technical result is an increase in accuracy and repeatability of measurements. 3 s.p. f-ly, 4 ill.

Description

The utility model relates to the field of measurement and can be used to measure the magnitude of the magnetoelectric effect in ferrite-piezoelectric composites in the field of low frequencies and electromechanical resonance, as well as the dependence of the magnitude of the magnetoelectric effect on the magnitude of the magnetic field, electric field, temperature, humidity, pressure and other external influences .

The main application of magnetoelectric measuring cells is to measure the magnitude of the magnetoelectric effect in a sample for a given orientation of magnetic fields, increasing the accuracy and repeatability of the measurement results.

The magnetoelectric effect is known in composite materials consisting of magnetostrictive and piezoelectric components, and having both magnetic and electric types of ordering. As a result of the interaction of the piezoelectric and magnetostrictive subsystems with each other, such materials induce electric polarization in an external magnetic field or the appearance of magnetization in an external electric field:

where P _i is the electric polarization, M _i is the magnetization, H _j is the magnetic field, E _j is the electric field, α _ij is the susceptibility ME tensor, μ ₀ is the magnetic constant (See Bichurin M., Petrov V. Modeling of magnetoelectric effects in composites, Springer series in material science, Volume 201, 2014, pp. 108).

Known installations for measuring the magnetoelectric effect in composite materials in the field of low frequencies and electromechanical resonance, including an electromagnet, power supply, Helmholtz coils, magnetic field meter, signal generator, amplifier and oscilloscope (See Bichurin M.I., Petrov V. M., Filippov D.A., Srinivasan G., Nan CW Magnetoelectric materials - M .: Academy of Natural Sciences, 2006. - 296 s).

Measuring cells are known for studying external effects on the magnetoelectric effect in ferrite-piezoelectric composite materials containing a sealed housing, a sample holder, a solenoid, and a temperature sensor (See M. M. Vopson, Y. K. Fetisov, G. Caruntu and G. Srinivasan Measurement Techniques of the Magneto-Electric Coupling in Multiferroics // Materials 2017, 10, 963; K Gil, J Gil, B Cruz, A Ramirez, M Medina and J Torres Experimental set up of a magnetoelectric measuring system operating at different temperatures / / Journal of Physics: Conference Series 687 (2016) 012090).

The disadvantages of the known magnetoelectric measuring cells are large overall dimensions, a narrow range of applications, the use of expensive materials, poor repeatability of the measurement results.

Closest to the technical solution, it is a cell for measuring the magnetoelectric effect, adopted as a prototype, containing a teflon thermally insulated body, in which a modulating coil, a test sample and a temperature sensor are fixed (See Burdin, DA; Ekonomov, NA; Chashin, DV; Fetisov, LY; Fetisov, YK; Shamonin, M. Temperature Dependence of the Resonant Magnetoelectric Effect in Layered Heterostructures. Materials, 2017, 10, 1183) -prototype.

The disadvantages of the prototype are the use of external electromagnets to create a constant magnetic field, large overall dimensions, the ability to measure only the temperature dependence of the magnitude of the magnetoelectric effect, the high cost of manufacturing, poor repeatability of the measurement results.

The objective of the proposed solution is to measure the magnetoelectric effect in ferrite-piezoelectric composite materials under normal conditions and under the influence of external influences in a single universal miniature design, to increase the accuracy and repeatability of measurements.

This object is achieved by the fact that in a universal magnetoelectric measuring cell, comprising a housing, a solenoid and a sample holder, a holder with a sample installed in the seat is placed inside the solenoid frame located inside the cell body, on the ends of which miniature permanent magnets made of Nd alloy are installed -Fe-B. The sample holder has a cylindrical shape and consists of two parts that are interconnected using a tenon groove system. In the seat of the sample holder, temperature, humidity and pressure sensors can be placed. The solenoid consists of a plastic frame with a winding of insulated copper wire. Grooves for wire leads are made in the holder for connecting the sample to an external circuit.

To solve this problem, a universal magnetoelectric measuring cell is proposed, consisting of a housing, miniature permanent magnets, a solenoid, and a sample holder. For accurate positioning of the measured sample in the region of maximum magnetic fields, a composite cylindrical holder with a seat in which the sample and the temperature, humidity, pressure sensor can be placed is proposed. The connection of the two parts of the holder to each other is carried out using the "tongue-groove" system. To connect the sample to an external circuit, grooves for wire leads are provided in the holder. To create a modulating alternating magnetic field, a solenoid is proposed, consisting of a plastic frame with a winding of an insulated copper wire. The holder with the sample is fixed in the grooves inside the frame of the solenoid, which is then placed in the cell body. Unlike the prototype, where a constant uniform magnetic field is created using an external electromagnet, it is proposed to use miniature permanent magnets made of Nd-Fe-B alloy, which are placed at the edges of the cell body. It is proposed that cell construction details be made of heat-resistant plastic by three-dimensional printing.

The proposed solution allows to obtain the following technical result: measurements of the magnitude of the magnetoelectric effect in ferrite-piezoelectric composites in the low frequency and electromechanical resonance regions, as well as measurements of the magnitude of the magnetoelectric effect on the magnitude of the magnetic field, electric field, temperature, humidity, pressure, vibration, and others external influences in a single, universal, miniature design, consisting of inexpensive and easy to manufacture parts.

To explain the alleged invention proposed drawings.

FIG. 1 - design of a universal magnetoelectric measuring cell.

FIG. 2 - sectional design of the cell and the orientation of the magnetic fields.

FIG. 3 - dependence of the constant magnetic field in the center of the measuring cell on the transverse size of the permanent miniature magnets and the distance between them.

FIG. 4 - Dependence of the constant magnetic field in the center of the measuring cell on the temperature and transverse size of the permanent miniature magnets and with a distance between the magnets of 30 mm.

The device consists of a cell body 1, a solenoid 2, miniature permanent magnets 3, a sample holder 4.

The device operates as follows. The test sample in the form of a rectangular plate is placed in the holder of a cylindrical shape 4 in the seat 5. The holder 4 consists of two symmetrical parts that are connected to each other using a tenon groove system. The output voltage from the test sample is measured using wire leads soldered to the sample, which are led out through insulated grooves. The design of the holder allows the use of clamping spring contacts in the case of metallization of conductive tracks. To control the parameters of external influences, temperature, humidity, pressure, etc. sensors are placed next to the sample in the seat 5.

The holder 4 is placed inside the solenoid 2, which is a plastic frame 6 with a winding of insulated copper wire. An input signal from the generator is supplied to the copper winding, creating a modulating alternating magnetic field h (t) in the sample. The magnetic field is regulated by the number of turns of the solenoid winding and the amplitude of the signal supplied from the generator. The holder 4 is fixed in the frame 6 of the solenoid 2 due to the grooves 7, thereby achieving high accuracy of the installation of the sample at the point of maximum fields and increases the accuracy and repeatability of the measurement results.

A constant uniform magnetic field H is created in the center of the measuring cell using miniature permanent magnets 3 made of an Nd-Fe-B alloy and can change smoothly and discretely. A discrete change in the magnetic field is carried out by changing the geometric dimensions and the number of miniature permanent magnets

3. A smooth change in the magnetic field is carried out by changing the distance between the magnets by moving the movable magnet holders 8 in accordance with the scale 9 applied to the cell body 1.

Depending on the direction of polarization of the piezoelectric phase in the measured sample relative to the orientation of the magnetic fields H and h (t) in the proposed cell, conditions will arise for the longitudinal or transverse magnetoelectric effect to occur in the sample.

To study the influence of temperature, humidity, pressure, and other external influences, the proposed measuring cell with a sample can be located inside any test equipment (heat and cold chamber, vibrostand platform, pressure chamber, or vacuum thermostat), while the mutual orientation of the magnetic and electric fields will be preserved.

Thus, the present invention allows to measure the magnitude of the magnetoelectric effect in ferrite-piezoelectric composites in the field of low frequencies and electromechanical resonance, as well as the dependence of the magnitude of the magnetoelectric effect on the magnitude of the magnetic field, electric field, temperature, humidity, pressure, vibration and other external influences in a single , universal, tiny and inexpensive design.

Claims (4)

1. Universal magnetoelectric measuring cell, comprising a housing, a solenoid and a sample holder, characterized in that the holder with the sample installed in the seat is fixed due to the grooves inside the solenoid frame located inside the cell body, with miniature permanent magnets mounted on the ends of which, the holder The sample consists of two parts that are interconnected using a tenon groove system. 2. The universal magnetoelectric measuring cell according to claim 1, characterized in that the sample holder has a cylindrical shape. 3. The universal magnetoelectric measuring cell according to claim 1, characterized in that the magnets are made of Nd-Fe-B alloy. 4. The universal magnetoelectric measuring cell according to claim 1, characterized in that the solenoid consists of a plastic frame with a winding of an insulated copper wire.

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