RU108639U1 - DEVICE FOR DETERMINING THE COERCITIVE FORCE OF FERROMAGNETIC PRODUCTS - Google Patents

Abstract

 1. A device for determining the coercive force of ferromagnetic products magnetized from the surface by a bipolar magnet or an electromagnet, comprising two magnetic field sensors with parallel sensitivity axes located on the working surface of the device, characterized in that the magnetic field sensors are connected to the measuring transducer and indicator, calibrated in units of coercive force. ! 2. The device according to claim 1, characterized in that the magnetic field sensors are made sensitive to the direction of the latter, are located at the poles of the magnetized section of the product and are oriented in one direction, and their sensitivity axes are perpendicular to the working surface of the device. ! 3. The device according to claim 2, characterized in that the magnetic field sensors are located at a distance b = (1.2-1.8) a, where a is the distance between the points of the working surface of the device, in which the tangent component of the magnetic field magnetized product is zero. ! 4. The device according to claim 1, characterized in that the magnetic field sensors are made sensitive to the direction of the latter, are located between the poles of the magnetized section of the product at a minimum distance from each other and are oriented in opposite directions, and their sensitivity axes are parallel to the tangent component of the magnetic field of the magnetized product . ! 5. The device according to claim 1, characterized in that it is equipped with rolling elements on the surface of the controlled product in the direction perpendicular to the magnetization of the latter. ! 6. The device according to claim 1, characterized in that it is equipped with a meter

Description

The utility model relates to the field of measuring the magnetic parameters of ferromagnetic materials and can be used, for example, to determine the coercive force of materials, as well as properties and stress-strain state of various ferromagnetic products.

Known attached (overhead) magnetic devices for determining the coercive force of ferromagnetic materials on samples and products of various shapes and sizes [1]. They contain an open P- or C-shaped magnetic circuit, closed by a controlled product, with one or two coils (windings) installed on it, connected to a power source, and a magnetic field transducer (sensor) connected to a source of excitation and signal conversion. When determining the coercive force, the device is installed on the controlled product, the magnetizing current is supplied to the coil of the magnetic circuit from the power source, after turning off the magnetizing current (compensation) is supplied to the coil, and at the moment of zero or a given value of the readings of the magnetic field sensors, the current is proportional to the coercive force controlled product.

The technical solution closest to the proposed utility model is a device for determining the coercive force of ferromagnetic products pre-magnetized from the surface by a bipolar magnet or electromagnet [2], containing a bipolar magnetic field source with poles adjacent to the working surface of the device, and two magnetic field sensors, each of which is installed at the corresponding pole of the source, with the sensitivity axis perpendicular to the working surface of the device. The sensors are connected in series-counter with respect to homogeneous magnetic fields (sequentially in accordance with the magnetic field of the magnetized product). The coercive force of the product in the known device is determined by the magnitude of the compensation current supplied to the source of the magnetic field and corresponding to the readings of the magnetic field sensors equal to zero or a given value.

The disadvantage of the prototype device is the complexity due to the presence of a magnetic field source in the form of coils (coils) connected to the corresponding power supply, and a compensation current control device. In addition, the known device has a low speed due to the need to compensate for the magnetic field at the locations of the sensors.

The proposed utility model is aimed at simplifying the device and increasing its speed.

The specified technical result is achieved by the fact that in the device for determining the coercive force of ferromagnetic products magnetized from the surface by a bipolar magnet or an electromagnet containing two magnetic field sensors with sensitivity axes parallel to each other located on the working surface of the device, according to the utility model, the magnetic field sensors are connected to the measuring transducer and indicator, calibrated in units of measure of coercive force.

In addition, the magnetic field sensors are made sensitive to the direction of the latter, are located at the poles of the magnetized section of the product and are oriented in one direction, and their sensitivity axes are perpendicular to the working surface of the device. In addition, the magnetic field sensors can be located at a distance b = (1.2-1.8) a , where a is the distance between the points of the working surface of the device at which the tangent component of the magnetic field of the magnetized product is zero.

The magnetic field sensors can be made sensitive to the direction of the latter, located between the poles of the magnetized section of the product at a minimum distance from each other and oriented in opposite directions, and their sensitivity axes are parallel to the tangent component of the magnetic field of the magnetized product.

The device can be equipped with rolling elements on the surface of the controlled product in the direction perpendicular to the magnetization of the latter, as well as a measure of the distance traveled.

Connecting magnetic field sensors to a measuring transducer and an indicator calibrated in units of coercive force allows simplifying the device and increasing its speed by eliminating a special magnetic field source with a power supply and a magnetic field compensation system.

The implementation of the magnetic field sensors sensitive to the direction of the latter, their location at the poles of the magnetized section of the product with orientation in one direction and with sensitivity axes perpendicular to the working surface of the device, as well as the location of sensors oriented in opposite directions between the poles of the magnetized section of the product at a minimum distance of from each other with sensitivity axes parallel to the tangent component of the magnetic field of the magnetized product, provides yshenie accuracy of determining the coercive force of the tested article by reducing errors from uncontrolled (e.g., temperature) changes the initial sensor output signals. In addition, the influence of external homogeneous magnetic fields on the readings of the device is eliminated.

The location of the magnetic field sensors from each other at a distance b = (1.2-1.8) a , where a is the distance between the points of the working surface of the device at which the tangent component of the magnetic field of the magnetized product is equal to zero, provides improved measurement accuracy by minimizing the error due to the uncontrolled displacement of the device from a neutral position along the line connecting the magnetic field sensors (lateral displacement of the device when scanning along a magnetized strip of extended products).

The implementation of the device with rolling elements on the surface of the controlled product in the direction perpendicular to the magnetization of the latter extends the functionality of the device by continuously determining the coercive force of extended ferromagnetic products previously magnetized by moving a bipolar magnet or electromagnet along the surface of the product along a line perpendicular to the direction of magnetization.

The use of the distance traveled in the device (for example, a curvimeter) allows you to get a picture of the distribution of the coercive force along the surface of the product and thereby more accurately determine the state of the product.

A device for determining the coercive force of ferromagnetic products is illustrated by drawings, where in Fig.1 shows a block diagram of a device; figure 2 - topography of the magnetic field of the magnetized product and the location of the magnetic field sensors at the poles of the magnetized area; figure 3, 4 - the location of the magnetic field sensors between the poles of the magnetized section of the product; figure 5 - dependence of the readings A of the device from the displacement l of the device relative to the neutral position on the surface of the controlled product in the direction of one of the poles of the magnetized section, depending on the distance b between the magnetic field sensors.

The device consists of sensors 1 and 2 of a magnetic field (Fig. 1) mounted on the working surface (plane adjacent to the surface of the product being monitored) of the device (Fig. 2) at the corresponding poles of the magnetized section of the product or at a minimum distance from each other between the poles of the magnetized section of the product (figure 3, 4). Sensors 1 and 2 are connected to a measuring transducer 3 and an indicator 4 calibrated in units of coercive force (Fig. 1; power supply units of functional elements 1-4 are not shown in the figure).

Sensors 1 and 2 are made sensitive to the direction of the measured magnetic field (for example, in the form of Hall transducers), are located at the poles of the magnetized section of the product with orientation in one direction (up or down in figure 2), and their sensitivity axis (O ₁ and O ₂ ) perpendicular to the working surface of the device. In this case, the sensors can be located from each other at a distance b selected from the interval (1.2-1.8) a , where a is the distance between the points of the working surface of the device at which the tangent component of the magnetic field of the magnetized product is zero (magnetic induction In _{and the} magnetic field of the product is perpendicular to the working surface of the device).

Magnetic field sensors made sensitive to the direction of the latter can be located between the poles of the magnetized section of the product (Fig.3, 4) at a minimum distance from each other with the same spatial orientation and sensitivity axes (O ₁ and O ₂ ) parallel to the tangent component the magnetic field of a magnetized product (for example, one of the sensors can be oriented along vector B _{and the} magnetic field of the product, and the other sensor in the opposite direction, as shown in Figs. 3, 4).

In all cases, to obtain an increased useful signal from the magnetic field of the magnetized product, the signals from the outputs of the sensors 1 and 2 of the magnetic field (Fig. 1) are fed to a measuring transducer 3, in which the algebraic difference of the signals recorded by the indicator 4 is determined. In this case, the modules of useful signals are added , and spurious signals (for example, drift of sensor signals due to inconsistent ambient temperature) are compensated.

The device can be equipped with rolling elements on the surface of the controlled product in the direction perpendicular to the magnetization of the latter, as well as a measure of the distance traveled (not shown in the figures).

The device operates as follows. After preliminary magnetization of the controlled product using a bipolar magnetizing device (for example, a permanent magnet, dotted line in figure 2), a residual magnetization field is formed above the product. When placing the device over the magnetized portion of the product (or over the magnetized strip of the product obtained by moving the magnetizing device along a given direction along the surface of the product), signals proportional to the magnetic field at the points of location appear at the output of the sensors 1 and 2 of the magnetic field (Figs. 1-4) sensors. The signals are added to the measuring transducer 3 (Fig. 1) and recorded by an indicator 4 calibrated in units of coercive force, for example, in A / m. Due to the high demagnetization coefficient of product sections magnetized from the surface by a bipolar magnet or electromagnet, the magnetic field (magnetic induction measured by magnetic field sensors) above the magnetized part of the product is uniquely and linearly related to the coercive force of the material of this section.

When the magnetic field sensors are located at the poles of the magnetized section of the product (Fig. 2), the distance (base) b between the active elements of the magnetic field transducers can be selected from the interval (1.2-1.8) a , where a is the distance between the points of the working surface devices in which the tangent component of the magnetic field of the magnetized product is zero. The exit of the parameter b for the specified interval leads to an increase in the error (deviation of the readings A of the device from the nominal value, Fig. 5) associated with the possible uncontrolled displacement of the device l from the neutral position along the line connecting the magnetic field sensors. As can be seen from figure 3, with the base b ₁ = a and a certain offset L of the device from the neutral position, its readings significantly change (decrease). At the same time, with a base of b ₂ = 1.2 a and the same offset L, the readings of the device are reduced to a much lesser extent than the nominal value of A ₀₂ , and with a base of b ₃ , = 1.6 a, they practically remain at the level nominal value A ₀₃ . With a further increase in the base (& 4 = 1.8 a ), the readings of the device first increase from the nominal value of A ₀₄ , and then decrease. When b ₄ > 1.8 a, the error from uncontrolled displacement of the device from the neutral position increases significantly, moreover, this is accompanied by an unjustified increase in the dimensions of the device.

When monitoring extended magnetized sections (bands) of ferromagnetic products, the device moves along the magnetized strip, due to which the coercive force is continuously determined over the entire length of the section. For the convenience of moving the device along the magnetized strip, it can be equipped with rolling elements on the surface of the controlled product.

The proposed device allows for repeated repeated measurements on the same magnetized area (strip) of the controlled product, because, unlike devices with demagnetization elements (magnetic field compensation), it does not destroy the residual magnetization of the product. This, in turn, increases the accuracy of determining the coercive force of ferromagnetic products due to the possibility of multiple measurements in the same section (strip), including measurements after magnetization of the controlled section of the product in two opposite directions in order to exclude the influence of external magnetic fields on the readings of the device, for example, the fields of the earth. In addition, it becomes possible to repeatedly consecutive in time control (monitoring) of the magnetized sections of products, for example, when determining their stress-strain state.

Information sources

1. Gorkunov E.S., Zakharov V.A. Coercimeters with attached magnetic devices (overview). - Defectoscopy, 1995, No. 8, pp. 69-88.

2. Attached magnetic device. Description of the invention according to the patent for a utility model of the Russian Federation No. 99188, G01R 33/12.

Claims (6)

1. A device for determining the coercive force of ferromagnetic products magnetized from the surface by a bipolar magnet or an electromagnet, comprising two magnetic field sensors with parallel sensitivity axes located on the working surface of the device, characterized in that the magnetic field sensors are connected to the measuring transducer and indicator, calibrated in units of coercive force. 2. The device according to claim 1, characterized in that the magnetic field sensors are made sensitive to the direction of the latter, are located at the poles of the magnetized section of the product and are oriented in one direction, and their sensitivity axes are perpendicular to the working surface of the device. 3. The device according to claim 2, characterized in that the magnetic field sensors are located at a distance b = (1.2-1.8) a, where a is the distance between the points of the working surface of the device, in which the tangent component of the magnetic field magnetized product is zero. 4. The device according to claim 1, characterized in that the magnetic field sensors are made sensitive to the direction of the latter, are located between the poles of the magnetized section of the product at a minimum distance from each other and are oriented in opposite directions, and their sensitivity axes are parallel to the tangent component of the magnetic field of the magnetized product . 5. The device according to claim 1, characterized in that it is equipped with rolling elements on the surface of the controlled product in the direction perpendicular to the magnetization of the latter. 6. The device according to claim 1, characterized in that it is equipped with a meter of the traveled distance.