UA82723C2 - Electromagnetic acoustic transformer - Google Patents

Abstract

The invention relates to non-destructive control of metal articles with electro-acoustic method. Electromagnetic acoustic transformer consists of magnetization unit and radiator placed between its poles. Magnetization unit has permanent magnet installed wit possibility of motion, as parallelepiped with rounded edges, placed between the upper ends of two magnetic conductors. Lower ends of magnetic conductors form poles of magnetization unit. Radiator is arranged as grid made of conductors parallel to each other and poles of magnetization unit. According to the invention transformer has two additional magnetic conductors lower ends of which are placed in plane of poles of magnetization unit normally with respect to conductors of grid. At that the upper ands of all the magnetic conductors are directed to center of magnet and the magnet is installed with possibility of rotation with respect to its point of symmetry. The invention provides increase of quality of measurements due to compensation of long component of external magnetic field.

Description

The invention relates to the technique of non-destructive control of metal products by the ultrasonic method.

When conducting non-destructive testing of metal products using the ultrasonic method, electromagnetic acoustic transducers (ZMA transducers) have become widely used, which allow the formation of an acoustic wave in the metal of the controlled object without the use of a contact liquid, through rust or paint coating. The principle of operation of ZMA converters is based on the formation of an acoustic wave as a result of the interaction of the primary and induced currents in the surface layer of the metal of the controlled object.

ZMA converters consist of a magnetizing unit and an emitter. The magnetization node is an electromagnet or a permanent magnet. The emitter is a coil or a set of elementary conductor threads located in close proximity to the surface of the controlled object or product.

The famous ZMA converter | see Scarlet Yu.M. Non-contact method of ultrasonic control. M.:

Mashinostroenie, 1974, p. 56.), intended for ultrasonic control of sheet metal. The ZMA converter consists of a magnetization unit and an emitter. In turn, the submagnetization node is a powerful concentrator of the magnetic field located on both sides of the controlled sheet of metal. The emitter is a spiral coil located between the controlled surface and the end of one of the magnetic field concentrators. The construction scheme of the ZMA converter does not allow monitoring of metal objects that have a significant thickness.

The famous ZMA converter | see Budenkov B.A., Budenkov G.A. etc. Non-contact introduction and reception of ultrasound. - Defectoscopy, 1969, Me1, p.121-123.), intended for ultrasonic control of metal products of any thickness. The ZMA converter consists of a magnetization unit and an emitter. The magnetization node is a U-shaped magnet, the poles of which are located on the surface of the controlled metal product. The emitter is a grid consisting of several conductors (emitter filaments) located in one plane parallel to each other. The grid is located between the poles of the magnet, parallel to the surface of the controlled product. For the formation of a sound wave by a system of in-phase emitters, the distance between the emitters is chosen equal to I-x. in case of violation of systems of anti-phase emitters I-x/h, where At is the length of a normal ultrasonic wave at the corresponding working point; pas. phase velocity of an ultrasonic wave; d. operating frequency of ultrasonic radiation.

The ZMA converter has a permanent magnet, which does not allow to quickly change the value of the magnetic induction of the external field on the surface of the controlled product. However, it is known (see V.G. Zychyna, N.A. Kesler

The influence of the magnetic field on the attenuation of ultrasonic oscillations. - Defectoscopy, 1972, Me3, pp. 53-58; Malinka

A.V., Drapkin I.A., Kolomoets N.T. Electromagnetic-acoustic method of monitoring ferromagnetic sheets and pipes. - Defectoscopy, 1972, Mo4, pp. 44-484, that the maximum effect during the control of products made of different materials is achieved at different values of the magnetic induction of the external field.

The famous ZMA converter | see Japanese patent 2004-177267, (01M29/04), which is a prototype of the claimed invention. The ZMA converter consists of a U-shaped submagnetization unit and an emitter.

The emitter is a grid consisting of several conductors (emitter filaments) located in one plane parallel to each other. The grid is located between the poles of the submagnetization node, parallel to the surface of the controlled product. The magnetization unit contains a permanent magnet located between the upper ends of the magnetic wires. The lower ends of the magnetic wires are the poles of the submagnetization node. A permanent magnet is a rectangular bar with rounded edges. The magnet is installed with the possibility of rotation around its transverse axis of symmetry, located parallel to the emitter threads. The design of the sensor allows changing the value of the magnetic induction of the external field on the surface of the controlled product within wide limits. At the same time, when measurements are taken under conditions of significant external fields, the direction of the resulting magnetic induction field vector on the surface of the controlled object may not coincide with the direction of the magnetic induction field vector formed by the submagnetization node. The design of the magnetization unit of the prototype does not allow changing the value of the magnetic induction of the longitudinal field. The presence of an uncompensated longitudinal component of the field can lead to variability in the measurement results of the same object under different conditions of exposure to external magnetic fields.

The invention is based on the task of improving the quality of measurements due to preliminary compensation of the transverse component of the external magnetic field. For this purpose, an additional U-shaped submagnetization node is introduced into the design of the ZMA converter, the poles of which are located on two sides of the emitter, perpendicular to the threads. This will make it possible to achieve stability of the magnetic image on the surface of the controlled object, which, in turn, will lead to the stability of the measurement results during control under conditions of external magnetic fields.

The problem, which is the basis of the invention, is solved due to the fact that in the ZMA converter, which consists of a magnetization node and an emitter located between its poles, which is a grid of several conductors located in the same plane parallel to each other and to the poles of the magnetization node, and the node magnetization is a movable permanent magnet in the shape of a rectangle with rounded edges, located between the upper ends of parallel magnetic wires, the lower ends of which form the poles of the magnetization node, in accordance with the invention, two additional magneto-waters are introduced into the converter, the lower ends of which are located from two sides of the emitter, in the plane of the poles of the magnetic wires of the submagnetization unit, perpendicular to the conductors of the grid, while the upper ends of all magnetic wires are directed to the center of the magnet, and the magnet is installed with the possibility of rotation around its point of symmetry. For ease of operation, the magnet can be pressed into a diamagnetic substance in the shape of a ball, which is located between the ends having spherical cutouts of magnetic wires, while the planes of symmetry of the magnet and the ball coincide.

The essence of the invention is as follows.

The ZMA converter consists of a magnetization unit and an emitter. The emitter is a grid consisting of several conductors located in the same plane parallel to each other (filaments

emitters). The grid is located between the poles of the submagnetization unit, in close proximity to the surface of the controlled product, parallel to it. Emitter threads should be located at a distance |, proportional to ХМ - the length of the normal acoustic wave disturbed by the ZMA converter.

That is, I-X/n, n-1, 2,... K where is an integer. In most cases of practical use of converters, p-1 or p-2 (see Glukhov N.A., Bobrov V.T., Veremenko S.V., Druzhaev Yu.A., Kolmogorov V.N., Lebedeva N.A. .

Electromagnetic-acoustic converters for elastic waveguides. - Defectoscopy, 1972, Moe4, pp. 38-45.).

In the control of products made of ferromagnetic materials, p-b (see Budenkov G.A. Gurevich S.Yu. Modern state of non-contact methods and tools of ultrasonic control: Acoustic methods. - Defektoscopy, 1981, Mo5, pp. b6-22.).

The magnetization unit consists of four magnetic wires installed perpendicular to the surface of the controlled product, around the emitter. At the same time, the poles of two magnetic conductors are located parallel to the threads, and the other two (additional) - perpendicular to the threads of the grid. The upper ends of the magnetic wires are directed towards the center of the magnet. The magnet, located between the upper ends of the magnetic wires, is made in the form of a parallelepiped with rounded edges. At the same time, the possibility of rotation of the magnet around its point of symmetry is ensured.

For the convenience of practical operation, the magnet is placed inside a sphere made of diamagnetic material, for example, by pressing.

The magnetic wires, the emitter and the ball of the magnet are fixed relative to each other by means of a rectangular bar made of dielectric material. At the same time, the emitter is attached to the lower side of the bar, to the sides of which the inner sides of the magnetic wires are attached. A spherical notch is made on the upper side of the dielectric bar.

For convenience, the ball can be supplied with a handle, and a coordinate grid is applied to the surface of the ball.

The operation of the proposed ZMA converter is as follows. For non-destructive testing,

The ZMA converter is installed on the surface of the controlled product. At the same time, the emitter is placed directly near the surface. With the help of the submagnetization node, a permanent magnetic field is created in the upper layer of the control object. The necessary characteristics of the magnetic field are obtained by rotating the magnet about its point of symmetry. When the magnet rotates, the value of the magnetic induction of the external field on the surface of the controlled product will change. In the specified position of the magnet, the maximum compensation of the longitudinal component of the external magnetic field will be ensured, with the given value of the magnetic induction of the transverse component. After that, an electric signal is applied to the emitter thread, as a result of which eddy currents are induced in the surface layer of the control object. The interaction of the primary and induced currents leads to the appearance of pressures that change with the ultrasonic frequency. Ultrasonic vibrations, in turn, create a space-periodic field in the metal, under the influence of which the particles of the medium vibrate. When oscillating particles cross the lines of force of the magnetic field, eddy currents arise in the surface layer of the metal, which are registered using the receiving part of the non-destructive testing system.

The design of the proposed ZMA converter is explained by the drawings shown in Fig. 1-3. Fig. 1 shows a sketch of a cross-section of the ZMA converter, Fig. 2 shows a top view, Fig. 3 shows a bottom view. Where 1 - emitter, 2 - magnet, C - magnetic wires, 4 - bar of dielectric material, 5 - ball, 6 - surface of controlled object, 7 - additional magnetic wires.

The use of the proposed ZMA converter will allow choosing the optimal characteristics of the magnetic field on the surface of the controlled product without using rotating magnets and electromagnets. 2: ravine; 4 1 In --- -- 2-2 more: i

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Claims (5)

1. Electromagnetic acoustic transducer, consisting of a submagnetization unit 1 located between its emitter poles, which is a grid of several conductors located in the same plane parallel to each other and to the poles of the submagnetization unit, and the submagnetization unit contains a permanent magnet installed with the possibility of movement in the form of a parallelepiped with rounded edges, located between the upper ends of two magnetic conductors, the lower ends of which form the poles of the sub-magnetization unit, which differs in that the converter contains two additional magnetic conductors, the lower ends of which are located on both sides of the emitter, in the plane of the poles of the sub-magnetization unit, perpendicular to the grid conductors, at thus, the upper ends of all magnetic conductors are directed to the center of the magnet, and the magnet is installed with the possibility of rotation around its point of symmetry. 2. Electromagnetic acoustic transducer according to point I, which is characterized by the fact that the magnet is pressed into a diamagnetic substance in the form of a sphere, which is located between the ends of the magnetic conductors, which have spherical cutouts, while the planes of symmetry of the magnet 1 of the sphere coincide. 3. Electromagnetic acoustic transducer according to item I, which is characterized by the fact that the emitter is fixed on a dielectric rectangular bar, to the sides of which the inner sides of the magnetic wires are attached. 4. Electromagnetic acoustic transducer according to item I, which differs in that the conductors of the emitter grid are located at a distance M/P, where X is the length of the normal acoustic wave excited by the electromagnetic acoustic transducer, n--1, 2... K is a positive integer. 5. Electromagnetic acoustic transducer according to claim 2, which differs in that a coordinate grid is applied to the surface of the ball, and the ball is equipped with a handle.