RU58714U1 - EMA CONVERTER - Google Patents

Abstract

The utility model relates to the technique of non-destructive testing of metal products by the electromagnetic-acoustic method. The EMA converter consists of a U-shaped magnetization unit and an emitter in the form of a lattice located between the poles of the magnetization unit. The central part of the U-shaped magnetization unit is a permanent magnet made in the form of a rectangular isosceles obelisk. The inclined sides of the magnet are coupled to the ends of the magnetic conductors having a similar inclination. Due to the plane-parallel movement of the magnet perpendicular to the plane of the control object, a smooth change in magnetic induction is achieved.

Description

The utility model relates to the technique of non-destructive testing of metal products by the ultrasonic method.

When conducting non-destructive testing of metal products by the ultrasonic method, electromagnetic acoustic transducers (EMA transducers) were widely used, which made it possible to form an acoustic wave in the metal of a controlled object without using contact fluid, through rust or paintwork. The principle of operation of EMA transducers is based on the formation of an acoustic wave as a result of the interaction of a primary and induced currents in a surface layer of a metal of a controlled object.

EMA converters consist of a magnetization unit and a radiator. The magnetization unit is an electromagnet or a permanent magnet. The emitter is a coil or a set of filaments of conductors located in the immediate vicinity of the surface of the controlled object or product.

Known EMA transducer (see. Shkarlet Yu.M. Non-contact methods of ultrasonic testing. M: Engineering, 1974, p. 56.), designed for ultrasonic testing of sheet metal. The EMA converter consists of a magnetization unit and an emitter. In turn, the magnetization unit is a powerful magnetic field concentrators located on both sides of a controlled sheet of metal. The emitter is a spiral coil located between the surface to be monitored and the end of one of the magnetic field concentrators. The construction scheme of the EMA converter does not allow the monitoring of metal objects having a significant thickness.

Known EMA transducer (see Budenkov B.A., Budenkov G.A. et al. Non-contact input and reception of ultrasound. - Flaw detection, 1969, No. 1, p. 121-123.), Designed for ultrasonic testing of metal products of arbitrary thickness . The EMA converter consists of a magnetization unit and an emitter. The magnetization unit is a U-shaped magnet, the poles of which are located

on the surface of a controlled metal product. The emitter is a grating consisting of several conductors (filament emitters) located parallel to each other in the same plane. The lattice 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 l = λ; upon excitation of systems of antiphase emitters l = λ / 2, where λ = c _c / f is the length of the normal ultrasonic wave at the corresponding operating point; c _c is the phase velocity of the ultrasonic wave; f is the working frequency of ultrasonic radiation.

The EMA converter has a permanent magnet, which does not allow you 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 Eichina V.G., Kesler N.A. Influence of a magnetic field on the attenuation of ultrasonic vibrations. - Defectoscopy, 1972, No. 3, p. 53-58; Malinka A.V., Drapkin I.A. ., Kolomoyets NT Electromagnetic-acoustic method for monitoring ferromagnetic sheets and pipes. - Defectoscopy, 1972, No. 4, p. 44-48.), That the maximum effect when monitoring products from various materials is achieved with different values of the external magnetic induction fields.

Known EMA transducer (see Japan patent 2004-177267, G 01 N 29/04, the first option), designed for ultrasonic testing of metal products of arbitrary thickness. The EMA converter consists of a U-shaped magnetization unit and an emitter. The emitter is a grating consisting of several conductors (filament emitters) located parallel to each other in the same plane. The lattice is located between the poles of the magnetization unit, parallel to the surface of the controlled product. The magnetization unit includes an electromagnet mounted between the upper parts of the magnetic cores. The lower ends of the magnetic cores are the poles of the magnetization unit. The presence of an electromagnet will allow changing the value of the magnetic induction of the external field on the surface of the controlled product over a wide range, however, it leads to additional energy consumption, which in some cases is not practical for the converter.

Known EMA converter (see Japan patent 2004-177267, G 01 N 29/04, the second option), which is the prototype of the claimed utility model. EMA converter

consists of a U-shaped magnetization unit and a radiator. The emitter is a grating consisting of several conductors (filament emitters) located parallel to each other in the same plane. The lattice is located between the poles of the magnetization unit, parallel to the surface of the controlled product. The magnetization unit includes a permanent magnet located between the upper ends of the magnetic cores. The lower ends of the magnetic cores are the poles of the magnetization unit. The permanent magnet is a rectangular block with rounded edges. The magnet is mounted to rotate around its longitudinal axis of symmetry, parallel to the emitter threads. The design of the sensor allows you to change the magnetic induction of the external field on the surface of the controlled product in a wide range. However, the presence of a rotating magnet may be unacceptable due to the design limitations of the non-destructive testing system using this transducer.

The utility model is based on the task of expanding the technological capabilities of manufacturing EMA transducers with an adjustable value of the magnetic induction of an external field on the surface of a controlled product through the use of a magnet in the form of a rectangular isosceles obelisk mounted between bevelled ends of the magnetic conductors. Plane-parallel movement of the magnet along an axis perpendicular to the plane of the emitter will allow you to smoothly change the air gap between the poles of the magnet and the ends of the magnets. This, in turn, will allow for a smooth change in magnetic induction on the surface of the controlled product using a design solution that is different from analogues and prototype.

The problem underlying the utility model is solved due to the fact that in the EMA converter, consisting of a U-shaped magnetization unit and an emitter located between its poles, which is a lattice of several conductors located parallel to each other and the poles of the magnetization unit, in which the magnetization unit is a movable permanent magnet located between the upper ends of the parallel magnetic conductors, the lower ends of which form the poles of the magnetization unit According to the utility model, the magnet is made in the form of a rectangular isosceles obelisk placed above the emitter, inclined

the sides of which, being the poles of the magnet, are directed to the ends of the magnetic conductors having a similar inclination, and the smaller base of the magnet is directed to and parallel to the emitter, while the magnet is mounted with the possibility of plane-parallel movement along an axis perpendicular to the plane of the emitter.

The design of the proposed EMA converter is illustrated in the figure shown in Fig. 1, where 1 is the emitter, 2 is the magnet, 3 is the magnet guide, 4 is a bar of dielectric material, 5 is the plane-parallel movement mechanism, 6 is the surface of the controlled object.

The essence of the utility model is as follows.

The EMA converter consists of a U-shaped magnetization unit and an emitter. The emitter is a grating consisting of several conductors (filament emitters) located parallel to each other in the same plane. The grating is located between the poles of the magnetization unit, in close proximity to the surface of the controlled product, parallel to it. The emitter filaments should be located at a distance l = λ, l = λ / 2 (see Glukhov N.A., Bobrov V.T., Veremenko S.V., Druzhayev Yu.A., Kolmogorov V.N. ., Lebedeva N.A. Electromagnetic-acoustic transducers for elastic waveguides. — Defectoscopy, 1972, No. 4, p. 38-45.), Or, when monitoring products from ferromagnetic materials, at a distance l = λ / 6 (see Budenkov G.A. Gurevich S.Yu. Current state of non-contact methods and means of ultrasonic testing: Acoustic methods. - Flaw detection, 1981, No. 5, pp. 6-22.), Where λ is the length of a normal acoustic wave, excitation given by an EMA converter.

The U-shaped magnetization unit consists of a permanent magnet located in the central part of the unit and two magnetic conductors mounted perpendicular to the surface of the product being monitored. The magnet has the shape of a rectangular isosceles obelisk (see, for example, Bronstein I.N., Semedyaev K.A. Mathematics Handbook for Engineers and Students of the Higher Technical School. M .: Nauka, 1980, p. 222). It is installed parallel to the plane of the emitter, while the smaller base of the magnet is located on the side of the emitter. The inclined sides of the magnet, which are its poles, are directed to the ends of the magnetic conductors having a similar inclination.

Magnetic conductors, emitter and magnet are fixed relative to each other using a rectangular bar made of dielectric material.

In this case, the emitter is attached to the underside of the bar, to the sides of which

the inner sides of the magnetic cores are attached. On the upper side of the dielectric bar, a plane-parallel magnet movement mechanism is installed.

The work of the proposed EMA converter is as follows. For non-destructive testing, an EMA transducer is installed on the surface of the controlled product. In this case, the emitter is located in close proximity to the surface. Using a magnetization unit in the upper layer of the control object creates a constant magnetic field. The required characteristics of the magnetic field are obtained by moving the magnet along an axis perpendicular to the plane of the emitter. The value of the magnetic induction of the external field on the surface of the controlled product will change as the magnitude of the air gap between the poles of the magnet and the upper ends of the magnetic conductors changes. After that, an electric signal with predetermined characteristics is supplied to the emitter filaments, as a result of which eddy currents are induced in the surface layer of the test object. The interaction of the primary and induced currents leads to the appearance of pressures that change with an ultrasonic frequency. Ultrasonic vibrations, in turn, create a spatially periodic field in the metal, under the influence of which the particles of the medium oscillate. When oscillating particles cross the magnetic field lines, eddy currents occur in the surface layer of the metal, which are recorded using the receiving part of the non-destructive testing system.

The emitter filaments can be made by etching a metal foil glued to the underside of a dielectric bar, or sprayed.

Using the proposed EMA converter will allow you to choose the optimal characteristics of the magnetic field on the surface of the controlled product without the use of rotating magnets and electromagnets.

Claims (5)

1. Electromagnetic acoustic (EMA) transducer, consisting of a U-shaped magnetization unit and an emitter located between its poles, which is a array of several conductors parallel to each other and the poles of the magnetization unit, the magnetization unit is a movable permanent magnet, located between the upper ends of the magneto conductors parallel to each other, the lower ends of which form the poles of the magnetization unit, characterized in that the magnet it is made in the form of a rectangular isosceles obelisk placed above the emitter, the inclined sides of which are the poles of the magnet, directed to the ends of the magnetic conductors having a similar inclination, and the smaller base of the magnet is directed to the emitter and parallel to it, while the magnet is mounted with the possibility of plane-parallel movement along an axis perpendicular to the plane emitter. 2. The EMA transducer according to claim 1, characterized in that the conductors of the emitter lattice are located at a distance of λ, λ / 2 or λ / 6 from each other, where λ is the length of the normal acoustic wave excited by the EMA transducer. 3. The EMA converter according to claim 1, characterized in that the emitter is mounted on a rectangular dielectric bar, the inner sides of the magnetic conductors are attached to its sides, and a plane-parallel magnet movement mechanism is installed on the upper side of the dielectric rectangular bar. 4. The EMA converter according to claim 2, characterized in that the emitter lattice is made by etching a metal foil deposited on a rectangular dielectric bar. 5. The EMA converter according to claim 2, characterized in that the emitter lattice is made by spraying a metal onto the underside of a rectangular dielectric bar.