UA140470U - ELECTROMAGNETIC-ACOUSTIC CONVERTER FOR ULTRASOUND CONTROL OF FERROMAGNETIC MATERIAL PRODUCTS - Google Patents

Abstract

Electromagnetic-acoustic transducer for ultrasonic control of products made of ferromagnetic materials, having a housing, fixed electrical connectors, tread, flat high-frequency inductor and a source of magnetic polarizing field, which are fixed in a non-ferromagnetic non-conductive base. The flat high-frequency inductor is rectangular in shape with two linear working sections of parallel conductors, the source of the polarizing magnetic field is made of two flat low-frequency inductors, the cross section of the conductors has a rectangular shape with a width-to-thickness ratio. , the dimensions coincide with the dimensions of the linear working sections of the parallel conductors of the flat high-frequency inductor, low-frequency inductors are mounted in the base so that their holes are located above the linear working sections of the parallel conductors of the flat high-frequency inductance. a counter on a magnetic field.

Description

The useful model belongs to the means of non-destructive ultrasonic non-contact control and can be used for defectoscopy and thickness measurement of electrically conductive ferromagnetic metal products using electromagnetic-acoustic (EMA) transducers (EMAP).

Well-known ultrasonic EMAP PIs for flaw detection of products having a case, fixed in it a flat high-frequency inductance coil and a source of a magnetic polarizing field based on permanent magnets.

The disadvantage of EMA converters of this type is a large force of attraction to the ferromagnetic product, which leads to the rapid failure of the EMA.

The closest to the proposed one is the ultrasonic EMA transducer (2), for flaw detection and thickness measurement of products and materials that have a body, electrical connectors fixed in it, a protector, a flat high-frequency inductance coil and a source of a magnetic polarizing field based on permanent magnets.

The disadvantage of such an ultrasonic EMA converter is also a large force of attraction to the ferromagnetic product, which leads to rapid damage of the EMAP.

The protector of such a converter quickly wears out due to rubbing against the surface of the ferromagnetic control object (OC).

The basis of a useful model is the task of creating an EMAP, the new implementation of which would allow to exclude the strong attraction of the converter to the ferromagnetic OK, thereby increasing the service life of the converter.

The problem is solved as follows. In the electromagnetic-acoustic transducer for ultrasonic inspection of products made of ferromagnetic materials, which has a housing, electrical connectors fixed in it, a protector, a flat high-frequency inductance coil and a source of magnetic polarizing field, which are fixed in a non-ferromagnetic non-conductive base, the flat high-frequency inductance coil is made of a rectangular form with two linear working areas of parallel conductors, the source of the polarizing magnetic field is made of two flat low-frequency inductors, the cross-section of which conductors has a rectangular shape with a width-to-thickness ratio of 5...10 times, both low-frequency inductors have holes inside that are coincide with

With the dimensions of the linear working sections of the parallel conductors of the flat high-frequency inductor, the low-frequency inductors are mounted in the base so that their holes are located above the linear working sections of the parallel conductors of the flat high-frequency inductor, while the low-frequency inductors are electrically connected to each other in opposition to the magnetic field .

In fig. 1 shows a diagram of the relative arrangement of a flat high-frequency inductor and low-frequency inductors.

In fig. 1 are marked: 1 - flat high-frequency inductor; 2 - the source of the magnetic polarizing field; C and 4 - low-frequency inductors; 5 and 6 - linear working sections of parallel conductors of a flat high-frequency inductor; 7 and 8 - holes of low-frequency inductors.

In fig. 2 shows a simplified design of the EMAP on the surface of the OK.

In fig. 2 marked: 1 - flat high-frequency inductor; 2 - the source of the magnetic polarizing field; C and 4 - low-frequency inductors; 5 and 6 - linear working sections of parallel conductors of a flat high-frequency inductor; 7 and 8 - holes of low-frequency inductors; 9 - body; 10- protector; 11 and 12 - electrical connectors; 13 - base; 14 - OK; 15 - insulating gasket. (g) and (-) - power supply polarity of low-frequency inductors. Arrows show the direction of propagation of ultrasonic pulses.

In fig. C shows the time sweeps of the voltage for powering low-frequency inductors (a) and for powering a flat high-frequency inductor (b).

In fig. C is marked: Ш - voltage; T - the duration of the power pulse of the low-frequency inductor coils; i - time; c - power supply pulse of a flat high-frequency inductance coil; and - received reflected impulse from OK.

EMAP works as follows. The EMAP, which has a body 9, is placed on the surface of the OK 14, as shown in Fig. 2, so that the protector 10 adheres to the surface of the OK 14.

Low-frequency inductors C and 4 magnetic field sources 2, insulating gasket 15 and flat high-frequency inductor 1 are fixed in the base 13, which in turn is fixed in the housing 9. Installation of the intersection of the conductors of low-frequency inductors C and 4 of a rectangular shape with a width-to-thickness ratio 5...10 times because it allows more effective concentration of the magnetic field in windows 7 and 8.

During the operation of the EMAP, the low-frequency inductor C and 4 sources of the magnetic field 2 are supplied with a voltage /, indicated in fig. 2 polarities (y i -3y, rectangular shape with a given time duration T, Fig. 3. A magnetic field is formed in windows 7 and 8, the vectors of magnetic induction of which are directed normal to the surface of OK 14 and in opposite directions. Due to the magnetic interaction of the low-frequency inductance coils

With and 4 with a magnetic field OK 14 and a short duration T of magnetization pulses EMAP is not attracted to the object of control. After the end of the transient processes in the low-frequency inductors C and 4, a high-frequency voltage, pulse c, is applied to the flat high-frequency inductor 1 through the electrical connector 12. As a result, a pulsed electromagnetic field is formed in the surface layer of the OK 14 under the linear working sections 5 and 6 of the parallel conductors of the flat high-frequency coil 1 of the inductance and under the windows 7 and 8. The interaction of the magnetic field and the high-frequency electromagnetic field in the surface layer of the OK 14 leads to the excitation of single-phase ultrasonic pulses that propagate in the volume of the OK 14. The ultrasonic pulses reflected from the OK 14 are received, the pulse and fig. 3b, due to the reverse EMA conversion by a flat high-frequency coil 1 inductance.

The protector 10 protects the EMAP from damage by the OK surface 14.

The technical result of the invention is that the converter of this design has a long duration of operation.

Sources of information: 1. Non-destructive testing: Reference book: In 7 vol. Pod obsch. ed. V.V. Klyueva. T.3:

Ultrasonic control / I.N. Ermolov, Yu.V. Lange. - M.: Mashinostroenie, 2006. - 864 p. 2. Mygushchenko R.P., Suchkov G.M., Petrishchev O.N., Desyatnychenko A.V. Theory and practice of electromagnetic-acoustic control. Part 5. Features of construction and practical application of ZMA devices for ultrasonic control of metal products: monograph. - Kh.: "Planeta-print" LLC, 2016. - 230 p.

Claims (1)

UTILITY MODEL FORMULA Zo An electromagnetic-acoustic transducer for ultrasonic inspection of products made of ferromagnetic materials, having a housing, electrical connectors fixed therein, a protector, a planar high-frequency inductor and a magnetic polarizing field source, which are fixed in a non-ferromagnetic non-conductive base, characterized by , that the flat high-frequency inductor is made of a rectangular shape with two linear working sections of parallel conductors, the source of the polarizing magnetic field is made of two flat low-frequency inductors, the cross-section of which conductors has a rectangular shape with a width-to-thickness ratio of 5...10 times, both low-frequency coils inductors have holes inside, the dimensions of which coincide with the dimensions of the linear working sections of the parallel conductors of the flat high-frequency inductor, the low-frequency inductors are mounted in the base so that their holes are located above linear working areas of parallel conductors of a flat high-frequency inductor, while the low-frequency inductors are electrically connected to each other in the opposite direction of the magnetic field.