SU1730573A1 - Method of determination of coordinates of acoustic emission sources - Google Patents

Abstract

The invention relates to non-destructive testing and can be used for acoustic emission monitoring of the quality of thin-walled structures. The aim of the invention is to improve the accuracy of determining the coordinates of sources by taking into account, when determining the coordinates of the group velocities, zero symmetric and antisymmetric Lamb waves at the center frequency of the working frequency range. When monitoring thin-walled products, the frequency range is set in which the acoustic emission signals generated by Lzmb waves are received. In this case, optimal conditions are provided for the dispersion of the group velocity of this wave, when a broadband acoustic emission pulse, transforming into a quasi-sinusoid, forms a large amplitude signal received by a group of transducers.

Description

The invention relates to non-destructive testing and can be used for non-destructive testing of thin-walled structures.

A known method for determining the coordinates of an acoustic emission source, which consists in accepting acoustic emission signals by a group of electroacoustic transducers located on the surface of a test article, measures the arrival times of the front of received signals to electroacoustic transducers, which determine the coordinates of the acoustic emission sources.

The disadvantage of this method is its low accuracy and low reliability of determining the coordinates of the source, which is associated with the distortion of the pulse front formed by several Lamb waves and having a dispersion of the propagation velocity.

A method is known for determining the coordinates of acoustic emission sources in sheet materials, which consists in receiving acoustic emission signals from sources located in a selected control zone in a given frequency range by a group of receivers located at the corners of a rectangle,

VI

CJ

about ate

Xi

with

the time of arrival of these signals at the receivers is measured, the frequency range is selected in the area of existence in the controlled sheet only the zero modes of the Lamb waves, and the group of receivers are shifted relative to the selected control zone, the offset value being selected taking into account the ratio of the propagation speeds of the symmetric and antisymmetric Lamb waves.

This method does not provide a reliable determination of the coordinates of acoustic emission sources in thin-walled structures, since the frequency range of receiving acoustic emission signals is chosen in the existence region of only zero symmetric so and antisymmetric Lamb waves. This leads to an unreliable result in determining the coordinates of the sources, because due to the different nature and direction of the components of the oscillatory displacements in these waves, the signal of a symmetric zero Lamb wave So is always in amplitude less than the signal of an antisymmetric Lamb wave a0, while the receiving transducer The x difference in arrival times of the signals is recorded at the SQ wavefront, and at the distant ones, at the a0 wavefront.

The closest to the invention in its technical essence and the achieved result is a method for determining the coordinates of acoustic emission sources, which means that in a given frequency range acoustic emission signals are received by a group of electrical transducers located on the surface of the product under test, measure the wall thickness of the product and the speed of propagation transverse acoustic waves in the material of the product, and acoustic emission signals generated by Lamb waves are taken in the range e frequencies emom determined from the relationship:

fl, f2

1.8 С h

(1 ± 0.07),

where f 1, f2 is the frequency range;

C is the propagation speed of transverse acoustic waves in the material of the product;

h is the wall thickness of the product.

This method allows to increase the accuracy of determining the coordinates of acoustic emission sources by stabilizing the speed of propagation of the front of acoustic emission signals.

This method has significant limitations for its use in thin-walled structures (with a wall thickness of less than 6 millimeters), since

the average frequency of the working frequency range for receiving acoustic emission signals is outside the actual upper limit used; the use of high frequencies when receiving acoustic emission signals by

This method for thin-walled structures is limited due to a strong decrease in the accuracy and reliability of determining the coordinates of acoustic emission sources, since in the high-frequency region

there is a strong attenuation of acoustic emission signals as they propagate.

The purpose of the invention is to improve the accuracy of determining the coordinates of the sources of acoustic emission in thin-walled structures.

The goal is achieved by the method of determining the coordinates of acoustic emission sources, which consists in placing a group of transducers on the product, register the differences in arrival times of acoustic emission signals formed by a symmetric Lamb wave, and calculate

coordinates according to the time of arrival at receiving transducers and the value of the velocity of propagation of symmetric Lamb waves, choose the operating frequency

range for receiving signals from the condition:

Pif2

gO.2 p. 0.5 S-, Ik - j

(one)

where fi, f2 - boundary frequency range;

The C-velocity of the transverse wave in the material of the product; h is the product wall thickness, the group velocities of zero symmetric Ui and antisymmetric 1) 2 Lamb waves at the average frequency of the operating range are determined and they are taken into account when calculating the coordinates of acoustic emission sources.

The claimed method is characterized in that, in order to improve the accuracy of determining the coordinates of acoustic emission sources in thin-walled structures, an operating frequency range is selected for receiving acoustic emission signals from the condition:

fl ,. j

where fi, fa - boundary frequency range;

The C-velocity of the transverse wave in the material of the product;

h is the product wall thickness, the group velocities of the zero-symmetric Ui and the antisymmetric U2 Lamb waves at the center frequency of the operating range are determined and they are taken into account when calculating the coordinates of the acoustic emission source.

The proposed method optimizes the reception of a zero symmetric Lamb wave in order to improve the accuracy of determining the coordinates of defects. Acoustic emission signals are optimized by selecting the operating frequency range of signal reception in such a way that in the working frequency band the first signal from the series of propagating signals formed by Lamb waves should have a maximum amplitude, which allows measuring the difference in signal arrival times by various transducers in a group of signals with one group speed. For objects with a relatively thin wall (from 6 to 2 mm), the optimum frequency range can be a range with boundary frequencies defined by the relation:

fi -f2;

where fi, fa - boundary frequency range;

C is the speed of propagation of transverse waves in the material;

h is the wall thickness of the product. The lower limit of the frequency range fi is chosen from the condition of excluding the reception of the low-frequency part of the signal formed by the zero antisymmetric Lamba ao wave. The upper cutoff frequency of the optimal range of acoustic emission reception signals fa corresponds to the dimensionless parameter fh / C 0.5 and is selected because of the exclusion of the part of the quasi-sinusoid So wave, which is formed under the influence of the component with strong dispersions. Thus, in the selected frequency range, the component waves SQ form a quasi-sinusoid with a slowly varying frequency and a sufficiently large amplitude of normal displacements. Antisymmetric, the AO wave does not form a signal with a pronounced periodicity, which makes it possible to significantly reduce the magnitude of the signal when it is received at the output of the resonant receiving transducer. When receiving acoustic emission signals by equipment consisting of resonant transducers with a resonant frequency close to the average frequency of the operating range, electronic amplifiers with filters that provide amplification of signals

in the fH f 11 f frequency band, optimum efficient signal reception is obtained, formed by a zero symmetric Lamb wave So, at which, in the selected

The frequency range of the amplitude of the signal formed by a zero symmetric Lamb wave is greater than the amplitude of the signal of a zero antisymmetric Lamb wave. In this case, the difference in the arrival times of acoustic emission signals is recorded along the front of a zero symmetric Lamb wave, which improves the accuracy and reliability of determining the coordinates of acoustic emission sources. In addition, the method proposes not to exclude the values of the difference between the arrival times of the signals, which are recorded along the front of the zero antisymmetric Lamb wave, but to perform the calculation taking into account the zero symmetric one,

0 and zero antisymmetric waves, which allows an increase in the number of reliable measurements of the coordinates of acoustic emission sources.

The method for determining the coordinates of the acoustic emission sources is carried out as follows. On the walls of a thin-walled structure with a thickness h, made of a material with a speed of propagation of transverse acoustic

0 waves C, a group of electrical transducers is established, a working frequency range of reception is established according to the formula (1), and signals from the zero Lamb waves are received.

At the same time, in the specified frequency range, there are optimal conditions for the group velocity of a zero symmetric Lamb wave, when a broadband acoustic emission pulse, transforming into a quasi-sinusoidal zero symmetric Lamb wave, forms a signal with a slowly varying frequency and large amplitude. Then, in the selected frequency range, the group velocities of the zero symmetric and antisymmetric Lamb waves at the average frequency of the operating range are determined and taken into account when calculating the coordinates of the acoustic emission source.

0 The proposed method for determining the coordinates of the source of acoustic emission can be implemented in relation to aluminum alloy tanks and a wall thickness of 6 to 2 mm as follows.

5 Using the apparatus and method of ultrasonic measurements, determine the thickness of the vessel wall and the speed of propagation of transverse waves in the material of the product; calculated by the formula (1) the value of the boundary frequencies of the working reception range

acoustic emission signals and the nominal value of the resonant frequency of the transducer as the average value of the frequency range. The amplification path of the multichannel equipment is adjusted with the help of bandpass filters to the required frequency range. Piezoelectric type transducers with a resonant frequency close to the design one are used as working transducers. Receiving transducers are installed on the tank in the installed places. The equipment is calibrated and the values Ui of the group propagation velocity of the signal, formed by the zero symmetric Lamb So wave in the working frequency range fH, fa, are measured. The velocity value Ui is a parameter in the calculation of the coordinates of defects by the values of the measured differences of the arrival times of the signals. Using the obtained values of the difference in the time of arrival of acoustic emission signals using the value of the group propagation velocity of a zero symmetric Lamb wave, So, the coordinates of the sources of acoustic emission are calculated. In the process of equipment calibration, in addition to the Ui value of the group propagation velocity of the signal formed by the zero symmetric Lamb wave So, the U2 value of the group propagation velocity of the signal formed by the zero antisymmetric Lamb ao wave is measured in the operating frequency range; the values of Ui and Da are taken into account when calculating the coordinates of the acoustic emission source.

Using the proposed method allows the location of acoustic emission sources in structures with a wall thickness of less than 6 mm, to improve the accuracy of determining the coordinates of acoustic emission sources in thin-walled structures, since it allows to increase the accuracy of determining the coordinates of acoustic emission sources, as it allows increase the number of measurements due to the registered location series of values of the difference in arrival times of signals formed by the zero antisymmetric Lamb wave ao

Claims (1)

Invention Formula The method of determining the coordinates of the acoustic emission sources, which consists in placing a group of transducers on the product, register the arrival times of the acoustic emission signals formed by the symmetric Lamb wave, and calculate the coordinates from differences in arrival times at receiving transducers and the value of the velocity of propagation of symmetric Lamb waves, characterized in that, in order to increase the accuracy of determining the coordinates and the sources of acoustic emission on thin-walled structures, the working frequency range is chosen for receiving signals from fi  f2 .0,5 С where C is the velocity of the transverse wave; f 1 and f2 - boundary frequency range; h is the wall thickness of the structure, determine the group velocities of zero symmetric Ui and antisymmetric Ug Lamb waves at the mid-frequency of the operating range and take them into account when calculating the coordinates of acoustic emission sources.