SU1019323A1 - Material acoustic emission checking device - Google Patents

Abstract

DEVICE FOR ACOUSTIC EMISSION MONITORING MATERIALS, containing not less than three channels for receiving signals, each of which consists of a series-connected electroacoustic converter and amplifier, the first and second filters, the inputs of which are connected to the output of the amplifier, time meter, digital memory block, output unit information connected in series and connected to the output of the amplifier of the control unit and the control unit, the first output of which is connected to the control input of the digital memory location, the second one with a controllable input of the information output unit, characterized in that, in order to increase reliability, each signal receiving channel is provided connected in series and connected between the first filter and the first input of the time interval meter with the first detector, the first differentiating unit and the first by the comparison unit, the first analog memory unit, the input of which is connected to the output of the first detector, the output of the first detector is connected to the second input of the first comparison unit, connected by a series between the second filter and the second input of the time interval meter, the second detector, the second differentiating unit and the second comparison unit, the second analog memory unit, the input of which is connected to the output of the second detector, the output of the second detector, connected to the second input of the second comparison unit In series with an analog voltmeter, a logarithm unit, a multiplication unit and a digital voltmeter, the inputs of the analog voltmeter are connected respectively to the output of the first and second a the tax memory blocks, the third output of the control unit (Lazy is connected to the control input of the time interval meter, the fourth output of the control unit is connected to the second input of the multiplying unit its fifth output - to the control input of the digital voltmeter, the second output of the logarithm is connected to the second input of the digital voltmeter, the output of the time interval meter is connected to the input of the digital memory unit, the first output of the digital voltmeter is connected to the second input of the digital memory unit, the second output of the digital voltmeter meter - with the first input of information output unit 00, the output of the digital memory block - with the second input of the information height unit, the output of the multiplication unit with the third input of the information output unit, the synchronization input and the synchronization output of the control unit are connected to the corresponding outputs and inputs of the blocks control the remaining receive channels.

Description

The invention relates to non-destructive testing of materials and can be used to determine the coordinates of defects from acoustic emission signals. A device is known for determining the coordinates of sources of acoustic emission signals containing at least three reception channels, each of which consists of a transducer connected in series, an amplifier and a filter unit, the time difference between the arrival of signals and the computing unit. A disadvantage of this device is the low reliability due to the complex mathematical processing of the information obtained, which consists in solving the triangulation problem for the acoustic emission signals arriving at the transducers. The closest to the invention in terms of technical drying is a device for acoustic emission monitoring of materials containing at least three channels for receiving signals, each of which consists of an electroacoustic converter and amplifier connected in series, the first and second filters, whose inputs are connected to the output of an amplifier, meter time intervals, digital storage unit, information output unit connected in series and connected to the output of the amplifier of the control unit and the control unit, first The output of which is connected to the control input of the digital storage unit, the second to the control input of the digital storage unit, and the second to the control input of the information output unit 2. A disadvantage of the known device is the low reliability of control due to the measurement error of the arrival time difference signals of different frequencies included in the energy spectrum of acoustic emission signals. The aim of the invention is to increase the reliability of the control. This goal is achieved by the fact that, in a device for acoustic emission monitoring of materials, there are at least three channels for receiving signals, each of which consists of an electroacoustic transducer and amplifier connected in series, the first and second filters, whose inputs are connected to the output of the amplifier, a time meter digital storage unit, information output unit connected in series and connected to the output of the amplifier of the control unit and the control unit, the first output of which is connected to the control unit An AV input of a digital storage unit, a second one with a control input of an information output unit, each signal receiving channel is provided with serially connected and connected between the first filter and the first input of the time interval meter, the first detector, the first differentiating unit and the first comparison unit, the first analog unit a memory whose input is connected to the output of the first detector, the output of the first detector is connected to the second input of the first comparison unit, connected in series and connected between the second the second filter and the second input of the time interval meter by the second detector, the second differentiating unit and the second comparison unit, the second analog memory unit whose input is connected to the output of the second detector, the output of the second detector connected to the second input of the comparison unit connected in series by an analog voltmeter, logarithm unit , the multiplication unit and the digital voltmeter, the inputs of the analog voltmeter are connected respectively to the output of the first and second analog memory blocks, the third output of the block the control is connected to the control input of the time interval meter, the fourth output of the control unit is connected to the second input of the multiplication unit, its fifth output is connected to the control input of the digital voltmeter, the second output of the logarithmic unit is connected to the second input of the digital voltmeter, the output of the time interval meter is connected to the input of a digital voltmeter - with the first input of the information output unit, the output of the digital storage unit - with the second input of the information output unit, the output of the multiplication unit - with the third input of the output unit and the information input sync and output sync control unit connected to the respective outputs and inputs of the remaining control units receiving channels. The drawing shows a device for acoustic emission monitoring of materials. The device contains channels 1-3 for receiving signals, each of which consists of electroacoustic converter 4 connected in series and amplifier 5, first 6 and second 7 filters, whose inputs are connected to the output of amplifier 5, meter 8 time intervals, digital block 9 of memory, block 10 information outputs connected in series and connected to the output of the amplifier 5 of the control unit 11 and the control unit 12, the first output of which is connected to the control input of the digital memory unit 9, the second to the control input of the unit 10 Ode information. Each channel 1-3 receiving signals is connected in series and connected between the first filter 6.

and the first input of the meter 8 time intervals by the first detector 13, the first differentiating unit 14 and the first comparison unit 15, the first analog memory block 16, whose input is connected to the output of the first detector 13, the output of which is connected to the second input of the first comparison unit 15, connected sequentially and connected between the second filter 7 and the second input of the meter .8 time intervals the second detector 17, the second differentiating unit 18 and the second comparison unit 19, the second analog memory unit 20, whose input is A dinene with the output of the second detector 17, the output of which is connected to the second input of the second comparison unit 19, connected in series by an analog voltmeter 21, a logarithm block 22, a multiplication unit 23 and a digital voltmeter 24, the inputs of the analog voltmeter 21 are connected respectively to the output of the first and second analog blocks 16 and 20 of the memory, the third output of the control unit 12 is connected to the control input of the meter 8 time intervals, the fourth output of the control unit 12 is connected to the second input of the multiplication unit 23, its fifth output - with the control input of the digital voltmeter 24, the second output of the logarithmic unit 22 is connected to the second input of the digital voltmeter 24, the output of the meter 8 time slots is connected to the input of the digital memory unit 9, the first output of the digital voltmeter 24 is connected to the second input of the digital memory unit 9 , the second output of the digital voltmeter 24 is connected to the first input of the information output unit 10, the output of the digital memory unit 9 is connected to the second input of the information output unit 10, the output of the multiplication unit 23 to the third input of the information output unit 10, input vShhod synchronization and synchronization control unit 12 are connected to respective inputs and outputs of channel control units 2 and 3 doses.

The device works as follows.

Electro-acoustic transducers are arbitrarily mounted on the controlled product, the location of the acoustic emission source being determined by the intersection of the circles with the centers at the transducer installation points and radii equal to the calculated distances from them to the signal source. Two harmonics of different frequencies are extracted from the signal recorded by the electroacoustic converter 4 and transmitted through the amplifier 5 using the first and second filters 6 and 7, the propagation rates of which and the attenuation in the material of the product are different. Distance I from acoustic emission source

before the electroacoustic converter is written with the expression:

Vi

 In

U,

where Ut and U2 are the amplitudes of the harmonic signal of the lowest and highest frequencies, respectively.

The absence of sound dispersion in a liquid at frequencies up to 2 MHz is used in the device to determine the signal propagation path, which can propagate both across the surface of the material being monitored (useful signal) and through the fluid filling the product, for example, made in the form of a high-pressure vessel. pressure. For this purpose, it makes measurements of time intervals.

The first filter 6 is allocated a low-frequency component (500 kHz), the second filter 7. - high frequency (800 kHz). The first and second detectors 13 and 17 highlight the harmonic envelope of the signal. Further, the amplitude of the harmonic components envelopes is stored in the first and second analog blocks 16 and 20 of memory. This information is then fed to the inputs of the analog voltmeter 21, which measures the ratio of the amplitudes of the envelopes of the harmonic components of the signal. This amplitude ratio is logarithmic in logarithm block 22 and goes to multiplication unit 23 if the device is in operation mode and to the digital voltmeter 24 when calibrating the device. In the operating mode, the information from the logarithm block 22 is supplied to the multiplication unit 23. The proportionality coefficient determined in the calibration mode is set in multiplication unit 23 via control unit 12. The voltage at the output of the multiplication unit 23 is measured by a digital voltmeter 24 and through the information output unit 10 is outputted to a digital indicator of the device. The same distance information from the source to the converter is recorded in the digital block 9 of the memory, which makes it possible to repeatedly reproduce it after the end of the measurements.

The time intervals are measured as follows.

From the outputs of the detectors 13 and 17, the envelopes of the harmonic components of the signal are fed to the outputs of the differentiating units 14 and 18 and the units 15 and 19 of the comparison. Comparison units 15 and 19 generate pulses at the moment of equality at their inputs of instantaneous values of the envelope voltage and its differentiated signal. These pulses determine the instant of arrival of signals to the electro-acoustic transducer 4. The pulses from the outputs

The comparison units 15 and 19 arrive at an 8 time interval meter, where they measure their time difference.

Thus, this device allows to increase the reliability of control

by introducing new units that measure the distance to the source of acoustic emission signals from the attenuation of various harmonic components, and determine the real path of signal propagation.

Claims (1)

DEVICE FOR ACOUSTIC EMISSION CONTROL OF MATERIALS, containing at least three signal reception channels, each of which consists of a series-connected electro-acoustic transducer and amplifier, first and second filters, the inputs of which are connected to the output of the amplifier, time interval meter, digital memory unit, information output unit connected in series and connected to the output of the amplifier of the control unit and the control unit, the first output of which is connected to the control input of the digital unit p mint, the second with a control input of the information output unit, characterized in that, in order to increase reliability, each signal receiving channel is equipped with a first detector, a first differentiating unit and a first comparison unit, connected in series and connected between the first filter and the first input of the time interval meter, the first analog memory unit, the input of which is connected to the output of the first detector, the output of the first detector is connected to the second input of the first comparison unit, connected in series and connected between the second filter and the second input of the time interval meter, the second detector, the second differentiating unit and the second · comparison unit, the second analog memory unit, the input of which is connected to the output of the second detector, the output of the second detector is connected to the second input of the second comparison unit, connected in series with an analog voltmeter , a logarithmic unit, a multiplication unit and a digital voltmeter, the inputs of the analog voltmeter are connected respectively to the output of the first and second analog blocks memory, the third output of the control unit is connected to the control input of the time interval meter, the fourth output of the control unit is connected to the second input of the multiplication unit, its fifth output is to the control input of the digital voltmeter, the second output of the logarithm unit is connected to the second input of the digital voltmeter, the output of the time interval meter is connected to the input of the digital memory unit, the first output of the digital voltmeter is connected to the second input of the digital memory unit, the second output of the digital voltmeter is connected to the first input of the bl information output window, the output of the digital memory unit with the second input of the information output unit, the output of the multiplication unit with the third input of the information output unit, the synchronization input and the synchronization output of the control unit are connected to the corresponding outputs and inputs of the control units of the remaining reception channels.