RU2150698C1 - Multichannel acoustic emission device to test articles - Google Patents

Abstract

FIELD: nondestructive testing, strength tests of structures. SUBSTANCE: multichannel acoustic emission device to test articles includes 1...n units each including four measurement channels composed of acoustic converter, pre-amplifier, filter, peak detector whose output is connected to inverting input of comparator connected in series, digital-to-analog converter whose output is linked to noninverting input of comparator. Device also has channel switch, master amplifier, analog-to- digital converter, on-line storage whose output is connected to first input of interface connected in series. Four inputs of channel switch are connected to outputs of channel filters and inputs of peak detectors of corresponding channels and inputs of digital-to- analog converters of four channels of unit are tied together and are linked to first input of interface. Outputs of comparators of each channel are connected to inputs of timer whose output is linked to second input of storage. Second output of interface is connected to third input of timer and third output of it is linked to bus of computer. EFFECT: increased precision of determination of coordinates of developing flaws. 1 dwg

Description

 The invention relates to non-destructive testing and can be used in strength testing of structures.

A multi-channel acoustic emission device for monitoring products (A. S. N 1589204, M class ⁴ G 01 N 29/04, priority from 4.10.88), containing identical channels for receiving and processing acoustic emission signals, each of which is known consists of a series-connected piezoelectric acoustic transducer, preamplifier, filter, main amplifier, the output of which is connected to a peak detector and a gate driver, as well as a digital-to-analog converter and a recorder. In addition, in each channel, the device contains a comparator, a memory element, as well as a generator, a counter, a memory unit connected in series, and in each channel, the output of the peak detector is connected to the inverting input of the comparator, the output of the gate driver is connected to the gate input of the comparator, the output of which is connected to a peak detector reset input and a memory element input of each channel. The output of the memory element of each channel is connected to the corresponding input of the switch. The memory block has a mode-setting input, and its second input is connected to the counter output and the second inputs of the gate former of the memory element of each channel. The output of the memory block is connected to the input of the digital-to-analog converter, the output of which is connected to the non-inverting inputs of the comparators of each channel. The output of the switch is connected to the input of the recorder. The output of the OR element of the gate driver is connected to the first input of the AND element and the first input of the second AND element, the second input of the first AND element is connected to the output of the third AND element, and the output of the first AND element to the input of the first trigger whose non-inverting output is connected to the second input of the second element And with the output of the driver, and the inverting output is connected to the second input of the third element I. The output of the amplifier is connected to the input of the comparator, the input of which is connected to the input of the delay element. The output of the latter is connected to the S-input of the second trigger, the output of which is connected to the first input of the third element I. The reset inputs of the first and second triggers are combined and connected to the output of the second element I.

 The disadvantage of this device is that it does not allow you to determine the arrival times of acoustic emission signals to the measuring channels, which means that it cannot determine the coordinates of the sources of acoustic emission with high accuracy.

 The closest in technical essence is a multichannel acoustic emission device for product monitoring (positive decision on application N 95111759/28 (020070) from 05/19/97, priority from 6/07/95), containing measuring channels from a series-connected acoustic transducer , a pre-amplifier, a filter, a main amplifier, a peak detector and a comparator, a generator, a counter and a memory unit, as well as a channel switcher, a memory element, the first input of which is connected to the output of the counter, connected in series and the second input - with the output of the channel switch, a digital-to-analog converter, the output of which is connected to the second inputs of the comparators, and a registrar. In addition, it is equipped with a second memory unit, the input of which is connected to the counter output, with a switch, the first input of which is connected to the output of the first memory unit, the second input - with the output of the second memory unit, and the output - with the input of the digital-to-analog converter of the control unit, the input of which is connected with the output of the channel switch, and the first output with the control input of the channel switch, a delay element, the input of which is connected to the second output of the control unit and with the control input of the switch, and the output is with reset inputs of the peak projectors channels and a timer, the input of which is combined with the inputs of memory blocks, and the output - is connected to the third input of the storage element and the output of the memory element is connected to the input of the recorder.

The disadvantage of this device is that it allows only serial polling of the measuring channels. The polling time of one channel when the device is working with a computer such as IBM PC / AT 486 is about 1.4 • 10 ^-6 s. The polling cycle of a 16-channel acoustic emission device is τ ₁ = 16 • 1.4 • 10 ^-6 = 22.4 • 10 ^-6 . Since the channels are polled sequentially, the information of the channels not polled is lost, which significantly reduces the accuracy characteristics of the system.

 When developing a multi-channel acoustic emission device for product monitoring, the task was to increase the accuracy of determining the coordinates of developing defects.

 The problem is solved due to the fact that the multi-channel acoustic emission device for monitoring products consists of 1 ... n blocks, each of which contains four measuring channels, consisting of a series-connected acoustic transducer, pre-amplifier, filter, peak detector, the output of which connected to the inverting input of the comparator, and also contains a digital-to-analog converter, the output of which is connected to the non-inverting input of the comparator, as well as a channel switch, the main amplifier litel, analog-to-digital converter, random access memory and timer. The device is connected in series with a switch, a main amplifier, an analog-to-digital converter, and random access memory, the output of which is connected to the first input of the interface device. Moreover, the four inputs of the switch are connected to the outputs of the channel filters and the inputs of the peak detectors of the corresponding channels, and the inputs of the digital-to-analog converters of the four channels of the unit are combined and connected to the first output of the interface device. The outputs of the comparators of each channel are connected to the inputs of the timer, the output of which is connected to the second input of random access memory. The second output of the interface device is connected to the third input of the timer, and the third output of the interface device is connected to the computer bus.

The proposed device in comparison with existing acoustic emission devices can significantly reduce hardware costs with a significant increase in metrological characteristics. Information from each channel is digitized. Moreover, in each block, the switch sequentially polls only four channels, i.e. the polling time of the four channels of one block will be: τ ₂ = 0.2 • 10 ^-6 • 4 = 0.8 • 10 ^-6 s. In the prototype (positive decision on the application N 95111759 / (020070) from 05/19/97, priority from 07/06/95), the switch interrogates sequentially all N channels of the system. So, if the system is 16-channel, then the polling time will be τ ₁ == 16 • 1.4 • 10 ^-6 = 22.4 • 10 ^-6 , that is, a gain in the accuracy of determining the difference in the arrival times of AE signals, and therefore, the coordinates of the sources of AE will be:
N = 22.4 • 10 ^-6 / 0.8 • 10 ^-6 = 28 times.

The drawing shows a functional diagram of a multi-channel acoustic emission device for monitoring products. A multichannel acoustic emission device for monitoring products contains:
1 ... n - blocks for receiving and processing measurement information;
1. . . 4 - measuring channels for receiving and processing acoustic emission signals in a block;
2 - acoustic transducer;
3 - pre-amplifier;
4 - filter;
5 - peak detector;
6 - comparator;
7 - digital-to-analog converter;
8 - switch;
9 - the main amplifier;
10 - analog-to-digital Converter;
11 - timer;
12 - random access memory;
13 - device pairing
14 - computer bus.

 A multi-channel acoustic emission device for monitoring products, consisting of 1 ... n blocks, each of which contains four measuring channels, consisting of a series-connected acoustic transducer 2, pre-amplifier 3, filter 4, peak detector 5, the output of which is connected to an inverting the input of the comparator 6, and also contains a digital-to-analog converter 7, the output of which is connected to the non-inverting input of the comparator 6, as well as a channel switch 8, the main amplifier 9, an analog-to-digital converter a timer 10, a timer 11 and a random access memory 12. In the device, a switch 8, a main amplifier 9, an analog-to-digital converter 10, a random access memory 12, the output of which is connected to the first input of the coupler 13 are connected in series. Moreover, the four inputs of the switch 8 are connected to filter outputs of 4 channels and peak detector inputs of 5 corresponding channels. The inputs of the digital-analog converters 7 of the four channels of the unit are combined and connected to the first output of the interface device 13. The outputs of the comparators of each channel are connected to the inputs of the timer 11, the output of which is connected to the second input of the RAM 12. The second output of the interface device 13 is connected to the third input of the timer 11, and the third output of the interface device 13 is connected to the bus of the computer 14.

The practical implementation of the proposed device is carried out according to well-known circuits using domestic (AD9220 analog-to-digital converters. UM 62256 memory) microcircuits, the main characteristics of which are described in the following books:
1. Shilo V.L. Popular digital circuits. - M .: Radio and communications, 1987, p. 19.

 2. Microcircuits for analog-to-digital conversion and multimedia. - M .: DODEKA, 1996, no. 1, p. 214.

 Preliminary and normalizing amplifiers are made on operational amplifiers of type K544UD2. As piezoelectric transducers 2, microvolume piezoelectric transducers made of ceramics of the TsTS-19 type are used. Comparator 6 is assembled on 554CAZ integrated circuits (A. Bulychev, V. A. Prokhorenko. Analog integrated circuits. Reference. - Minsk: Beloruss, 1994, p.208 - 210.) Channel 8 switch is made on 555, 1533 series microcircuits, 590KN8. The digital-to-analog converter 7 is made on a 572PA1 chip (Analog and digital integrated circuits. Reference manual. Edited by S.V. Yakubovsky. - M.: Radio and communications, 1984).

 The device operates as follows.

 A device whose functional diagram is shown in FIG. 1, is made in parallel-serial principle and contains N four-channel blocks. Moreover, each block is a functionally complete four-channel system, structurally made in the form of a board, which is inserted into the ISA bus of an IBM PC / AT-type computer.

Work in the mode of receiving AE signals is as follows. Before starting work, the values of the threshold voltages U _pores , which are set above the hardware and acoustic noise in this channel, are recorded in the registers of the digital-to-analog converter 7. Then the timer 11 is programmed, the cutoff times for receiving AE signals, the number of measurements performed by the analog-to-digital converter 10 are recorded. In this case, the comparators 6 are reset to the initial state, the address counter of the random access memory 12 is enabled. The acoustic emission signals are transmitted to the piezoelectric transducers 2 and converted them into electrical signals. Next, the acoustic signal is amplified by a pre-amplifier 3, passes through a filter 4 and is fed to the input of a peak detector 5, which selects the envelope of the acoustic emission signal and remembers the amplitude of the signal. The output signal of the peak detector 5 is fed to the inverting input of the comparator 6. The threshold level U _then is set to the non-inverting input of the comparator 6 from the output of the digital-analog converter 7, which is set by command from the interface device 13 and must exceed the hardware and acoustic noise of this channel. When the signal from the output of the peak detector 5 exceeds the detection threshold level of the corresponding channel, the comparator 6 is activated and the timer 11 starts to count down the arrival time of the AE signal. Comparators 6 of the remaining channels are triggered when the AE signals exceed their threshold values and record the arrival times of the signals in timer 11. At the end of the cut-off time, timer 11 generates an interrupt signal, by which the processor reads the values of the arrival times of AE signals. At the same time, the switch 8 sequentially polls all the channels (1 ... 4) of this block N _i . In this case, the AE signal of this channel from the output of the filter 4 through the switch 8 is fed to the input of the main amplifier 9, amplified and passed to the input of the analog-to-digital converter 10. The analog-to-digital converter 10 measures the levels of the AE signals of all (1 ... 4) channels of this block N _i and the measurement results are recorded in the buffer random access memory 12. At the end of the AE signal from the output of the timer 11, a signal is sent to stop the counter of random access memory 12. In this case, the recording of information ends, and the processor The computer can read information about the history and shape of the AE signal from the buffer memory 12. The comparator 6 determines the readiness for the next AE signal. As soon as the signal levels are below the threshold, the processor will reset the device.

Claims (1)

 A multi-channel acoustic emission device for monitoring products, consisting of 1 ... n blocks, each of which contains four measuring channels, consisting of a series-connected acoustic transducer, pre-amplifier, filter, peak detector, the output of which is connected to the inverting input of the comparator, and also contains a digital-to-analog converter, the output of which is connected to the non-inverting input of the comparator, as well as a channel switch, a main amplifier, an analog-to-digital converter, a portable memory device and a timer, characterized in that the device is connected in series with a channel switch, a main amplifier, an analog-to-digital converter, random access memory, the output of which is connected to the first input of the interface device, and the four inputs of the channel switch are connected to the outputs of the channel filters and inputs peak detectors of the corresponding channels, and the inputs of the digital-to-analog converters of the four channels of the unit are combined and connected to the first output of the device Ia, the outputs of the comparators of each channel are connected to inputs of a timer whose output is connected to a second input of the random access memory, the second output coupling device is connected to the third input of the timer, and the third output interface device connected to the bus of the computer.