SU989471A1 - Device for acoustic emission checking device - Google Patents

Description

(54) DEVICE FOR LEAKY EQUIPMENT

CONTROL

Claims (2)

The invention relates to non-destructive testing and can be used in monitoring the state of objects. A device for quality control of products using acoustic emission is known, which contains a preamplifier converter, a main amplifier, a peak detector, an intensity meter, and an agglobee discriminator driver 1 13. The closest in technical essence to the invention is a device for acoustic emission konorol, containing a series-connected transducer, amplifier, frequency selection unit ,. threshold normalizing amplifier and pulse counter G 2 T. The disadvantage of these devices is that the reliability and speed of monitoring is low, due to the inability to judge directly from the measured parameters about the danger of developing a defect in an object. The purpose of the invention is to increase the reliability and speed of monitoring. This goal is achieved through. that the device for acoustic emission monitoring, containing serially connected transducer, amplifier, frequency selection unit, threshold normalizing amplifier and pulse counter, is supplied connected to the pulse counter inlet by serially connected memory unit, the first shaper of the threshold level, the first compiler and the unit shshi , sequentially connected by the second driver, the threshold level and the second comparator, as well as the timer, the first timer output is connected to the second inputs The pulse generator and the memory unit, the second timer output is connected to the input of the second threshold level generator, the output of the pulse counter is connected to the second inputs of the first and second comparators, the memory block output is connected to the second input of the second threshold level generator, the first input of which is connected the second input of the first shaper of the threshold level, and the output of the second comparator is connected with the second input of the control unit. The drawing shows the block diagram of the device. The device contains a serially connected converter 1, an amplifier 2, a frequency selection block 3, a norm normalizing amplifier 4, counting 5 pulses, a memory block 6, a driver 7 of the threshold level of the catastrophe state of the object, the first comparator 8 and block 9 of the indicator connected in series the shaper 10 of the threshold level of the channel definition of the critical condition of the object, connected by the first input to the output of memory block 6, and the second comparator 11 connected by its second input to the output of the counter Single pulses 5, and outputs - to the input of block 9 ivdikashsh, and a timer 12 coupled to schetchshshm impulgzsov 5, the memory unit 6, and E 7 and shaper 10, The apparatus operates as follows. Transducer 1 receives and converts acoustic emission signals in an electrical signal, which are amplified by amplifier 2 and fed to frequency selector 3, where the signals are filtered, based on the noise immunity conditions. From the output of the frequency selection block 3, signals are sent to the threshold normalizing amplifier 4, where they are amplified, subjected to algorithmic discrimination by comparison with the threshold level and normalized in duration and amplitude. The normalized signals, from the output of the threshold normalizing amplifier 4, arrive at the counter of 5 pulses, where their number is counted over a period of time, the value of which is determined by the required averaging time and set by timer 12. By the signal of timer 12, the number of pulses recorded by counter 5 is written to the block 6 memories, where it is shifted to D-fe and fed to shapers of 7 and 10 porcip levels. The same number is fed to the inputs of digital comparators 8 and 11. In the 4 Upper 10 threshold level channel determines the mode of the critical emission of acoustic emission signals, the number coming from memory 6 is raised to the power and the result is fed to the second input i4 of the second comparator 11 and fixed until the next threshold level is formed. The output signals from timer 12 are the synchronizing signals for memory block 6 and for drivers 7 and 10 threshold levels. Thus, in the second comparator 11, the number corresponding to the time interval is compared with the threshold level cell formed from the number corresponding to the time interval D, b. When the number of acoustic emission pulses exceeds the number of threshold levels generated by the number of acoustic emission pulses during the time interval D bf.-i, the output of the second comparator 11 generates a pulse that goes to the display unit 9, where the fact is displayed the onset of a critically active mode of emission of acoustic emission signals characterizing the active development of a defect. The channel for determining the mode of catastrophic radiation of acoustic emission signals, which includes the driver 7 of the threshold level, the first comparator 8 and the display unit 9, works in a similar way, but in the driver 7 of the threshold level, the number received from the block. 6 memories are raised to the power of | 3. Thus, the proposed device for high emission control allows determining the degree of danger of developing defects, which increases the reliability of control and allows to automate technological processes, therefore, increases the reliability of control. Claims. A device for acoustic emission monitoring containing a transducer connected in series, an amplifier, a frequency selection unit, a threshold normalizing amplifier, and a tachometer counter, characterized in that, for the purpose of accuracy and operational control, it is equipped with impulses connected to the output of the pulse counter connected by an m block, a first threshold level former, a first comparator and a shadicadia unit, successively connected by a second threshold level generator - 5SS n and a comparator as well as a timer; the first timer output is connected to the second inputs of the pulse counter and the memory unit; the second timer output is connected to the input of the second threshold level generator; the output of the pulse counter is connected to the second inputs of the first and second comparators; connected to the second input of the second threshold level generator, the first input of which is connected to the second input of the first generator of the threshold 1 and the output of the second level level, connected to the second input of the induction unit. Sources of information (mashga taken into account during the examination 1, Sinnikov V. A., Drobot Yu. B. Akusticheskaya. M., Iai-vr standards, 1976, p. 91, 2. Acoustic e Missy and its application for the unambiguous control in nuclear power engineering. Under the d. K. B, Vakara, M., Avtoizdat, 1980, with L14. (prototype).