RU2321849C2 - Method and device for calibration of acoustic emission converters - Google Patents

Abstract

FIELD: calibration of acoustic emission converters.

SUBSTANCE: system is subject to calibration due to optical interference linear shifts metering device. System has acoustic signal source and integral transmitting unit. Acoustic emission standard converter is brought in contact with monolith transmitting unit. Signal from acoustic emission converter is processed and memorized. Acoustic emission converter to be calibrated in put on place of standard one and second signal is recorded and processed in computer. Second signal is subject to comparison to standard one while doing calibration of acoustic transmission converter to be calibrated.

EFFECT: improved precision of calibration; widened functional abilities of system in total.

2 cl, 2 dwg

Description

The proposal relates to the field of measurement technology, and more specifically to metrological support for the calibration of acoustic emission transducers during their certification. It can also be used to conduct automatic non-destructive testing of products during the manufacture of other acoustic devices, linear displacement sensors, nanopositioners, and similar devices.

Known methods for calibrating acoustic emission transducers based on the use of laser interferometric nanoscale meters (see, for example, Laser interferometers to study the distribution of ultrasonic vibrations in various media. Avtometriya Journal, No. 3, 1999, pp. 109-114). In this case, the acoustic emission transducer itself is used as the active element of the interferometer, playing the role of a movable element (mirror) in the information channel of the interferometer-phase meter and is absolutely calibrated (in the offset-frequency coordinate space). However, this technical solution is characterized by piecewise operations with the calibration object and therefore cannot provide in-line calibration of many transducers, which does not meet the industrial requirements for system performance.

The closest prototype to the proposed technical solution is the method and device provided by US Standard "E076-94". They include the process of receiving from a single source two test acoustic signals by two acoustic emission transducers, standard and calibrated, with subsequent registration of the received signals and their comparison using a computer. Here, the device for calibrating acoustic emission transducers comprises an acoustic signal source, a monolithic transmitting unit, a block of analog-to-digital converters, a computer, as well as a calibrated acoustic emission transducer, the input of which is connected through a monolithic transmitting unit to an acoustic signal source, and the output through an analogue- digital converters - with computer input.

A disadvantage of the known technical solution is the low accuracy of the measurement processes during calibration, due to the instability of the characteristics of the acoustic signal source, and limited functionality when changing the type of acoustic emission transducer.

The aim of the proposal is to increase the accuracy of calibration and expand the functionality of the system as a whole.

This goal is achieved in that the test acoustic signal is periodically calibrated by optical interferometric means by measuring the time dependence of the absolute linear displacement, and the signal from the calibrated acoustic acoustic emission transducer is compared with the reference signal recorded from the standard acoustic emission transducer in measurements made earlier.

This goal is also achieved by the fact that the device further comprises an optical interference linear displacement meter, which is optically coupled to a monolithic transmitting unit, and a controlled generator, the control input of which is connected to the computer, and the output to the input of the acoustic wave emitter, and the acoustic wave emitter is made in in the form of a linear electro-acoustic transducer.

An optical interference linear displacement meter may include a laser connected in series with the signal, an optical modulator unit, an interferometer that is additionally optically coupled to a monolithic transmitting unit, and a photodetector connected to an analog-to-digital converter unit, and a difference frequency generator connected to the optical unit modulators and with a block of analog-to-digital converters.

The device may include a recording device connected to the output of the computer.

Figure 1 presents the prototype device according to US Standard "E076-94" (Fig. 1 of the US Standard is fully preserved here, where all the notations contained in the source document are given).

Figure 2 presents the proposed device for calibration of acoustic emission transducers.

Presented in figure 1 according to US Standard "E076-94" the device in the original symbols contains a monolithic transmitting unit A, which is contacted by an acoustic signal source made in the form of a destructible capillary B, pressed against a monolithic transmitting unit A by a screw D and a disk C. C drive D connects the amplifier E and the oscilloscope F. The standard acoustic emission transducer G and the calibrated acoustic emission transducer H are connected directly to the monolithic transmitting block A, and through analog-to-digital blocks -forming I - with a computer J.

Presented in figure 2, the proposed device contains an acoustic signal source 1, which is contacted by a monolithic transmitting unit 2. The block of analog-to-digital converters 3 is connected to a computer 4. An output of a calibrated acoustic emission transducer 5 is connected to the input of the block of analog-to-digital converters 3. the transmitting unit 2 and the block of analog-to-digital converters 3 are connected to an optical interference linear displacement meter 6, and between the output of the computer 4 and the input of the acoustic source 1, a controlled oscillator 7 is installed. An optical linear linear displacement meter 6 includes a laser 8, a block of optical modulators 9, an interferometer 10, which is additionally optically coupled to a monolithic transmitting block 2, and a photodetector 11 connected to an analog block -digital converters 3, as well as a differential frequency generator 12, connected to the block of optical modulators 9 and to the block of analog-to-digital converters 3. To the output of the computer 4 EHO recording device 13.

The proposed method for calibrating acoustic emission transducers involves three modes of operation of the device in three stages. They are implemented as follows. At the beginning of the work, when replacing the source of acoustic signal 1 or during periodic verification, first of all, using an optical interference linear displacement meter 6, the system is calibrated consisting of an acoustic signal source 1 and a monolithic transmitting unit 2. This is done as follows: acoustic signal source 1 is introduced in acoustic contact with a monolithic transmitting unit 2; by commands from the computer 4, the controlled generator 7 changes the frequency of the source of the acoustic signal 1 in a given range; using an optical interference linear displacement meter 6 in real time, the surface displacements are measured by a monolithic transmitting unit 2 and the source of acoustic signal 1 is calibrated. The linear displacement meter 6 is assembled according to a simplified scheme and works as follows. The optical signal from the laser 8, modulated by the block of optical modulators 9 with a differential frequency specified from the differential frequency generator 12, is fed to an interferometer 10, which is optically coupled to a monolithic transmitting unit 2, the photodetector 11 detects a signal whose phase shift relative to the reference signal from the differential frequency generator 12 is proportional to the linear displacement of the surface of the monolithic transmitting unit 2; the block of analog-to-digital converters 3 transmits this information to computer 4. If the characteristics of the system are normal, then the transition to the third stage of the device. In this case, a standard acoustic emission transducer 5 is introduced into the acoustic contact with the monolithic transmitting unit 2. Then, the signal from this acoustic emission transducer is processed and stored. At this second stage ends and the device is brought into operation. After installing the calibrated acoustic emission transducer 5 in place of the standard one, the second signal is recorded and processed in the computer, which is compared with the saved reference. Thus, a calibrated acoustic emission transducer is calibrated. This last stage can be performed in a flow manner many times with the same type of acoustic emission transducer, without changing the device settings before changing the type of transducer or when scheduled maintenance is due.

Thus, in comparison with the prototype device, the proposal significantly increases the accuracy of the calibration of acoustic emission transducers and expands the functionality of the entire measuring system as a whole, which leads to the achievement of the goal of the invention.

Claims (2)

1. A method of calibrating acoustic emission transducers, including the process of receiving a test acoustic signal from one source by two standard acoustic transducers, calibrated, followed by recording the received signals and comparing them using a computer, characterized in that using an optical interference linear displacement meter calibration of a system consisting of an acoustic signal source and a monolithic transmitting unit is performed, and then The first contact with the monolithic transmitting unit is introduced, the standard acoustic emission transducer is processed and the signal from this acoustic emission transducer is processed and stored, then the calibrated acoustic emission transducer is replaced with the standard one, the second signal is recorded and processed in the computer, which is compared with the stored reference one, thereby calibrating calibrated acoustic emission transducer. 2. A device for calibrating acoustic emission transducers, comprising an acoustic signal source, a monolithic transmitting unit, an analog-to-digital converters unit, a computer, and an acoustic emission transducer, the input of which is connected through a monolithic transmitting unit to an acoustic signal source, and the output through an analogue unit digital converters - with a computer input, characterized in that it further comprises an optical interference linear displacement meter having optical communication with a monolithic transmitting unit and connected to the block of analog-to-digital converters, a controlled generator, the control input of which is connected to a computer, and the output with the input of the acoustic wave emitter, and the acoustic wave emitter is made in the form of a linear electro-acoustic transducer.

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