SU1587437A1 - Ultrasonic echo-pulse flaw detector - Google Patents

Description

The invention relates to ultrasonic inspection and can be used to record the stages of the accumulation of fatigue damage of cyclically loaded parts.

The purpose of the invention is to increase the accuracy of recording stages of the accumulation of fatigue damage to the material of a cyclically loaded part by measuring not only the sign, but also the difference between the active durations of the echo signals.

In FIG. 1 shows a block-cxet + a ultrasonic pulse echo detector; figure 2 - plot voltage, explaining the principle of operation of the flaw detector.

An ultrasonic echo-pulse flaw detector contains a serially connected synchronizer 1, a probe pulse generator 2, an ultrasonic combined transducer 3, an amplifier-detector 4, a time selector 5 ^; and a normalizer 6, a driver 7 of the selecting pulses, the output of which is connected to the second input of the temporary selector 5, the load level sensor 8 connected in series, the first element 9 is cf. the first multivibrator 10, the first trigger 11, the first coincidence element 12, the first counter 13, the second comparison element 14, register 15 and indicator 16, sequentially connected

1587437 A1 is a reference voltage source 17, a third comparison element 18 and a second multivibrator 19, the output of which is connected to the second input of the first trigger 11 and to the first input of the synchronizer 1, the counting pulse generator 20 'connected in series, the second coincidence element 21 and the second counter 22, the output of which is connected to the second input of the second comparison element 14, the third coincidence element 23 and the one-shot 24 connected in series, the output of which is connected to the installation input of the register 15, the second output of the reference source 17 voltage is connected to the second input of the first comparison element 9, the second input of the third comparison element 18 is connected to the output of the load level sensor 8, the output of the normalizer 6 is connected to the second inputs of the first and second coincidence elements 12 and 21 and to the first input of the third coincidence element 23, the second the input of which is connected to the second output of the trigger 11 and combined with the third input of the second coincidence element 21, the output of the counter pulse generator 20 is connected to the third input of the first coincidence element 12, the output of the first multivibrator 10 is connected reset with the inputs Reset the first and second counters 13 and 22 and with the second input of the synchronizer 1, connected by the second output to the input of the selector pulse generator 7, serially connected to the second register 25, adder 26, logic element EXCLUSIVE OR 27, third register 28, read-only memory 29 and a second indicator 30, serially connected to a clock 31 and a first pairing circuit 32, the output of which is connected to a second input of a second indicator 30, serially connected to a second pairing circuit 33 and a third indicator 34, the fourth register 35, the output of which is connected to the second input of the adder 26, the first information input of the fourth register 35 is connected to the output of the second counter 22, and the second synchronization input of the fourth register 35 is connected to the output of the second multivibrator 10, the first information input of the second register 25 is connected with the output of the first counter 13, the second synchronization input - with the output of the first multivibrator 10, the second input of the EXCLUSIVE OR element 27 is connected to the output of the second comparison element 14, the second synchronization input of the third regis ra 28 connected to the output of the monostable 24, the output clock generator 31 is connected to the second input of the ROM memory 29, a second input interface circuit is connected to the second output of the clock generator 31 and the second input of the third indicator coupled to an output-only memory 29.

The diagram (figure 1) also indicates a cantilevered test piece 36 experiencing cyclic loading.

Flaw detector works as follows.

During the cyclic loading of the product, the load level sensor 8 converts the load into the voltage represented by diagram 37 (FIG. 2), which is supplied to the comparison elements 9 and 18, when this voltage exceeds the levels of U ₁ and U _z set by the reference voltage source 17 and supplied respectively to the second inputs of the first 9 and third 18 comparison elements, the multivibrators 10 and 19 are started. The clock pulses at the output of the multivibrator 10 are represented by diagram 38, and the clock pulses from the output of the multivibrator 19 are represented by diagram 39.

With each arrival of the clock pulses, the synchronizer 1 starts the generator at the same time. 2 probing pulses and shaper 7 selective pulses. Then, the transducer 3 excites ultrasonic vibrations in the loaded part, receives echo pulses, which, after passing through the amplifier-detector 4, are fed to the input of the temporary selector 5, by which signals are reflected from the edge of the stress concentrator (from the edge of the groove in the sample in the zone of which fatigue damage accumulate). Echoes at the output of the temporary selector 5 are represented by plot 40. Using the normalizer 6, such echo signals are amplified and limited at a fixed level Uj (plot 40). From the output of the normalizer 6, amplified and: limited echo signals are input to the inputs of the matching elements 12, 21 and 23, The pulses at the output of the normalizer 6 are shown in diagram 41. The pulses from the first output of trigger 11, the duration of which corresponds to the loading time of the part within the cycle, are presented diagram 42, the pulses from the second output of trigger 1I — diagram 43. The pulses at the output of the single-shot 24 are represented by diagram 44. The counting pulses from the generator 20 are supplied to the output of the first coincidence element 12 at the coincidence time intervals of the pulses with the output yes normalizer 6 (plot 41) with pulses at the first output of the trigger. 11 (plot 42). The counting pulses at the output of the second coincidence element 21 appear in the time intervals of the coincidence of the pulses at the output of the normalizer 6 (plot 41) with pulses at the second output of the trigger 11 (plot 43). The signals at the output of the first coincidence element 12 are represented by diagram 45, and the output of the second coincidence element 21 is represented by diagram 46.

From the outputs of the counters 13 and 22, information in the form of a binary eight-bit code is fed to the input of the second comparison element 14 for the subsequent indication of the sign of the difference of the active-. the duration of the echo signals on the first indicator 16. Additionally, from the outputs of the counters 13 and 22, this information is fed to the information inputs of the second register 25 and the fourth register 35 for the subsequent calculation and indication of the absolute value of the difference between the active durations of the echo signals (4ί.).

Indication of the sign-difference of the active durations of the echo signals is as follows. The second comparison element 14 compares two eight-bit binary numbers whose values correspond to the active durations of the two echo signals received within the load cycle of the part. At the same time, a signal> or corresponding to the sign of the difference in active durations is formed at its output. From the output of element 14, the binary code of the sign is recorded in register 15 at the moment of arrival of the pulse from the output of the one-shot. 24 (diagram 44), then the sign of the indicated difference is fixed by indicator 16.

Calculation and indication of the absolute value of the difference between the active durations of the echo signals is carried out as follows. Information on the value from ¹ ,; at the moment of arrival of pulses from the multivibrator 10, and in the register 35, about the value of c; at the moment of arrival of pulses from the multivibrator 19 (diagrams 45 and 46). From the output of the register 25 to the input of the adder 26, the information comes in a direct code, and from the output of the register 35 to the second input of the adder 26 - in the reverse code. As a result, in the adder 26, the difference between the active durations of the two echo signals is calculated, which, in the form of a direct or inverse binary code, is fed to the input of the logic element 27 controlled by the signal from the output of the comparison element 14. At the output of the logic element 27, a binary code of the absolute value of the quantity is generated.

The specified information is recorded in register 28 at the moment of arrival of the pulse from the output of one-shot 24 (plot 44) and is recorded using a circuit consisting of elements: read-only memory 29, two seven-segment indicators 30 and 34, clock 31, two pairing circuits 32 and 33 . The device 29 has a program for translating a binary code of a number into a seven-segment code. .

Indication of the absolute value of ZJ? | carried out as follows. The binary code of the number coming from the output of the register 28 to the input of the permanent storage device 29, as well as the pulses from the output of the clock generator 31 form the address of the memory cell. Moreover, upon receipt of a logical 0 pulse from the output of the clock generator 31, the memory cell address of the seven-segment indicator 30 is formed, and when a logical pulse arrives, the address of the indicator memory cell 34 is formed. The pairing circuits 32 and 33, depending on the state of the outputs of the clock generator 31, switch the cathodes of the corresponding indicators 30 and 34. As a result, the indicators 30 and 34 record the absolute value of the value within each cycle of loading the part.

At the first stage (incubation) in the material of the part there are practically no structural damage, respectively, the value of d ^ i is constant and has a positive sign (Fig. 2, a). .

When the metal exhausts its plastic possibilities in the local deformed zone and the formation of a number of disparate micro-discontinuities in it (shear lines intersecting the grain boundaries of the polycrystalline material), di \ becomes zero (Fig. 2,6), and then negative (Fig. 2, ) In this case, the indicator 16 signals a change in the sign of the quantity from positive to negative, which corresponds to the beginning of the second stage - the stage of prefracture of the material.

As the density of disparate micro-discontinuities and the depth of their propagation in the material increase, the absolute value of d begins to increase with ¹ ·, which is recorded by indicators 30 and 34. In this case, the sign of the measured quantity is negative, which is recorded by indicator 16. The operating time of the product is, within which di ; grows from zero to maximum in the negative range of values, corresponds to the second stage.

The maximum negative value of Zli; recorded by the indicators 16.30 and 34 corresponds to the formation of a number of scattered microcracks in the plastically deformed zone of the metal.

Further operating time leads to an increase in the degree of structural changes, accompanied by an increase in the size and number of microcracks. At this (third) stage, the negative value of /) (? Decreases from the maximum value to zero, which is recorded by indicators 30 and 34.

At the subsequent (fourth) stage, microcracks merge into a macrocrack. At the same time, indicators 16 ^ 30 and 34 record the growth of a positive value of d J.

Thus, the proposed flaw detector allows you to distinguish four stages of the accumulation of fatigue damage to the material. If the value of de is positive and does not change with an increase in the number of loading cycles (N) of the part, then this corresponds to stage I (incubation); if the sign of the quantity d v is negative, and its absolute value increases with increasing number N, then stage II (stage of prefracture of the material); if the sign of Δ <? negative, and its absolute value decreases with an increase in the number of loading cycles of the investigated part — stage III (stage of microcrack development); if the sign of dP is positive, and its absolute value increases with. an increase in the number N is stage IV (the stage of macrocrack development).

The proposed flaw detector, in comparison with the known one, makes it possible to increase the accuracy of recording various stages of the accumulation of fatigue damage to a material, and it has been expanded. functionality. The proposed flaw detector additionally provides a circuit (elements 25-35) for calculating and indicating the absolute value of the difference between the active durations of the echo signals, measured within each loading cycle of the investigated part. This allows one to record with high accuracy the four stages of the accumulation of fatigue damage of the material in accordance with the specified methodology. At the same time, using a known flaw detector, it is impossible to distinguish stage II from stage III, since it only records the sign of di, which is negative within the indicated stages. The known flaw detector does not allow to distinguish stage I from stage IV, within which the value of di has a positive sign, and the hallmark of these stages is only the law of change in the absolute value of d? as a function of the number of loading cycles of the part. Therefore, the proposed technical solution allows to increase the accuracy of registration of various stages and has wider functionality.

Claims (1)

Claim An ultrasonic echo-pulse flaw detector containing a synchronizer, a probe pulse generator, an ultrasonic combined transducer, an amplifier detector, a time selector and a normalizer, a selector pulse generator, the output of which is connected to the second input of the temporary selector, the load level sensor is connected in series, the first comparison element , the first multivibrator, the first trigger, the first match element, the first counter, the second comparison element, register and indicator p, a series-connected reference voltage source, a third comparison element and a second multivibrator, the output of which is connected to the second input of the first trigger and to the first synchronizer input, series-connected pulse generator, a second coincidence element and a second counter, the output of which is connected to the second input of the second element comparisons, the third coincidence element and the one-shot connected in series, the output of which is connected to the installation input of the register, the second output of the reference voltage source The connection is connected to the second input of the first comparison element, the second input of the third comparison element is connected to the output of the load level sensor, the output of the normalizer is connected to the second inputs of the first and second matching elements and to the first input of the third matching element, the second input of which is connected to the second output of the trigger and combined with the third input of the second coincidence element, the output of the counter pulse generator is connected to the third input of the first coincidence element, the output of the first multivibrator is connected to the inputs the first and second counters and with the second input of the synchronizer connected to the input of the shaper of the selecting pulses by the second output, characterized in that, in order to increase the accuracy of recording the stages of accumulation of fatigue damage of the material of the cyclically loaded part, it is equipped with a second register, adder, logic connected in series an EXCLUSIVE OR element, a third register, read-only memory, and a second indicator sequentially connected by a connected clock and the first circuit interface, the output of which is connected to the second input of the second indicator, connected in series with the second interface circuit and the third ₂₀ indicators, the fourth register, the output of which is connected to the second input of the adder, the first information input of the fourth register is connected to the output of the second counter, and the second 25 the fourth register synchronization input - with the output of the second multivibrator, the first information input of the second register is connected to the output of the first counter, the second synchronization input - jq - with the output of the first multivibrator, the second input of the EXCLUSIVE OR element is connected to the output of the second comparison element, the second synchronization input of the third the register is connected to the output of a single vibrator, the output of the clock generator is connected to the second input of the permanent storage device, the input of the second interface circuit is connected to the second output of tovogo generator and the second input of the third indicator coupled to the output of the ROM memory. P · PFig. 2