RU2357242C1 - Automatic defect signalling device for ultrasonic detector - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: automatic defect signaling device for ultrasonic detector contains the peak selector, actuator, synchroniser connected, via the tested zone strobe-pulse front edge shaper, with the trigger first input, the output of the latter being connected with the counter reset input and, via the clock pulse generator, with the counter input and shift register clock input. The shift register output is connected to logic element "AND", while the counter output is connected to the trigger second input. Note that the proposed device additionally incorporates the one-shot multivibrator arranged between the peak selector output and shift register write input, (n-1) m of input logic elements "AND" with their inputs connected to the registers outputs, while outputs of all n logic elements "AND" are connected to logic element "OR", its output being connected to the actuator input.

EFFECT: higher noise immunity and reliability of proposed device of defects, hence, reduced number of its false operations.

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Description

The invention relates to devices for ultrasonic flaw detection. The primary area of use is automated systems for ultrasonic testing of products of the metallurgical and engineering industries.

Known automatic signaling device for defects to an ultrasonic flaw detector according to copyright certificate SU No. 278149, IPC G01N 29/04, containing a logic element “I”, an actuator connected to its output, a primary trigger, a counter, a second trigger and a synchronizer connected in series.

The reasons that impede the achievement of the technical result are the low noise immunity of the signaling device, due to the fact that it responds to random interference signals that coincide in time with the strobe pulse of the control zone and are located in different parts of the control zone in different location cycles.

Signs that coincide with the claimed object - synchronizer, trigger, counter, logical element "I", actuator.

Also known is an automatic signaling device of defects to an ultrasonic flaw detector according to copyright certificate SU No. 371504, IPC G01N 29/04, comprising an amplitude selector, a synchronizer, a clock pulse generator, series-connected shift registers, a logical element “I”, an actuator and a pulse counter.

The reasons that impede the achievement of the technical result are the low noise immunity of the signaling device with a small number of impulses from defects.

Signs that coincide with the claimed object are an amplitude selector, a clock pulse generator, a shift register, an AND logic element, a pulse counter, and an actuator.

From a number of these shortcomings, an automatic defect detector for an ultrasonic flaw detector is free according to the copyright certificate SU No. 534689, IPC G01N 29/04, which has the largest number of matching features with the claimed object and contains a synchronizer, an amplitude selector, an “I” circuit, an actuator, a shift register, driver of the leading edge of the strobe pulse of the control zone, trigger, clock generator and counter. The output of the amplitude selector is connected to the input of the And circuit and the write output of the shift register, the output of which is connected to the second input of the And circuit, and its output is connected to the actuator; the input of the leading edge of the strobe of the control zone is connected to the synchronizer, and the output is to the input of the trigger, the output of which is connected to the reset input of the counter, and also through the clock generator with the clock input of the register and the counting input of the counter, the output of which is connected to the second input of the trigger .

The capacity of the counter is chosen so that a pulse at its output appears when the number of pulses at its input is equal to the number of cells in the shift register. The repetition period of the signals generated by the clock must be no less than the ratio of the maximum duration of the strobe to the number of cells in the shift register. From the input of the receiving path of the flaw detector, a sequence of video pulses is fed to the input of the amplitude selector, where they are limited to a minimum and reduced to digital form. From the output of the amplitude selector, the video pulses are fed to the input of the And circuit and to the input of the shift register record. The leading edge of the strobe of the control zone is triggered by a clock coming from the output of the synchronizer, it generates a pulse signal supplied to one of the inputs of the trigger, and switches it so that a signal appears at its output with a level that allows the clock and counter to work.

The sequence of clock pulses from the output of the clock goes to the clock input of the n-bit cyclic shift register and shifts the information received at the input of the register record. In addition, the clock pulses are fed to the counter input of the counter, counted by it, and after n pulses, a pulse is generated at the counter output and fed to the second trigger input so that a signal appears at its output with a level that prohibits the operation of the clock pulse generator and resets counter to zero.

Thus, the information received at the input of the register record, at the end of the effect of clock pulses in each period, is shifted by the number of cells equal to the number n of clock pulses received at the clock input of the shift register. For example, if a video pulse is output from the amplitude selector output to the input of the shift register record immediately after the leading edge of the strobe pulse of the control zone, then after the end of the clock pulses this information will be recorded in the last cell of the shift register and will go to the input of the “AND” circuit. In the next cycle of locating, the echo pulse from the defect will also appear immediately after the leading edge of the strobe pulse of the control zone, as a result of which signals with a high logic level will arrive at the two inputs of the “I” circuit and a signal with a high logical level will appear at the output of the “I” circuit which will trigger the actuator. Thus, the strobe-pulse of the control zone is divided into n parts with a duration equal to the period of the clock pulses. The presence of a defect is judged by the temporal coincidence of the signals for two periods of the following cycles of location in the corresponding parts of the strobe pulse. The probability of occurrence of interference in the same part of the strobe pulse of the control zone in this defect detector is halved compared to the detector that makes a decision about the presence of a defect in one location cycle. However, this device does not use all the possibilities of increasing noise immunity that can be implemented for most ultrasonic monitoring devices.

So, for example, when monitoring some products with an ultrasonic transducer with a diameter of 12 mm, moving at a speed of 1 cm / s and with a frequency of location cycles equal to 1 kHz, we get that the echo pulses from the defect located in the control zone under the transducer will be accepted in a row in a hundred cycles of location. When moving the transducer at a speed of 1.2 m / s, echo pulses will be received in ten cycles of location.

In the device under consideration, decision-making is carried out in only two adjacent cycles of location, therefore, with an interference duration of more than one location cycle, false positives of the considered automatic defect detector occur.

In addition, the shift register in this device works cyclically (with rewriting information), therefore, after several cycles of location, its cells will be filled and false alarms will occur. If, however, the shift register is cleared, for example, after every K cycles of location, then the next location cycle after cleaning the register will be preparatory when the information is written to the shift register, and only the next one will be working when the ASD system can be triggered. The shift and recording of information in the shift register is possible only with a temporary coincidence of echo signals and clock pulses. And since the duration of the echo signals is usually less than the period of the clock pulses, it is possible to skip the echo signals, which also reduces the reliability of the ASD system.

The reasons that impede the achievement of the technical result are the low noise immunity and reliability of this automatic defect detector.

Signs that coincide with the claimed object are an amplitude selector, an “I” circuit, an actuator, a shift register, a leading edge of a strobe pulse of a control zone, a trigger, a clock generator, a counter, a synchronizer.

The objective of the invention is to increase the noise immunity and reliability of an automatic defect detector.

The technical result of the invention is to eliminate the false positives of the automatic defect detector when exposed to interference with a duration greater than the period of the location cycle, eliminating possible omissions of defects.

The technical result is achieved in that in a device containing an amplitude selector, an “I” circuit, an actuator, a synchronizer connected to the input of the leading edge of the strobe pulse of the control zone, the output of which is connected through a trigger and a clock generator connected in series with the clock input of the register the shift and the counter, the output of which is connected to the second input of the trigger, additionally introduced: standby multivibrator installed between the output of the amplitude selector and the recording input reg Stra shear; (n-1) logical elements “AND” and logical element “OR”, the output of which is connected to the actuator, and its n inputs are connected to n outputs of the circuits “AND”, m inputs of each of them are connected to the outputs (m * n) bit shift register. Moreover, the inputs of the first circuit “And” are connected to the first, 2.1, 3.1, ..., m.1 outputs of the shift register, the inputs of the second circuit “And” are connected to the second, 2.2, 3.2, ..., m.2 outputs of the shift register and so on; m is the number of location cycles taken into account when deciding on the presence of a defect, n is the counter capacity and the number of intervals into which the control zone is divided.

The invention is illustrated by drawings. Figure 1 shows the structural diagram of the device, figure 2 - voltage diagrams at various points of the inventive device, figure 3 - connection diagram of the logical elements "And" to the outputs of the shift register.

The automatic defect detector contains a synchronizer 1, connected through the front edge of the strobe of the control zone 2 to one of the inputs of trigger 3, the output of which is connected to the reset input of counter 4, and also through the clock generator 5 with the counter input of counter 4, the output of which is connected with the second input of trigger 3, as well as with the clock input of the shift register 6, the recording input of which is connected to the output of the standby multivibrator 7, the input of which is connected to the output of the amplitude selector 8, the outputs of the shift register h Through n m-input logic elements "AND" 9 are connected to n inputs of the logic element "OR" 10, the output of which is connected to the input of the actuator 11.

Synchronizer 1 produces clock pulses U1, which are input to the leading edge of the strobe pulse of control zone 2, at the output of which video pulses U2 are generated, which are fed to one of the inputs of trigger 3 and switch it in such a way that signal U3 appears on its output allowing the counter 4 to work and a clock generator 5, the output of which clock pulses U4 are supplied to the counting input of the counter 4 and to the clock input of the shift register 6. The capacity of the counter 6 is n, where n is the number of intervals into which the control zone is divided ASD system, and the capacity of the shift register is n * m, where m is the number of repetitions of the echo signals necessary for the operation of the ASD system. After counting n pulses at the output of the counter, a signal U5 is generated that goes to the second input of trigger 3 and transfers it to its original state, in which the level of signal U3 at the output of the trigger prohibits the operation of clock generator 5, resets the counter 4 to zero and prohibits its operation . The clock pulses U4 go to the clock input of the shift register 6 and shift the information pulses U6 that go to the input of the register 6 from the output of the multivibrator 7, which is triggered by a sequence of video pulses U7, consisting, for example, of a video pulse corresponding to the probing signal U8, echo signals U9- U11 and bottom signal U12. The video pulses U7 have digital levels ("0" and "1") and are generated in the amplitude selector 8 from the signals U13 coming from the output of the receiving path of the flaw detector (not shown in Fig. 1).

In the amplitude selector, the U13 signals are limited to a minimum, and parts of the U13 signals exceeding the limit threshold, which are converted to U7 signals with digital levels (“0” and “1”).

The limit threshold is usually chosen such that the amplitudes of the echo signals from defects with acceptable dimensions do not exceed the limit threshold. It is possible to implement an amplitude selector, for example, according to patent RU 22420022 (block cutoff locator).

The duration of the video pulses U6 is chosen equal to the period of the clock pulses U4, which eliminates gaps when recording information about defects in the shift register. The signals U9 ^I -U10 ^I corresponding to the control zone of the ASA system coincide in time with the clock pulses U4 and therefore they are recorded in the shift register and shifted in its cells. If the echo signals from any defect located in one of the n control zones are repeated without interruption in m location cycles, then high logic levels will appear at the outputs of the m cells of the register, coming to the inputs of one of the n logical elements “AND”. The output of this element is a signal of a high logic level, which is fed to one of the inputs of the n-bit logic element "OR", the output of which the signal U14 with a high logic level is fed to the input of the actuator 11.

The "And" elements have m inputs and are connected to the outputs of the shift register 6, and, for example, the first input of the first logical element "And" is connected to the first output of the register, the second input to output 2.1, the third to output 3.1 and the last input to output m.1, as shown in figure 3. The inputs of the second logical element "AND" are connected respectively to the outputs of the register 2, 2.2, 3.2, ..., m.2. In total, n m-input logical elements “AND” are installed, the outputs of which are connected to n inputs of the logical element “OR”.

Thus, in the proposed device as a result of the introduction of new blocks and connections: a waiting multivibrator installed between the output of the amplitude selector and the input of the shift register entry, (n-1) logical elements "AND" and the logical element "OR" installed between the outputs of the logical elements "And" and the input of the actuator, increased noise immunity and reliability of the ASD system. The implementation of the proposed ASD system does not present any difficulties, while standard digital elements can be used.

Claims (1)

An automatic defect detector for an ultrasonic flaw detector, comprising an amplitude selector, an actuator, a synchronizer connected through the front edge of the strobe of the control zone to the first input of the trigger, the output of which is connected to the counter reset input and through the clock generator to the counter input and clock the input of the shift register, the output of which is connected to the logical element "AND", the output of the counter is connected to the second input of the trigger, characterized in that it complements A standby multivibrator is installed that is installed between the output of the amplitude selector and the input of the shift register record, the (n-1) m-input logic elements “I”, the inputs of which are connected to the outputs of the register, and the outputs of all n logic elements “AND” are connected to the inputs of the logical element "OR", the output of which is connected to the input of the actuator.

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