SU726476A1 - Eddy-current flaw detector - Google Patents

Description

The invention relates to the field of non-destructive testing by the eddy current method and can be used, for example, to detect cracks in cylindrical articles.

A device containing two autogenerators is known, the oscillating circuit of each of which includes an inductive converter, and an output unit made in the form of a bridge circuit with a galvanometer in measuring diagonal 1.

The known device has a large inertia measurement, which reduces the performance of the control.

Another device is known that contains n 2 inductive converters, n autogenerators, the oscillator circuit of each of which includes a converter, and output unit 2.

The known device contains amplitude detectors, a power stabilization circuit and a phase-sensitive indicator in the output unit.

The known device has a high sensitivity, but insufficient speed, which reduces the performance of the control.

The aim of the invention is to improve the performance of product quality control.

This is achieved by the fact that the proposed device is equipped with a switch, with the signal inputs of which the oscillators are connected, and its output is connected to the signal input of the output unit, a delay unit and a clock pulse generator, the output of which is directly connected to the control input of the switch, and through the delay unit the input of the output block, which is made in the form of a period measurement circuit

FIG. Figure 1 shows the ripe device structural diagram; in fig. 2 is a block diagram of a period duration measurement unit.

The eddy current flaw detector contains inductive converters 1-3, autogenerators 4-6, clock generator 7, switch 8, delay unit 9, output unit 10 from the period duration measurement circuit 11 and indicator 12 Defects.

Claims (2)

Converters 1-3, included in oscillatory circuits of autogenerators 4-6, are designed to excite eddy-currents in a controlled product. The frequency of the oscillator changes as the defective part of the product passes under the transducer. Switch 8 is prednazng. For alternately connecting autogenerators 4-6 to circuit 11 of block lO.re the non 7 control the operation of switch 8, Block 9 is designed to delay switching of circuit 11, for example disconnecting from switch 8 by switching time, which prevents possible measurement error duration of the period of autogenerators 4-6. Indicator 12 signals the presence of a defect under one of converters 1-3. Scheme 11 is intended for setting up and measuring the length of a single oscillation period of an autopower. The circuit 11 consists of a period selection circuit 13, a crystal oscillator 14, a coincidence circuit 15, a counter 16 and a digital threshold device 17.v. The circuit 13 shows the selection of two identical fronts of pulses (front or rear) and the formation of a signal, the duration of which is equal to the duration of the oscillation period of the autogenerator. K :: art oscillator 14 generates high frequency fijg stable oscillations. Circuit 15 is designed to transmit oscillations from generator 14 only if there is a signal from the output of circuit 13. Counter 16 is designed to determine the number of generator period 14 that passed through circuit 15. After counting the number of periods of generator 14, counter 16 is set to the initial circuit The Digital Threshold Device 17 is designed to form a signal in response to the arrival of 16 pulses in the counter, the number of which exceeds a certain predetermined number. To explain the principle of operation in the device, the number of autogenerator numbers equals three. Accepted by the fact that the oscillators 4 and 5, whose converters 1 and 2 are above the surface of the product without defects, operate at the same frequencies. If the converter 3 of the oscillator 6 is above the defect, then the frequency is less than the frequency of the oscillators 4 and 5. The connection of the oscillators to the circuit 11 of the unit 10 is performed by the switch 8 with the frequency of the oscillator. The leading edge of the pulse coming from. Oscillator 7 in switch 4 is given permission for 6t oscillator 4 of oscillator 4 to pass through commutator 8 to circuit 11. When the leading edge of the pulse is transmitted from oscillator 4 to circuit 13, the last signal at the output of the oscillator is logical. The logical signal from the output of the circuit 13 is supplied to the input of the circuit 15 and permits the passage of oscillations 0-: generator 14 to the counter 16. The latter will count the pulses of the generator 14b n: the beginning of the period to its end, after which the output of the circuit 13 shows the logic signal closes the circuit 15 Then, the communicator 8 connects to the circuit 11 an auto-oscillator 5. The circuit 13 at the gap of the period is made so that it separates the period of the signal from the first front that arrives at it to the next front of the same name (from the falling front to the falling back or from the leading edge to front). The oscillation period of the oscillator 4 was separated between two leading fronts, and in the case of the arrival of the oscillator 5 at the beginning of the trailing edge, the oscillation period of the oscillator will occur between the two falling fronts. then the oscillator 6 is connected to the circuit 11, which will measure the duration of its period. . As practical tests have shown, the duration of the periods of the autogenerators 4 and 5 is determined by .50 pulses with a counter 16, and the duration of the period of the autogenerator depending on the geometrical dimensions of the defect is 51 ... 60 pulses. The last number will be registered with block 17 as a defect. The necessity of introducing block 9 into the device is due to the fact that at certain points in time, an oscillator 6 is connected to the circuit 11 Measuring the period duration instead of the aytogen generator 5, which, in the absence of a delay block 9, will be perceived by circuit 13 as the leading edge of the autogenerator 6. Such an occurrence may result in skipping. defect. . The analysis of oscillation parameters of oscillators in a known device is limited by the time and time of the detector circuit. For reliable operation of the amplitude, frequency and phase detectors, the analysis time is t where T is the oscillation period of the oscillators. For the proposed vortex flaw detector, the minimum frequency analysis time is t where -c is the delay time for which circuit 11 is disconnected from switch 8, in the switching pattern of autrgents, where M is the design factor determined by the operation algorithm of period selection circuit 13. If the period selection is produced from any first pulse, followed by the selection scheme of period 13, to the next eponymous (libr from front to front, or from back to rear), then the coefficient Mel, 5. When choosing a period from a certain front to the same name (for example, only from the front to the front) coefficient. The difference between the M coefficient and the unit is due to the fact that the autogenerators operate with the same frequencies, but different phases. In the flaw detector under consideration, the coefficient M is 1.5. The time t for switches is several tens of nanoseconds and can be ignored at operating frequencies up to 1 MHz. Reducing the time of measuring the frequency of the oscillator. Up to t (1.5-2) T. allows to increase the frequency of the clock generator in comparison with flaw detectors using an amplitude, frequency or phase detector by 5-6 times, which makes it possible to increase the speed of movement of the product relative to the block of surface sensors by 5-6 times or at the same speed of movement the same number of N converters. Both possibilities allow to increase the productivity of quality control of products. Claims of the invention: eddy current flaw detector, containing inductive transducers, p-oscillators, in the oscillatory circuit of each of which a transducer is included, and an output unit, o. distinguished by the fact that, in order to improve the performance of the control, it is equipped with a switch, with the signal inputs of which are connected autogenerators, non-catchers, and its supply is connected to the signal input of the output unit, the delay unit and the clock pulse generator, the output of which is connected directly to the control input cbmutator, and through the delay unit - with the input of the output unit, which is made in the form of a period measurement circuit. Sources of information taken into account in the examination 1. The author's certificate of the USSR 55758, cl. G 01 N 27/86, 1938. 2. Avtorskoe, certificate of the USSR N 27/86, 1974 No. 490004,. GG 01 (prototype). 726476