SU1748045A1 - Device for ultrasonic control of metals - Google Patents

Abstract

The invention relates to non-destructive testing using electromagnetic-acoustic transducers and can be used to measure thickness and detect defects in metal articles. The aim of the invention is to increase the reliability of control and reduce power consumption due to the recovery of the energy of a pulsed magnetic field in a storage capacitor. For this, the device containing an electromagnetic-acoustic transducer with a pulsed electromagnet is equipped with a blocking generator, whose collector windings are located on a common pulsed magnetic core. an electromagnet winding, the switching current switching circuit is designed as a four-arm bridge consisting of a thyristor In the AC diagonal of which the storage capacitor is included, the pulse winding of the electromagnet is included in the diagonal of the direct current. After each bias pulse, the storage capacitor is recharged by the current maintained in the pulse winding of the electromagnet due to self-induction, and the magnetic field energy returns to the storage capacitor. the direction of the current in the pulsed winding of the electromagnet Podzair d storage capacitor is carried out from the inductively connected with the impulse winding of the electromagnet to the collector circuit of the blocking generator. 2 Il. SL С 4 N 00 g SL

Description

The invention relates to the non-destructive testing of metals with the aid of electromagnetic-acoustic transducers and can be used to measure thickness and detect defects in metal products.

Non-contact ultrasonic testing devices are known that use the electromagnetic acoustic (EMA) conversion for

excitation and reception of ultrasound, in which a magnetizing field is created by a pulsed electromagnet.

The closest to the invention to the technical essence is a device for ultrasonic control of metals, containing a high-frequency generator electrically connected to each other and a circuit for starting it, series-connected echo receiver and indicator, the second

the input of which is connected to the output of the high-frequency generator startup circuit, Schmitt trigger, current pulse generator, made in the form of a valve electrically connected at one point, a capacitor, a thyristor connected to a Schmitt trigger trigger output by a control electrode, containing an electromagnet and a measuring coil, which connected to a high frequency generator and receiver, and an electromagnet connected to the output of a current pulse generator, a voltage suppressor and a full-wave rectifier, output which is connected to the output of the current pulse generator, a voltage limiter and a full-wave rectifier whose output is connected to the input of the gok pulse generator and to the input of the limiter, and the output of the latter is connected to the Schmitt trigger input

A disadvantage of this device is the high energy consumption of the excitation circuit of the pulsed winding of an electromagnet, due to the fact that the energy of the magnetic field generated in each pulse, after the end of the action of the pulse, is completely converted to heat energy and this does not allow reaching the electromagnet of high magnitude with small dimensions. reliability of control due to an increase in the magnetic induction created by an electromagnet in a pulse. The disadvantage of this device is also low productivity The monitoring efficiency, due to the fact that the frequency of the current pulses in the pulsed winding of the electromagnet is strictly equal to twice the value of the frequency of the alternating current of the network

The purpose of the invention is to increase the reliability of the control and reduce the power consumption.

This is achieved by the fact that the device is equipped with a blocking generator collector and the base windings of which are located on the magnetic circuit of the electromagnet, the collector winding of the blocking generator is turned on according to the magnetic flux with the pulse coil of the electromagnet and the control pulse generator connected to the collector winding of the blocking generator, the switching circuit This current is made in the four-flipper bridge, consisting of thyristors in the diagonal of alternating current of which the storage capacitor is connected, The direct current diagonal includes the impulse winding of the electromagnet, the control electrodes of the thyristors are connected to the corresponding outputs of the driver of control pulses,

the impulse winding leads of the electromagnet are connected to the control inputs of the starting circuit of the probe pulse generator,

FIG. 1 shows the flow chart

the proposed device; FIG. 2 shows the voltage and current pulse diagrams generated during operation of the device. The device consists of a generator 1, zone 0 of pulses and a circuit 2 for its start, a receiver 3 echo signal and a unit 3 for signal processing, a generator 5 for current pulses containing a storage capacitor b and the switching circuit of the discharge current, which is polynyed on four thyristors 7-10, driver 11 of control pulses, blocking generator 12, EMA converter 13, containing a pulse-wound electromagnet 14 and high-frequency

0 primary emitting iDuctor 15

The starting pulse generator circuit 2 is connected in series with the probe pulse generator 1 The echosngial receiver 3 is connected in series with the signal processing unit 4, the second input of which is connected to the output of the probe pulse generator circuit 2 High-frequency receiving-emitting inductor 15 is connected to the output

0 of the generator 1 of the probe pulses and with the input of the receiver 3 of the echo signal The collector winding 16 and the base winding 17 of the Mng generator 1 are located on a common magnetic conductor 18 with a pulse winding5 14 electromagnets. The collector winding 16 of the blocking generator 12 is turned on according to the magnetic flux with a pulse mark 14 of the electromagnet Four thyristors 7-10 form a four-shoulder

0 the bridge to the diagonal of the alternating current of which the storage capacitor 6 is connected, and in the dc-voltage converter - a pulse winding 14 of the electromagnet The control electrodes of the thyristors 7-10 are connected

5, respectively, to the four outputs of the driver control generator 11 (not shown), the terminals of the pulse winding 14 of the electromagnet are connected to the control inputs of the generator start circuit 2

0 probe pulses, and the collector winding 16 of the blocking generator 12 is connected to the synchronizing input of the driver 11 of control pulses

5 The device works as follows.

The bocking generator 12 used in the device is executed according to a scheme that provides a self-oscillating mode of its operation. During the operation of the blocking generator 12

in the self-oscillating mode, the synchronizing input of the driver 11 of the control pulses associated with the collector winding of the blocking generator 12 receives periodically repeated voltage pulses 19. The beginning of each cycle of the blocking generator corresponds to the instant of a rapid decrease in the collector potential and an avalanche buildup of the collector current. The cycles of the blocking generator 12 correspond to alternating even and odd device operation cycles. For each voltage drop 19, the clock input of the driver 11 of the control pulses at the output of the driver 11 a control pulse is produced which terminates after the rise of voltage 19 at the synchronization input of shaper 11 with a delay of time g arranging the end of the process for the disappearance of the current in the collector circuit of the blocking generator 12 At the outputs of the imaging unit 11 connected to the control electrodes of the thyristors 7 and 9, the specified control pulses 20 are generated only in even cycles and at the outputs connected to the control electrodes of the thyristors 8 and 10 control pulses 21 only in odd cycles

In the steady-state operating mode, the voltage on the storage capacitor 6 at the beginning of the even-numbered cycles of the device is direct for thyristors 7 and 9. When the collector current increases in blocking generator 12 in the pulse winding 14 of the electromagnet, an applied back voltage is applied1 relative to the thyristors 7 and 9 Because of this, the thyristors 7 and 9 are not unlocked immediately after supplying the control pulse 20 to their control electrodes, but after being induced in the blocking generator 12 in the process of establishing the collector current in the The electromagnet pulse winding 14 will become less in magnitude than the voltage on the plates of the storage capacitor 6 After unlocking the thyristors 7 and 9, the storage capacitor 6 is discharged through the pulse winding 14 of the electromagnet During the discharge when the discharge current increases in the base winding 17 of the blocking generator 12 EMF is induced, which maintains the open state of the transistor in the blocking generator. The first phase of the cycle is completed after the maximum value of the current in the impulse winding 14 electromagnet is reached. In this case, the maximum value of the current in the collector winding 16 of the blocking generator 12 At this point, the energy accumulated by the storage capacitor before the start of the cycle passes into the energy of the magnetic

5 floor generated by impulse winding 14 electromagnet

In the next phase of the cycle, the accumulator capacitor 6 is recharged to transfer the energy of the magnetic field created by the pulse winding 14 of the electromagnet to the energy of the electric field of the storage capacitor. A fast locking of the transistor b of the blocking generator 12 and the energy of the magnetic field created by the collector winding 16 blrking generator 12 also transforms to the energy of the electric field of the storage capacitor 6. Thus, the charging of the storage capacitor 6 and the compensation of thermal sweats s energy during about device operation proceeds due to induction totse occurring in the pulse coil 14 of the electromagnet for locking tranzisto5 pa in blocking oscillator 12 By the latter process there is an accumulation steady value charge storage capacitor 6 (over several cycles) after the device is switched on, and

0 device translates into steady state operation. The open state of thyristors 7 and 9 in this phase of the even cycle is guaranteed by the falling edge of the control pulses produced

5 shaper 11 control pulses

In the next odd cycle, all the processes described above are repeated with a change in the polarity of the voltage

0 capacitor capacitor plates

In this cycle, the discharge of the storage capacitor occurs through the opening thyristors 8 and 10 on the control electrodes of which the unlocking

5 pulses 21 produced at the corresponding outputs of the driver 11 control pulses The direction of the discharge current 22 in the pulse winding 14 of the electromagnet is the same in even and

0 odd cycles of operation of the device. Current 22, flowed through the impulse winding 14 of the electromagnet, creates a magnetic impulse. The voltage from the impulse winding leads 14 of the electromagnet goes to

5 the input of the starting pulse generator circuit 2, in which the moment of the change of the voltage sign on the leads of the winding 14 is recorded. At this moment, the maximum current in the winding at the output of the circuit 2 is a pulse,

which includes a generator of probe pulses and a signal processing unit 4. The radio pulse generated by the probe pulse generator 1, passing through the radiating coil of the high-frequency receiving-emitting inductor 15, creates eddy currents in the controlled metal. When eddy currents interact with the magnetic field of the pulsed winding 14, alternating Lorentzian forces arise, which create ultrasonic oscillations in the metal. In the case of reverse EMA-conversion, the emf is induced in the measuring coil of the high-frequency transceiver-emitting inductor 15 This emf is amplified by the echo receiver 3 and is fed to the signal processing unit 4. Parameters of the Controlled Metal are estimated by the magnitude and position of the echoes.

Thus, the reduction in power consumption is achieved by recovering the energy of the magnetic field s of the storage capacitor b after each discharge (during inertial reloading with a change in the discharge voltage on the plates). In this case, the direction of the discharge current in the impulse winding 14 of the electromagnet is constant and no reversal of the core of the electromagnet occurs. With small dimensions of the device, this makes it possible to achieve large values of magnetic induction in a pulse of magnetizations, to increase the efficiency of the EMA conversion and, consequently, the reliability of control. The magnitude of the magnetic induction in the pulse increases also because the maximum value of the current in the collector circuit is Rotor 12 and in the pulse winding 14 of the electromagnet coincide in time. The frequency of the current pulses in the pulsed winding 14 of the electromagnet is determined by the parameters of the timing circuit of the blocking grid and is independent of the frequency of the alternating current of the supply mains.

Claims (1)

Invention Formula A device for ultrasonic testing of metals, containing sequentially connected starting circuit of the probe pulse generator and probe pulse generator connected in series with the echo receiver and signal processing unit, the second input of which connected to the output of the starting pulse generator, the current pulse generator, consisting of a storage capacitor and a switching current switching circuit, into an electromagnetic-acoustic converter, consisting of a pulse-wound electromagnet and a high-frequency receiving-emitting inductor connected between the probe output pulses and input the echo receiver, which differs in that, in order to increase the reliability of control and reduce power consumption, it is equipped with a blocking generator, the collector and base windings of which are located on the electromagnet magnetic circuit, the collector winding of the blocking generator is enabled according to the magnetic the flow with a pulse winding of an electromagnet, and a driver of control pulses connected to the collector winding of the Bloding generator, the switching current switching circuit is made in the form of a four-shoulder bridge, present on of the thyristors in diagonal The AC current of which is included into the accumulator capacitor, the pulse current of the electromagnet is included in the diagonal of the direct current, the control electrodes of the thyristors are connected to the corresponding outputs of the control pulse generator, the terminals of the pulse winding of the electromagnet are connected to the control inputs of the starting circuit of the generator of pulse impulses. in t o WITH t I 22 . fig 2