SU974240A1 - Device for checking ferromagnetic articles - Google Patents

Description

one

The invention relates to non-destructive testing and can be used in devices for monitoring such Lerromagnetic products as wires, cylindrical magnetic films, etc. P .

Devices for non-destructive testing of ferromagnetic products are known, based on the Barkhausen effect, which contain a magnetization reversal and measuring windings, as well as a recording unit connected to the measuring winding. The magnetizing winding creates an alternating magnetic field that magnetises the controlled product. The emf from the Barkgauen jumps induced in the measuring winding enters the recording unit, where its parameters are measured. The magnitude of the latter is controlled by the product 1.

The disadvantage of such devices is the difficulty of filtering harmonics.

frequency of magnetization reversal, which leads to the need to reduce the frequency of magnetization reversal to a value of the order of 0.1–1 Hz and, as a result, to an increase in the time of control.

The closest to the invention in its technical essence is a device for controlling ferromagnetic products, comprising a series-connected AC source, a differential inductive transducer with an overmagnetization and measuring windings, and a recording unit. The controlled product is reversal magnetized by an alternating magnetic field created by an alternating current source. PDS from Parkhausen jumps from the output of an inductive converter enters the unit

Claims (2)

20 registration, where the measurement of the specified quantitative characteristics of this SDS is carried out. On the basis of the measurement result, the quality of the product being tested is judged. The disadvantage of the device is that, when testing products with high permeability by magnetic permeability, the compensation of harmonics of the magnetization reversal frequency worsens. In this case, the waveform is distorted, which leads to a deterioration in measurement accuracy, and, consequently, to a deterioration in the reliability of the control. The purpose of the invention is to improve the accuracy of control of ferromagnetic materials. The goal is achieved by that the Mto device is equipped with a k source of alternating current connected in series by an amplifier limiter, an inverter and a switch, and an additional magnet winding connected to the output of the switch, the second input of which is connected to the second output of the limiter amplifier. FIG. 1 shows the graphs illustrating the principle of operation of the device; in fig. 2 - block ches; ma last. In a number of cases (control of materials with high magnetic permeability, scatter of the coercive force of the material, the presence of constant magnetic fields, etc.) the emf takes the form e; j (t) (Fig. III) due to a mismatch in time corresponding to the maximum intensity of the SDS. Obviously, such a search for a signal significantly increases the measurement error of the characteristics (this is especially true for measuring the average number of outliers). Suppose that the sections of a ferromagnet located in the zones of sections of the measuring winding of an inductive transducer are re-magnetized by the field H (t) and H, (t), as shown in FIG. 1a The first section has an empty coercive force HC, and the second section H (;. Since in most practical cases the maximum of the EMF intensity from the Barkhausen bench is in the area of the CIRT of the force, it is obvious that the maximum of the magnetization reversal of the first section will correspond to time t the second maximum is the moment ii. The meaning of harmonic compensation is to combine the moments of time t and t .. Create an additional constant field lN From the graphical constructions in Fig. 1a, it is clear that in this case the moments t and t coincide at the point t, and this was required. However, if in the first half-period of the reversal of the field, the dH compensates for the spread of the coercive force, then in the second half-period, the presence of this field aggravates the distortion of the signal. If we consider that the magnitude of the compensating field should remain unchanged for this sample, then it is easiest to create this field with the help of an adjustable limiting amplifier connected to the output of the variable source. Foot power, and more winding. In order to achieve a positive effect of the above elements, it is not enough, as there are cases when a compensating field in both half periods increases the signal. It is necessary to create the possibility of phasing the additional field with respect to the magnetizing fields. This is achieved by using an inverter and a switch connected between the amplifier-limiter and the auxiliary winding. The block diagram of the device includes an alternating current source 1, an additional winding 2 magnetizing, reversing the winding 3 of an inductive converter, a monitored product k, measuring windings 5 of an inductive converter, a recording unit 6, an adjustable limiting amplifier 7, an inverter B and a switch 9. Source 1 power, differential inductive transducer (windings 3 and 5) and block 6 registration are connected in series. The amplifier-limiter 7, the inverter 8, the switch 9 and the additional winding 2 are connected in series. In addition, the input of the amplifier-limiter 7 is connected to the second output of the source of alternating current, 1, and the output to the second input of the switch 9. The device operates as follows. The source 1 generates an alternating current which, flowing through the windings 3 of the inductive converter, reversal the monitored product and in the windings 5 induces an emf from Barkhausen jumps, which is fed to the input of the recording unit 6. The latter performs the functions of amplifying and measuring the given characteristics of an emf. Since the rebound windings 3 are switched in opposite, and the measuring windings - according to that, in the first approximation harmonics are compensated in the same way as in the prototype. The almost complete harmonic compensation is carried out in accordance with the previously described principle. At the same time, the input of the adjustable limiting amplifier 7 receives a signal from the output of the AC source 1. The output of limiter amplifier 7 is a balanced square signal whose amplitude can be smoothly controlled. The signal then goes to inverter 8 which changes its base by 18p without changing the amplitude. The additional winding 2 receives a signal either from the output of the amplifier-limiter 7 or from the output of the inverter 8, which is achieved by means of the switch 9. On the coil 2, it creates a compensating field that compensates for the spread of corrective force and the presence of dark external magnetic fields. Ta KIM, the value of the compensating field is set by adjusting the limiting level of the amplifier limiter 7, and the phase is necessary by the switch 9. This is done either by visually observing the signal or by the indications of a conventional voltmeter minimal at the moment of compensation. In the proposed device, the component of measurement error caused by uncompensated harmonics of the magnetization reversal frequency is almost completely eliminated. This means not only increased reliability of control, but also the ability to control products such as cylindrical magnetic films, since, for example, measuring the average number of EMF emissions from Barkhausen jumps in such films without harmonic compensation is almost impossible. Claims An apparatus for monitoring lerromagnetic products comprising an alternating current source connected in series, a differential inductive transducer with remagnetization and measuring windings, and a recording unit, characterized in that it is equipped with series-connected limiting amplifier connected to the alternating current source , an inverter and a switch and an additional bias winding connected to the output of the switch, Ora input of which is connected to the second output of the limiting amplifier. Sources of information taken into account during the examination 1. Defectoscopy. K 4, 1977, p. 77-94. 2. US patent number 3 27872, cl. 73-88.5, 1969 (prototype). fPU9.1