SU540229A1 - Device for monitoring magnetic cores - Google Patents

Description

one

The invention relates to the field of magnetic measurements and can be used to automatically control ferromagnetic cores during production.

Known devices for monitoring ferromagnetic cores include a current pulse generator connected to a series-connected variable resistor and magnetizing shell, a test sample reading a winding located on the sample whose output is connected to the comparison circuit, the second input of which is connected to the output of the variable resistor, and access to the actuator 2.

However, in known devices, the output: Signals taken from the read winding have a permissible variation in the time when the signal reaches its maximum.

The closest technical solution to the present invention is a device for monitoring magnetic cores, comprising a current pulse generator connected to a series-connected variable resistor and a magnetizing shell, a delay line that reads a winding, a comparison unit and an actuator 2.

However, the known device is characterized by complexity.

The purpose of the invention is to simplify the device. This is achieved by the fact that in a device for controlling magnetic cores, a current pulse generator connected to a series-connected variable resistor and a magnetizing winding, a read winding, a delay line, a comparator unit and an actuator reading a winding through a delay line

and the resistor is connected to the input | of the comparison unit, the comparison unit on the tunnel diode, the anode of which is connected to the positive power source through the second resistor, the cathode of the tunnel diode is connected

with a grounded bus and with a variable resistor and a magnetizing winding, and the actuator is connected parallel to the tunnel diode. FIG. 1 shows a structural diagram.

the proposed device; in fig. 2 is a diagram of his work.

The current pulse generator 1 is connected to one of the successively connected variable resistor 2 and magnetizing winding 3

test sample 4, readout winding 5, the input of which is connected to the delay line 6, and the output of the latter is connected to resistors 7 and 8 and a tunnel diode 9, in parallel with which the actuator 10 is connected.

The device works as follows.

Test sample 4 is re-magnetized by winding 3 with current pulses from generator 1. In this case, EMF pulses in the readout winding 5 characterize the magnetic parameters of the test sample. These pulses are delayed by a delay line 6 and fed through a resistor 7 to a tunnel diode 9, to which the supply voltage is supplied through a resistor 8. Pulses taken from the read winding 5 are delayed by a delay line 6 relative to the reference signal (see Fig. 2 position 11 ), which is formed from the magnetizing current of a resistor 2. The forward pulses shown in the diagram I applied to the cathode of the tunnel bottom 9 bring it to a stable state with a small internal resistance, and a fall The pitch across the tunnel diode is small, which is determined by the resistor 8 connected to the power source. The pulses from the read winding 5, delayed by the delay line 6, are applied through a resistor 7 to the anode of the tunnel diode 9, on the cathode of which a reference voltage is applied at that time. When the pulses shown in diagram 12 exceed the amplitudes of the reference voltage of the pulse 11 by the threshold value 13 of the tunnel diode 9, the latter is transferred to another stable state with high internal resistance and the magnitude of the incident voltage increases (see Fig. 2 position 14 b, c and 11, 12 b, c).

Thus, when the amplitude of the pulses exceeds the reference voltage and the threshold of operation of the tunnel diode, the latter will go into a steady state with a large internal resistance before the pulse 126 and end, and after they decrease 116 and return to the steady state low internal resistance. If pulses 12 exceed the threshold of operation of the tunnel diode, positive pulses will be emitted at the latter (see Fig. 2, positions 146 and c). The presence of these pulses determines that the amplitude of the read signals of the test sample is greater than the reference voltage (see Fig. 2 positions 126 and c).

No positive impulses on

tunnel diode means that the test subject's pulses are o: the sample is less than or equal to the reference signal (see Fig. 2, positions 12a and d).

The signals taken from the tunnel diode and describing the result of the comparison, control the actuator 10, which directs the cores after testing to the corresponding stream. Thus, when a delay line is introduced into the measuring device, it is possible to simplify the comparison device and, accordingly, the entire device. Since the effect of random impulse noise on the input of the device is eliminated, this makes it possible to exclude from

devices, preamplifier integrators, various rectifying devices or impulse-to-frequency amplitude converters, etc., and a comparison device can be built on a single tunnel diode. Considering that signals whose amplitudes have units of volts are removed from the read windings, it is possible to build a sorting device without first amplifying the compared signals, which simplifies

magnetic core control device.

Claims (2)

1. A device for monitoring magnetic cores containing a pulse generator current connected to the series-connected variable resistor and magnetizing shell, readout winding, delay line, comparison unit and actuator, characterized in that, in order to simplify the device, readout winding through the delay line and the resistor is connected to the input of the comparison unit. 2. The device according to claim 1, characterized in that the comparison unit is made on a tunnel diode, the anode of which is connected via a second resistor to a positive power source, the cathode of a tunnel diode is connected to a grounded busbar and to a variable a resistor and a magnetizing winding, and the actuator is connected parallel to the tunnel diode. Sources of information taken into account in the examination: 1. A. A. Krupsky. Measurement of the time of magnetization reversal of the cores. Energy 1971, p. 5. 2. USSR author's certificate No. 310224, M. Kl.2 G 05V 1/00, 07.26.71. (prototype). FIG I 3