SU1185572A1 - Accumulating magnetic amplifier - Google Patents

Abstract

ACCUMULATING MAGNETIC AMPLIFIER containing, on the common magnetic core, input and short-circuited windings, excitation and reading windings, connected respectively to the generator outputs / ".11 / 3 I" Lt07 of the excitation and reading pulses, output winding connected to the information input of the integrator, control input which, like the controlled inputs of the excitation and readout pulse generators, is connected to the output of the control unit, the input connected to the corresponding output of the excitation pulse generator, characterized in that, in order to increase the noise immunity from external magnetic fields and stray fields, the short-circuited winding is made as separate short-circuited 9 sections evenly distributed (L along the length of the magnetic circuit.

Description

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1 The invention relates to electrical engineering and can be used in devices for monitoring and measuring weak quasi-static signals against the background of exceeding noise levels in terms of external magnetic fields and stray fields, for example, as a leakage current sensor in devices for selective control of resistance isolation of electricity ac systems with isolated neutral. The purpose of the invention is to increase the noise immunity of the cumulative magnetic amplifier from external magnetic fields and stray fields, by making the short-circuited winding in the form of short-circuited sections distributed along the length of the magnetic circuit, which ensures demagnetization of the magnetic circuit not only when exposed to alternating fields at the input of the storage magnetic amplifier, but also under the conditions of the influence of external magnetic fields fQ and the fields dissipated by Frd, Fr Fr, which, in turn, will increase the noise immunity of the proposed Yelnia magnetic amplifier compared with the prototype. The drawing shows a circuit of a magnetic amplifier. The storage magnetic amplifier contains excitation pulse generator 1 and readout 2, integrator 3, control unit 4, the input of which is connected to excitation pulse generator 1, and output to control inputs of integrator 3 and excitation pulse generator 1, 2, magnetic circuit 5 from the input a winding 6, an excitation winding 7 connected to the output of the generator 1 of the excitation pulses, a read winding 8 connected to the output of the generator 2 of the reading pulses, the output winding. 9, connected to the information input of the integrator 3, and a short-circuited gate 10, made in the form of short-circuited sections distributed along the length of the magnetic circuit 5. The storage magnetic amplifier works as follows. During the flow in the input winding 6 of the measured quasistatic current 722 and alternating current in the short-circuited sections 10 demagnetizing currents are induced, leading to a decrease in the effect of the variable interference on the magnetic circuit 5 to the level of the coercive force. With this noise level, the cumulative magnetic amplifier provides a fairly good noise immunity due to averaging the input signal as follows. The signal from the control unit A triggers the excitation pulse generator 1. As a result of the simultaneous action on the magnetic circuit 5 of the input signal with a reduced variable component and N periods of excitation EMF, its induction receives a resultant increment of 4 (proportional to the integral of the input signal. At the end of the M th excitation period, control unit 4 stops the generator 1 of excitation pulses resetting the integrator 3, with some delay, starts the generator 2 read pulses and puts the integrator 3 into the integration mode. The read pulse generated by the generator 2, the magnetic circuit 5 reverts the magnetic circuit 5. The impulse EMF pulse is induced when it is read on the output winding 9 by the integrator 3. As a result, the voltage at its output becomes proportional to the induction increment obtained by the core in the excitation interval, i.e. At the end of the reading, the control unit 4 switches the integrator 3 to the information storage mode obtained by the amplifier in the preceding excitation cycle, and starts the generator 1 of the excitation pulses. Further, the cycle of operation of the storage magnetic amplifier is repeated. By performing a short-circuited winding in the form of separate short-circuited sections distributed along the length of the magnetic circuit, induced in each section the EMF causes a demagnetizing current and reduces the effect of the fields in question on the magnetic circuit.

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Thus, the implementation of short-alternating currents of interference, the impact of the closed-loop winding accumulating at the input, and from the external re-magnetic amplifier in the form of short-term fields and stray fields,

The closed-loop sections, distributed, allow interference to be achieved along the length of the magnetic circuit, providing a 5 control measure and measuring the weakness of its interference immunity as anti-static electrical signals.

Claims (1)

STORAGE MAGNETIC AMPLIFIER containing on the common magnetic circuit input and short-circuited windings, field windings and read windings, connected respectively to the outputs of the excitation and read pulse generators, output winding connected to the information input of the integrator, the controlled input of which, as well as the controlled inputs of the excitation and read pulse generators connected to the output of the control unit, the input connected to the corresponding output of the excitation pulse generator, characterized in that, with In order to increase the noise immunity from external magnetic fields and scattering fields, the short-circuited winding is made in the form of separate short-circuited sections uniformly distributed along the length of the magnetic circuit.