SU387498A1 - Magnetostriction resonator - Google Patents

Description

one

The invention relates to radio equipment and can be used in frequency stable oscillators.

A magnetostrictive resonator is known, comprising a resonant element, excitation and signal windings, a constant magnet, and a frequency control winding. However, a large amount of electrical power is needed to control the frequency of the resonator, and the frequency range is small.

The aim of the invention is to reduce power consumption for frequency control.

This is achieved by the fact that a permanent magnet, made in the form of two ring sections, is located between the control winding and signal excitation and between the control winding and signal pickup, the control windings are electrically connected in series and span the entire length of the ring sections, which are oriented relative to each other so that their magnetic inductions are directed towards each other and coincide with the direction of the magnetic fields of the corresponding control windings.

The drawing shows the proposed resonator.

It contains a resonant element /, an excitation winding 2, a signal removal coil 3,

a permanent magnet 4, made in the form of two annular sections, and a frequency control winding 5. A permanent magnet 4 is located between the frequency control winding

5 and the excitation winding of the signal 2 and between the frequency control winding 5 and the signal pickup winding 5. The frequency control windings 5 are switched on electrically in series and span the entire length of the annular magnetic sections, which are oriented relative to each other so that their magnetic inductions are directed towards each other and coincide with magnetic fields applied to their respective control windings.

Under the influence of a variable magnetic field, the excitation winding 2, the resonant element / begins to periodically change its length. When the frequency of the external magnetic field coincides with the natural frequency of the resonant element, the amplitude of oscillations increases sharply: a resonance occurs. Due to the reverse effect of magnetostriction on the winding of the pickup signal 3, e is induced. D. s., the frequency of which coincides with the resonant frequency of the resonant element.

The permanent magnet 4 creates an initial bias, and the additional magnetic field created by the frequency control windings 5 is variable in time with an oscillator.

but given to the program, creates conditions

to change the frequency of the resonator within the required limits. The reduction of the power consumed for controlling the frequency is explained by the fact that most of the magnetic field required for the operation of the resonator is created by a permanent magnet, and the frequency control windings only give the field the power required for a given change in the frequency of the priranle, enne. In addition, with a series connection of the frequency control windings, to ensure the same change as in the case of a parallel connection, the change of the magnetic field requires less supply voltage. The arrangement of the permanent magnet, made in the form of two annular sections, and the frequency control windings in such a way that their magnetic inductions are directed towards each other, creates the necessary conditions for increasing the frequency variation range.

The proposed resonator allows reducing the frequency of the mosh consumed to control, more than 3-4 times, or at a given 3-4 watt, expanding the frequency range up to 900-1200 Hz.

Subject invention

A magnetostrictive resonator, containing a resonant element, windings for excitation and removal of a signal, a permanent magnet made in the form of two annular sections, and

frequency control winding, characterized in that, in order to reduce the power consumed for controlling the frequency, a permanent magnet is located between the control winding 1A of the signal excitation and between the control winding and the signal pickup, while the control windings are electrically connected in series to wrap the entire length of the magnetic sections which are oriented relative to each other so that their magnetic inductions are directed oppositely and coincide with the direction of the magnetic fields of the corresponding control windings.