SU777780A2 - Electrodynamic oscillation exciter - Google Patents

Description

one

The invention relates to a vibration technique, namely to electrodynamic exciters, and can be used mainly in installations for vibration testing of various products.

Known electrodynamic exciters with the so-called double-core magnetic core 1.

The use of a double-core magnetic conductor allows an increase in the induction of a constant magnetic field in the annular air gap of the magnetic conductor, and hence, the force developed by the pathogen. However, in this type of exciters, the inductive component of the input resistance of the moving coil is not compensated, which results in uneven amplitude-frequency response.

According to the main author. St. 250273, an electrodynamic exciter is known, consisting of a magnetic circuit and a moving system with a coil connected to an alternating current source and rigidly connected to the object table, in which, in order to compensate for the inductive component of the input resistance of the moving coil, the magnetic circuit has two annular gaps, what magnetic power

the lines pass them sequentially in the same direction, and in the gaps there are two sections of the windings of the moving coil connected in series and meeting 5 but 2.

However, in a known oscillation pathogen, variable magnetic fluxes of the moving coil sections must overcome the resistance of two air gaps. it

10 reduces the inductive coupling coefficient between the sections of the moving coil and, therefore, the effect of compensating the inductive component. The latter, in turn, limits the possibilities of a known exciter of oscillations in relation to the developed force and the efficiency of equalizing its amplitude-frequency characteristic.

The aim of the invention is to increase

20 the developed effort and increase of uniformity of the amplitude-frequency characteristic.

According to the invention, this goal is achieved due to the fact that the magnetic core

25 is provided with magnetic circuit elements connecting the core ends with the magnetic core.

FIG. 1 shows an embodiment of the described exciter with a magnetic wire provided with bias coils; in fig. 2 - the same, with permanent magnets.

The electrodynamic oscillation pathogen contains a magnetic core formed by the romm 1 with annular poles 2, a 3, a core 4 and elements 5 and 6 of the magnetic circuit connecting the ends of the core 4 to the rom 1 of the magnetic circuit. According to an embodiment (Fig. 1), biasing windings 7, 8 and 9 are placed in the cavity of the magnetic core. The part of the magnetic circuit of the exciter exciter (Fig. 2) are permanent magnets, therefore there are no bias windings in it. The magnetic circuit is made with two air gaps 10 and 11, in which sections 12 and 13 of the windings of the moving coil 14 are located, which are rigidly connected to the object table 15, which forms a moving system with the coil 14, which is elastically suspended to the magnetic circuit by means of parallel spaced flat springs 16 and p.

Operates the exciter as follows.

The magnetic system (magnetic core and magnetic biasing windings 7, 8, and 9) provides the necessary induction in gaps 10 and And, with magnetic power lines passing both gaps in series. Since the dimensions of the gaps are the same, the magnetic induction created in them is the same.

The magnetic fluxes generated by the bias windings 7 and 9 are summed with the main magnetic flux created by the winding 8. As can be seen from the drawings, the total magnetic flux passed through the gap

10, splits into two streams, the magnetic lines of force of which pass through different sections of core 4. In contrast, the gap 11 has two magnetic streams of lines of force which pass through different sections of core 4, merge into one magnetic stream that passes gap

11. The total magnetic flux passes gaps 10 and And consistently in the same direction. Under these conditions, the forces developed by sections 12 and 13 of coil 14 are equal in magnitude and coincide in direction,

As is known, the magnitude of the magnetic induction in the air gap is limited to

induction of core saturation; In a known pathogen, in order to achieve maximum induction in the gap, the height of the air gap should not exceed 4 of the core diameter. Under these conditions, the area of the annular pole of the magnetic circuit is equal to the area of the core section,

In the described driver, the magnetic current passing through the air gap,

equal to the sum of the streams passing through different core sections. Consequently, the induction in the air gap will be equal to the induction in the core with a gap height equal to half the core diameter, which allows

increase the length of the conductor in section 12 and

13 coils 14 not less than 2 times, and in

to increase the developed effort in the same way.

Unlike the known exciter, where

variable magnetic fluxes are closed

Through two air gaps, representing for them a significant resistance, in the described exciter, the alternating magnetic fluxes can, mines the air gaps, flow along a magnetic conductor with less resistance. This contributes to a more complete compensation of the inductive component of the input impedance of the moving coil and, as a result, increases the uniformity of the amplitude-frequency characteristic of the oscillator.

Claims (2)

Invention Formula Electrodynamic exciter according to aut., Ev, 2.50273, characterized in that, in order to increase the developed force and increase the uniformity of the amplitude-frequency characteristic, the magnetic circuit is equipped with magnetic circuit elements connecting the core ends to the magnetic core. Sources of information taken into account. 1, Genkin M. L, Rusakov A, I, Yablonsky V, B, Electrodynamic Vibrators, M., Mashinostroenie, 1975, p. 18, 2. USSR author's certificate No. 250273, class, H 02K 33/18, 1965 (prototype).