RU2029443C1 - Magnetic system of moving-coil electromechanical transducer - Google Patents

Abstract

FIELD: electromechanical transducers. SUBSTANCE: magnetic system of moving- coil electromechanical transducer has magnetic circuit and permanent magnet. Magnetic circuit is built up of large and small channel bars with permanent magnet placed between them with its opposing poles abutting them. Working gap is formed by external walls of small channel bar sides and internal walls of large channel bar. Large and small channel bars have their bottoms facing opposite sides. EFFECT: improved design. 2 dwg

Description

 The invention relates to instrumentation and can be used in electromechanical devices.

 A magnetic system is known in which permanent magnets in the form of rectangular parallelepipeds are magnetized in the direction perpendicular to the bar on a common lower strip of the magnetic circuit, with one magnetic circuit located between each pair of magnets and one magnet located between each pair of magnetic circuits [1].

 The disadvantage is the small amount of magnetic flux in the working air gap.

 The closest solution is a loudspeaker with an elongated rectangular voice coil.

 A magnetic system of an electromechanical converter with moving coils is described, comprising a magnetic circuit and a permanent magnet. The magnetic core is made in the form of a large (V-shaped) channel and a small (V-shaped) channel, between which a permanent magnet is placed adjacent to them by opposite poles, and the working gap is formed by the outer walls of the shelves of the small channel and the inner walls of the shelves of the large channel. Both channels are facing the bottoms in the same direction [2].

 The disadvantage is the small amount of magnetic flux in the working air gap.

 The purpose of the invention is the increase in magnetic flux in the working air gaps of the magnetic system.

 The essence of the invention lies in the fact that the magnetic system of an electromechanical converter with moving coils contains a magnetic circuit and a permanent magnet, while the magnetic circuit is made in the form of large and small channels, between which a permanent magnet is placed adjacent to them by opposite poles, and the working gap is formed by the outer walls of the small shelves channel and the inner walls of the shelves of the large channel, the large and small channels are facing the bottoms in opposite directions.

 Figure 1.2 shows the magnetic system.

 The permanent magnet 1 is located between two magnetic circuits 2 and 3, made in the form of channels: small 2 and large 3, facing the bottoms in opposite directions. A working air gap 4 is formed between the outer sides of the walls of the channel 2 and the inner sides of the walls of the channel 3. The permanent magnet 1 is adjacent to the bottoms of the channels 2 and 3 by opposite poles.

 The magnetic flux of the permanent magnet 1 is directed to the channel 2 and is divided into two streams in the direction of the working air gaps between the walls of the channels 2 and 3. These magnetic fluxes from the walls of the channel 2 flow through the working air gaps to the walls of the channel 3 and then to the base of the channel 3 and, uniting, they close in a permanent magnet 1.

 The magnetic flux paths in the magnetic system of FIG. 1.2 are smaller than in the prototype, with the same size of the permanent magnet. The magnetomotive force of the permanent magnet in the magnetic system of Fig.1,2 is greater than in the prototype, if the height of the compared magnetic systems will be the same. And in both cases, the magnitude of the magnetic flux in the working gaps in the magnetic system of figure 1.2 is greater than in the prototype.

 The magnetic fluxes of scattering at the end regions of the magnetic circuit are insignificant in comparison with the working magnetic flux and do not affect the results of comparison of two magnetic systems.

 The magnetization of magnet 1 in the magnetic system of Fig.1,2 is carried out in one direction, which allows magnetization in the assembled magnetic system and the use of subcritical magnetic materials having a large magnitude of induction at the maximum point of the energy product of the magnet material.

 The main purpose of the magnetic system is electromechanical actuators, for example, a mechanical type microwave phase shifter drive.

Claims (1)

 MAGNETIC SYSTEM OF ELECTROMECHANICAL CONVERTER WITH MOBILE COILS, containing a magnetic circuit and a permanent magnet, the magnetic circuit is made in the form of a large and small channels, between which a permanent magnet is placed adjacent to them by opposite poles, and the working gap is formed by the outer walls of the shelves a large channel, characterized in that, in order to increase the magnetic flux in the working gap, the large and small channels are turned by the bottoms in the opposite hundred ones.

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