SU1095251A1 - Device for magnetizing multipole magnet - Google Patents

Abstract

A DEVICE FOR MAGNETIZING A MULTIPOLUS MAGNET, containing annular magnetic cores and ferrules made of ferromagnetic material and having projections and grooves facing each other and forming a working gap, protrusions and grooves, the number of which is equal to the number of magnetized sections of the multipole magnet, are located in the magnetic grooves and recesses of the section and in a drawing area. magnetizing winding in such a way that in the adjacent parts of the working gap creates counter-magnetic fluxes, characterized in that, in order to The magnetism of the magnets magnetically, cylindrical grooves are made in the lugs of the magnetic core, the connection of sections and tangential jumpers of the winding is made in a collet, and spring elements are installed between the end surfaces of the slots of the magnetic circuit and the sections of the winding.

Description

The invention relates to electrical engineering, and more specifically to devices for magnetizing multipolar stators of electric machines or multipolar cylindrical permanent magnets. A device for magnetizing complex objects is known, containing two identical magnetic cores with a magnetizing winding and protrusions, the end surfaces of which are superimposed on the magnetized object, the magnetizing winding made in the form of shaped tires with loops perpendicularly located in relation to their parts, occupying the space between the magnet magnets. 1. The disadvantage of this arrangement is the low degree of magnetization of the magnets. Closest to the invention to the technical essence is a device for magnetizing a multi-pole magnet, comprising annular magnetic cores and a clip made of a ferromagnetic material and having projections and grooves facing each other and forming a working gap, the number of which is equal to the number of magnetizable sections of the multi-pole magnet, in the grooves the magnetic circuit and the holder are located sections and tangential jumpers detachable magnetizing windings in such a way that in adjacent areas of the working gap are created counter magnetic fluxes 2. A disadvantage of this design is the low magnetisation of the magnets. This is due to the fact that during assembly of the device, the magnetizing winding consists of a series of sections, in the junction points of which there are pass resistances. Taking into account that the active resistance of the winding is extremely small and constitutes the Ohm fraction, the values of the indicated transition resistances must be taken into account when determining the magnetizing current. With a rigid connection of the system, consisting of a magnetic core and a yoke and a magnetized stator, due to inaccuracies of manufacturing, insufficient rigidity of the winding elements, not all elements of the galvanic connection of the winding sections are fully mutually matched. It . leads to an increase in the transient resistance of a number of winding sections and, consequently, to an increase in its impedance, which reduces the magnetising current and decreases the degree of magnetization of the permanent stator magnets. The purpose of the invention is to increase the degree of magnetization of the magnets. The goal is achieved by the fact that in a device for magnetizing a multi-pole magnet containing annular magnetic cores and a clip made of a ferromagnetic material and having projections and grooves facing each other and forming a working gap, the number of magnetized sections of the multi-pole magnet in the magnetic grooves and clamps are located sections and tangential jumpers detachable magnetizing windings in such a way that in the adjacent parts of the working gap creates a counter-magnetic flux The cylindrical grooves are made in the protrusions of the magnetic conductor, the connection of the sections and tangential jumpers of the winding is made with a collet, and spring elements are installed between the end surfaces of the slots of the magnetic conductor and the sections of the winding. FIG. 1 shows a structural diagram of the proposed device; in fig. 2, section A-A in FIG. one; in Fig.-3 - collet connection sections and tangential jumpers winding. The device consists of a magnetic core 1 and a clip 2 made of electrical steel, between which a multi-pole magnetisable magnet (stator) 3 is installed during assembly of the device. In the slots 4 of the magnetic core 1 and the slots 5 of the clip 2, P. or U-shaped sections 6 and 7 are detachable magnetizing winding 8. Sections 6 and 7, located in each of the slots 4 and 5, are mutually fastened. for example, by pouring an epoxy compound. Galvanic connection of sections 6 and 7 is carried out by P or U-shaped tangential jumpers 9. Magnetic circuit 1 has protrusions 10 in which cylindrical grooves 11 are made, concentric to ring magnetic circuit 1. Stator 3 is installed in grooves 11, after that iboyma 2, the end protrusions 12 of which are located opposite the projections 10 of the magnetic circuit 1, and the magnetizable portions of the stator 3, denoted by the pole symbols NS, are located in the slots 4 and 5. The axial dimension of the cylindrical groove 11 is such that when collecting There is an air gap between the end face of the stator 3 facing the magnetic circuit 1 and the end of the groove 11. With this device assembly, galvanic connection of sections 6 and 7 and tangential jumpers 9 occurs. For this, the connection point of said elements 6, 7 and 9 is made in the form of a collet clamp 13, which consists -from the collet 14, made, for example, at connected ends sections 7 and jumpers 9, and a tapered pin 15 with a stop 16, made at the ends of sections 6. The collet connection 13 ensures contact between the connected elements, increases the conductivity of the connection, and also prevents the connection between

Claims (1)

DEVICE FOR MAGNETIZATION OF A MULTI-POLE MAGNET, containing an annular magnetic circuit and a ferrule made of ferromagnetic material and having protrusions and grooves facing each other and forming a working gap, the number of which is equal to the number of magnetized portions of the multi-pole magnet, and tangent sections are located in the grooves of the magnetic circuit and the ferrule of the magnetizing winding in such a way that counter magnetic fluxes are created in adjacent sections of the working gap, characterized in that, in order to increase degrees of magnetization of the magnets, cylindrical grooves are made in the protrusions of the magnetic circuit, the sections and tangential jumpers of the winding are connected with a collet, and spring elements are installed between the end surfaces of the grooves of the magnetic circuit and the winding sections. figure 1