RU2595998C2 - Magnetic bearing - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building, specifically to non-contact bearing assemblies with electromagnetic bearings, and can be used in designing high-speed rotor units. Magnetic bearing for support of rotor to rotate consists of two magnetically conductive rings (1), connected to each other by solid magnetic conducting rods (2), with coils (3). Coils (3) are located around bearing axis parallel to axes, each of coils (3) has a magnetic core and winding (5) providing axial arrangement of magnetic flux. Windings (5) are located on bushings (4) made of insulating material, and bushing (4), in its turn, are located on rods (2), which are cores of coils (3) and connecting two rings (1).

EFFECT: technical result is improvement of manufacturability of magnetic bearing, reliability and ease of repair, as well as widening range of perceived axial loads, due to use of whole core coils.

5 cl, 10 dwg

Description

The invention relates to mechanical engineering, namely to non-contact support nodes with electromagnetic bearings, and can be used to create high-speed rotary assemblies.

Known magnetic support using repulsive magnetic forces according to patent US 2005047430 (application WO 2006074070) in which the rotor and stator have interacting conical elements, made in such a way as to have a gap between them with a significant angle of inclination to the main axis of the support.

Closest to the present invention is a magnetic radial bearing for rotatably supporting a rotor according to patent EP 2012072960 (application WO 2013087360), comprising a stator with a plurality of coils, the coils being arranged circumferentially around the axis of the radial bearing, each of the coils has a core consisting of sheets , and on each core there is a winding, with individual sheets of the core stacked in a circumferential direction, and the windings form the axial organization of the magnetic flux. There can be four pairs of such coils opposed. Each core is made arcuate in the longitudinal direction and has a U-shaped cross section, and the windings are wound around the middle (connecting) part in a direction perpendicular to the axis of the radial bearing. Guides are installed on both sides of the coil on the core. The coil system is installed in two ring housings.

The disadvantage of this device is the difficulty in the manufacture of core cores, as well as low values of perceived axial load.

The technical problem solved by the invention is the use of a single core coil and an increase in the perceived axial load.

The technical problem is solved by the use of rings connected by integral rods with coils mounted on them. The inner holes of the rings can be made cylindrical or conical, and in the latter case, the rotor necks interacting with the rings are also made conical.

The invention is illustrated by the following figures.

In FIG. 1, 2 shows a magnetic bearing with three coils in a group and a cylindrical bore.

In FIG. 3, 4, a magnetic bearing with two coils in a group and a cylindrical bore is shown.

In FIG. 5, 6, a magnetic bearing with two coils in a group and a conical bore is shown.

In FIG. 7 shows the magnetic support of a cylindrical shaft.

In FIG. 8, 9 shows the magnetic bearing of the shafts with conical sections.

In FIG. 10 shows magnetic shaft levitation in magnetic fields.

According to FIG. 1, 2, 3, 4, the magnetic bearing consists of two rings 1, interconnected by solid rods 2, with coils 3 mounted on them, consisting of bushings 4 and containing a winding 5. The rings 1 and rods 2 are made of magnetic materials, while while bushings 4 are made of insulating material. In order to control the currents in the windings 5, the latter are divided into groups, and each group is separated from the neighboring grooves 6 made on the rings 1. The number of groups of coils 3 can be at least three, and the connection of the windings 5 within one group can be either parallel or and consistent. The surface 7, located inside the rings 1, serve as the poles of the magnetic circuits, conducting adjustable magnetic fluxes, providing non-contact support for the shaft 8 (Fig. 7, 8) with constant gaps. The width of the grooves 6 should be approximately 10 times greater than the size of the gap between the shaft 8 and the surfaces 7. Segmented grooves 6 of the surface 7 can be made cylindrical or conical. In the second case, the central hole of one ring 1 is smaller than that of the other, so that surfaces 7 can be located on one cone. In this case, the counterpart of the shaft 8 should have a corresponding cone. The material of the mating parts of the shaft 8 can both coincide with the material of the rings 1, and differ from it, for example, be more magneto-permeable.

By arranging two such bearings in a symmetrical manner (in accordance with FIG. 8 or FIG. 9), the shaft 8 can be held so as to absorb significant axial loads. Depending on the magnitude of the estimated axial load, the angle at the apex of the cone forming the inner surfaces 7 of the rings 1 and the counterparts of the shaft 8 is in the range (varies at the manufacturing stage) from 10 ° to 60 °.

The bearing operates as follows (Fig. 10). When an electric current flows in the windings 5 within each group of windings, a magnetic flux 9 is formed, passing through the rods 2, rings 1 and through the segmented surfaces 7 and creating an electromagnetic force acting on the shaft 8. Due to the fact that the segmented surfaces 7 are located symmetrically on the periphery of the shaft 8, and the change in the electric current and, accordingly, the magnetic flux 9 within each individual group of windings is made according to its own specific algorithm, the magnetic levitation of the shaft 8 is carried out.

The technical result is to increase the manufacturability of manufacturing a magnetic bearing, its reliability and ease of repair, as well as increasing the range of perceived axial loads.

Claims (5)

1. Magnetic bearing for supporting the rotor with the possibility of rotation, containing two magnetically conductive rings, with many coils, and the coils are located around the circumference around the axis of the bearing with parallel axes, each of the coils has a magnetically conductive core and winding, providing axial organization of magnetic flux, different the fact that the windings are on bushings made of insulating material, and the bushings, in turn, are on solid magnetically conductive rods, which are the cores of nis and connecting the two rings. 2. The magnetic bearing according to claim 1, characterized in that the coils are divided into at least three groups due to grooves made on the rings. 3. The magnetic bearing according to claim 2, characterized in that the inner holes of the rings are cylindrical. 4. The magnetic bearing according to claim 2, characterized in that the inner holes of the rings are tapered. 5. The magnetic bearing according to claim 2, characterized in that the angle at the apex of the cone forming the inner holes of the rings is in the range from 10 ° to 60 °.

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