WO2007008110A1

WO2007008110A1 - Magnetic rotor system

Info

Publication number: WO2007008110A1
Application number: PCT/RU2006/000339
Authority: WO
Inventors: Andreiy Vladimirovich Sagalovskiiy; Vladimir Iosifovich Sagalovskiiy; Olga Nikolaevna Gmyzina; Dmitriiy Aleksandrovich Shkad
Original assignee: Oilfield Equipment Development Center Limited
Priority date: 2005-07-14
Filing date: 2006-06-29
Publication date: 2007-01-18
Also published as: RU2316103C2; RU2005122305A

Abstract

The invention belongs to the field of electric equipment and in particular to the technical realization of magnetic systems of magnetoelectric rotors of collectorless machines, and can be used in motors or generators. The magnetic rotor system consists of a stack of plates of magnetically conducting steel comprising V-shaped openings, and permanent magnets having the shape of a prism with a tangential magnetic load N-S. The magnets forming a pole pitch are mounted in the openings of the plates with a slope compared to the radial axis and are in contact by their poles having the same sign. Under the magnets forming the pole pitch nonmagnetic inserts can be mounted. The invention makes it possible to reduce dispersion flows in the case of a tilted slope of the magnets and, consequently, to increase the useful magnetic flow and to keep the radial dimensions of the motor.

Description

Rotor magnetic system

The technical field to which the invention relates. The invention relates to the field of electrical engineering and relates to the design of magnetic systems of rotors of brushless magnetoelectric machines. The inventive device can be used both in engines and generators, and can improve the technical characteristics of electrical machines of these classes. State of the art

Known magnetic rotor system, consisting of a package of solid disk-shaped plates with radial rectangular grooves in which tangential permanent magnets are placed (see patent GB 1263300, publ. 09.02.72 class. H 02 K 1/28). This magnetic system has a low value of the working magnetic flux, which is due to significant scattering fluxes and small radial dimensions of the magnets, limited by the radial dimension of the rotor.

Known magnetic rotor system, consisting of a package of disco-shaped plates with radial rectangular grooves with different placed in them by tangential permanent magnets, which is equipped with bursts of wedge-shaped plates, placed along the axis in alternating order with disk-shaped plates to reduce the dispersion flux (see a.s. SU 1098070, publ. 15.06.84, class. H 02 K 1 / 06).

This magnetic system, despite the decrease in the dispersion flux, has a low value of the working magnetic flux, which is due to the small radial dimensions of the magnets, limited by the radial dimension of the rotor. In addition, the specified magnetic system has a low manufacturability due to the need to use for assembly of a package of welding plates or special connecting elements.

Closest to the technical nature of the claimed invention is a magnetic rotor system consisting of a package of plates of magnetically conductive steel with holes, and permanent prismatic magnets with tangential magnetization NS mounted in the holes of the plates with an inclination to the radial axis so that the distance between the opposite the poles of two adjacent magnets along the outer arc are less than the inner (see patent RU 2244370, publ. 10.01.03, class H 02 K 1/06). This magnetic system, in comparison with the above-described designs, allows, due to the inclined installation of magnets, either to increase the radial size of the magnets for a given radial dimension of the rotor, and therefore to increase the value of the working magnetic flux, or, while maintaining the working magnetic flux, to reduce the radial dimensions of the rotor. In addition, this design allows you to get a finished magnetic rotor system with an even number of poles in the complete absence of requirements for the magnetic properties of the material of the rotor shaft. However, with this design, significant scattering fluxes are maintained, which are closed between the magnets facing each other by the same poles through the jumper between the holes, which leads to a decrease in the working magnetic flux, and as a result to a decrease in the energy indices of the magnetoelectric machine

Disclosure of invention

The problem to which the invention is directed is to increase the energy performance of a magnetoelectric machine while maintaining the high adaptability of the rotor design.

The technical result achieved by the implementation of of the inventive invention, is to reduce the dispersion flux with an inclined installation of magnets and, as a consequence, to increase the working magnetic flux.

The specified technical result by the claimed invention is achieved due to the fact that in the magnetic system of the rotor, consisting of a package of plates of magnetically conductive steel with holes and permanent magnets of a prismatic shape with tangential magnetization NS, installed in the holes of the plates at an angle to the radial axis so that the distance between different the nominal poles of two adjacent magnets along the outer arc are smaller than the inner, the holes are made V-shaped, and the magnets installed in them forming the pole division e, touch the poles of the same name.

In the particular case of the invention, in order to further reduce the scattering fluxes, non-magnetic inserts can be installed under the magnets forming the pole division.

The implementation of the invention

Fig. 1 - Configuration of plates of magnetic steel. Fig. 2 - Fragment of the magnetic system of the rotor with magnets installed. The rotor magnetic system consists of a package of plates 1 made of magnetically conductive steel. V-shaped holes 2 are made in the plates 1, in which the permanent magnets of the prismatic form 3 and 4 are formed, forming the pole division. The number of V-shaped holes depends on the required number of poles of the magnetic system. Magnets 3 and 4 have a tangential magnetization NS and are in contact with the same poles. In the center of the plates 1, a circular hole 5 is made through which the rotor shaft passes. To connect the package to the rotor shaft and transmit the torque, the plates 1 have a protrusion 6. Under the magnets forming the pole division, non-magnetic inserts 7 are placed.

Due to the V-shaped shape of the holes 2, the magnets 3 and 4 are located at an angle to the radial axis. Like the well-known magnetic system, this allows either to increase the working magnetic flux, for a given radial dimension of the rotor (by increasing the radial size of the magnets) or to maintain the working magnetic flux, to reduce the radial dimensions of the rotor, and also allows to obtain a finished magnetic rotor system with an even the number of poles in the complete absence of requirements for the magnetic properties of the material of the rotor shaft. Due to the fact that the magnets Those who are involved in pole division are in contact with the poles of the same name, the scattering fluxes decrease, and the working magnetic flux increases. An additional decrease in dispersion fluxes is achieved by installing non-magnetic inserts under the magnets forming the pole division, which significantly increases the energy performance of the magnetoelectric machine.

Claims

Claim

1. The rotor magnetic system, consisting of a package of plates of magnetically conductive steel with holes, and permanent prismatic magnets with tangential magnetization NS ₅ mounted in the holes of the plates at an angle to the radial axis so that the distance between the opposite poles of two adjacent magnets along the outer arc less than internal, characterized in that the holes are made V-shaped, and the magnets installed in them, forming the pole division, are in contact with the same poles

2. The rotor magnetic system according to claim 1, characterized in that non-magnetic liners are installed under the magnets forming the pole division.