RU139411U1 - MAGNETO-ELECTRIC GENERATOR - Google Patents

Abstract

A magnetoelectric generator including a stator containing a toroidal magnetic circuit with radially spaced teeth, grouped by three teeth in each group, on which the stator windings and a rotor mounted on the shaft are mounted, containing a disk on which a number of permanent magnets with axial magnetization and alternating polarity are mounted, characterized by the fact that the stator toroidal magnetic circuit is made of two parts parallel to each other, the teeth are made on the sides of the magnetic circuit parts facing each other, with The teeth of one part are shifted relative to the teeth of the other part by the width of the tooth, the rotor is located between the parts of the magnetic circuit and is equipped with an additional series of permanent magnets, permanent magnets are mounted on both sides of the rotor disk symmetrically to each other, magnets located on opposite sides of the rotor disk, facing it with opposite poles, each group of teeth of the parts of the magnetic circuit corresponds to a group of two permanent magnets located on the side adjacent to the group of teeth of the rotor disk, when The distance l between the extreme edges of the magnets of each group along an arc concentric with respect to the axis of the rotor and passing in the middle of the magnets corresponds to the distance l along the same arc between the extreme points of the stator windings in each group.

Description

The utility model relates to the field of electrical engineering, namely to low-speed electric generators, and can be used, in particular, in wind energy installations.

A magnetoelectric generator is known, the rotor of which is equipped with permanent magnets, and the stator contains two parallel plates, between which there are ring windings made in the form of isosceles trapezoid, the sides of which are located radially relative to the axis of rotation of the rotor, and the sections of the ring windings in the trapezoid bases are curved in an arc, the rotor is made of two parallel disks fixed to the shaft, on each of which, on the surfaces facing each other, annular rows of constant ma magnets, the polarity of the permanent magnets in each row alternates, while the poles of the permanent magnets of one row are facing the opposite poles of the permanent magnets of the other row, the ring windings are inserted into each other with the formation of modules, while the distance ℓ between the sections of the ring windings in the trapezium bases exceeds the width b ring-shaped series of permanent magnets, characterized in that between the annular windings there is an additional flat annular winding in the form of an isosceles trapezoid, the sides of the second are located in the same plane between the sides of the other ring windings, RU 115978 U1.

The disadvantage of this technical solution is the large gap between the rows of permanent magnets, which leads to a decrease in the magnetic field strength in this gap and, accordingly, the generator power.

A magnetoelectric generator is known, including a stator with a toroidal magnetic circuit with radially spaced teeth, on which stator windings and a disk rotor mounted on a shaft with permanent magnets with axial magnetization and alternating polarity are mounted; each tooth corresponds to a magnet equal in area to it, http://imlab.narod.ru/Energy/Gen_196/Gen_196.htm, 4 s, Fig. 2.1 and 5.1 (a copy of the link is attached).

When the permanent magnets coincide with the teeth of the stator magnetic circuit (Fig. 5.1) due to attractive forces, a large moment of resistance to rotation of the rotor with the shaft (“sticking” of the rotor) occurs, to overcome which it is necessary to significantly increase the starting moment on the generator shaft.

With an increase or decrease in the number of windings per unit compared to the number of magnets, the effect of “sticking” of the rotor is somewhat smoothed out, however, the generator’s efficiency (efficiency) is significantly reduced.

All these disadvantages are also characteristic of a magnetoelectric generator according to RU 2337458 C1, which includes a stator with a toroidal magnetic circuit with radially spaced teeth. The number of coils and, accordingly, teeth, b = 2, 3, 4, 5 ... a positive integer. In the specific example of FIG. 1, 2 in each group contains three teeth. The rotor contains 16 permanent magnets, and the stator magnetic circuit contains 18 teeth with windings. Since the number of magnets and teeth varies, the effect of “sticking” of the rotor is somewhat smoothed, however, the efficiency is significantly reduced. electric car.

The device RU 2337458 C1 adopted as a prototype of this utility model.

In addition to the above, the prototype device has a serious drawback, consisting in the fact that the rotor disk is subjected to attractive forces in one direction, namely, from the rotor to the stator. This causes a significant bending moment acting on the rotor disk, transmitted to the bearings, through which the rotor is mounted on the shaft, which leads to accelerated wear of the bearings. In addition, the specified bending moment requires an increase in the thickness of the rotor disk, which leads to an increase in its mass; this is especially important for generators of wind power units, raised and installed at a height of tens of meters.

The objective of this utility model is to eliminate the effect of “sticking” of the rotor and increase the efficiency, as well as unloading the disk and bearing assembly of the rotor.

According to a utility model, in a magnetoelectric generator comprising a stator containing a toroidal magnetic circuit with radially spaced teeth, grouped into three teeth in each group, on which the stator windings and a rotor mounted on the shaft are mounted, containing a disk on which a series of permanent magnets with axial magnetization and alternating polarity, the stator toroidal magnetic circuit is made of two parts parallel to each other, the teeth are made on the sides of the magnetic circuit parts facing each other and, moreover, the teeth of one of its parts are shifted relative to the teeth of the other part by the width of the tooth, the rotor is located between the parts of the magnetic circuit and is equipped with an additional series of permanent magnets, permanent magnets are mounted on both sides of the rotor disk symmetrically to each other, magnets located on opposite sides of the rotor disk are opposite to each other each other, opposite poles are facing it, each group of teeth of the parts of the magnetic circuit corresponds to a group of two permanent magnets located on the side of the rotor disk adjacent to the group of teeth , The distance ℓ _m between the outermost edges of each group of magnets in an arc concentric with the rotor axis and passing through the middle of the magnets, is the distance ℓ _o of the same arc between the outermost points of the stator windings in each group.

The applicant has not identified any technical solutions identical to the claimed one, which allows us to conclude that the utility model meets the patentability condition “Novelty”.

Due to the implementation of the distinguishing features of the utility model, the rotor, with almost equal effort, is attracted to each of the two parallel parts of the stator. Thus, the disc and the bearing assembly of the rotor are unloaded.

Permanent rotor magnets on each side of the disk are interconnected with no gaps between them and, in practice, form a closed ring contour. Therefore, opposite the entire surface of any tooth of the parts of the stator magnetic circuit, there is always the surface of one or two magnets located on the side of the rotor disk facing this magnetic circuit part. The situation causing the “sticking” of the rotor is excluded when there is a gap between the magnets opposite the tooth surface, as is the case in the prototype device. The extremely insignificant forces of resistance to rotor rotation due to hysteresis during magnetization reversal of the teeth of the stator magnetic circuit can be neglected.

Since all the magnets on both sides of the disk simultaneously and constantly interact with the teeth of the parts of the stator magnetic circuit and, accordingly, with the stator windings, the efficiency increases generator. Thus, a technical result is achieved consisting in unloading the disk and rotor bearings, as well as in the practical exclusion of the forces of resistance to rotation of the generator shaft due to the elimination of the effect of “sticking” of the rotor; efficiency increases generator.

The essence of the utility model is illustrated by drawings, which depict:

in FIG. 1 is a front view with a partial tear;

FIG. 2 is a section A-A in FIG. one;

in FIG. 3 is a section B-B in FIG. one;

in FIG. 4 is a section C-C in FIG. one;

in FIG. 5 is a schematic illustration of a group of teeth on one of the parts of the stator toroidal magnetic circuit with windings and permanent magnets located above them;

in FIG. 6 is a section D-D in FIG. 5;

in FIG. 7 - a group of teeth of a toroidal stator magnetic circuit with windings in a perspective view;

in FIG. 8 - magnetoelectric generator assembly in a perspective view with a partial tear.

The magnetoelectric generator includes a stator containing a toroidal magnetic circuit made of two parallel parts 1 and 2. On each side of the parts 1, 2 of the toroidal magnetic circuit facing each other, teeth 3, 4, respectively, are made. The teeth of one part of the magnetic circuit are shifted relative to the teeth of the other part by the width of the tooth. The teeth are grouped into three teeth in each group. The number of teeth in the group determines the phase of the generator, that is, with three teeth in the group, the generator is three-phase. On the teeth 3, 4 are placed windings 5, 6 of the stator. A rotor comprising a disk 8 is mounted on the shaft 7. Permanent magnets 9 and 10, respectively, are symmetrically mounted on the disk 8 on both sides of the disk 8. Magnets located on opposite sides of the rotor disk 8 facing each other face the disk 8 with opposite poles. Magnets 9 and 10 have axial magnetization. The polarity of the magnets in each row alternates. Each group of teeth 3, 4 corresponds to a group of two permanent magnets 9 or 10 of the rotor, respectively. The distance ℓm between the extreme edges of the magnets of each group along the arc, the concentric axis of the rotor and passing through the middle of the magnets, corresponds to the distance ℓ _o along the same arc between the extreme points of the stator windings in each group (Fig. 5, 6).

The magnetoelectric generator comprises a housing 11 with a cover 12.

Magnetoelectric generator operates as follows. When the shaft 7 is rotated with the rotor disk 8, the magnetic field lines of the permanent magnets 9, 10 induce an alternating magnetic field in the teeth 3, 4, respectively, which causes the appearance of an EMF in the stator windings 5, 6. Since there are no gaps between the permanent magnets in each row, the surface of one or two permanent magnets 9, 10 is always facing the surface of each tooth 3, 4, respectively. In addition, since the teeth 3 of part 1 of the stator magnetic circuit are shifted by the width of the tooth relative to the teeth 4 of part 2 of the stator magnetic circuit, any of the permanent magnets 9, 10 in any position of the rotor interacts with the surface of the teeth of 3.4 always equal to the sum of the surfaces of 3 teeth. Thus, the alignment of the rotor attraction to both parts of the stator magnetic circuit is ensured. As a result, “sticking” of the rotor is excluded; all magnets always and fully induce EMF in the stator windings, which ensures an increase in efficiency in comparison with the prototype. The phase shift of the EMF in the windings on adjacent teeth of each group (Fig. 5, 6, 7) is 120 °, which ensures the generation of a three-phase electric current.

A prototype device has been manufactured and tested.

The magnetoelectric generator can also operate in electric motor mode.

Claims (1)

A magnetoelectric generator including a stator containing a toroidal magnetic circuit with radially spaced teeth, grouped by three teeth in each group, on which the stator windings and a rotor mounted on the shaft are mounted, containing a disk on which a number of permanent magnets with axial magnetization and alternating polarity are mounted, characterized by the fact that the stator toroidal magnetic circuit is made of two parts parallel to each other, the teeth are made on the sides of the magnetic circuit parts facing each other, with The teeth of one part are shifted relative to the teeth of the other part by the width of the tooth, the rotor is located between the parts of the magnetic circuit and is equipped with an additional series of permanent magnets, permanent magnets are mounted on both sides of the rotor disk symmetrically to each other, magnets located on opposite sides of the rotor disk, facing it with opposite poles, each group of teeth of the parts of the magnetic circuit corresponds to a group of two permanent magnets located on the side adjacent to the group of teeth of the rotor disk, when The distance l _m between the extreme edges of the magnets of each group along an arc concentric with respect to the axis of the rotor and passing in the middle of the magnets corresponds to the distance l _o along the same arc between the extreme points of the stator windings in each group.

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