RU94083U1 - MAGNETO-ELECTRIC GENERATOR - Google Patents

Abstract

 A magnetoelectric generator, the rotor of which is equipped with permanent magnets, and the stator contains two parallel plates, between which ring windings are located, characterized in that the rotor is made of two parallel disks mounted on the shaft, on each of which ring-shaped rows of constant are placed on facing surfaces of magnets located in each row equidistantly, the polarity of the permanent magnets of each row alternates, while the poles of the permanent magnets of one row are opposite to the opposite poles of the permanent magnets of a different row, and the stator ring windings are made in the form of isosceles trapezoidal, 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 ring windings are inserted into each other in pairs, while the distance l between the sections of the annular windings in the bases of the trapezoid exceeds the width b of the annular row of permanent magnets.

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 low-speed magnetoelectric generator is known, comprising an annular row of stator windings on iron cores made of sheets or pressed iron powder, and a corresponding annular row of permanent rotor magnets, in particular, a synchronous machine with constant magnetization for sinusoidal voltage, the windings are concentrated and not distributed in grooves, cores with windings alternate with iron cores without windings, so that on every second iron core there is a winding, the number of industrial of creeks between the cores differs from the number of poles, while the number of gaps between the cores s and the number of poles p follows the expressions | sp | = 2 · m and s = 12 · n · m, where n and m are natural numbers, and the machine is designed for three-phase voltage with series connection of adjacent coils to obtain · m such groups per phase that can be connected in series or in parallel, RU 2234788 C2.

The disadvantage of this generator is the low efficiency (efficiency), since the windings in the annular row are at a considerable distance from each other, and at the moment the magnets are in the gap between the windings, the EMF is not induced.

A magnetoelectric generator is also known, the rotor of which is equipped with permanent magnets, and the stator contains two parallel plates in the form of disks connected to each other, between which windings are placed; the stator has magnetic cores in the form of flat rings, RU 2168062.

This technical solution was made as a prototype of this utility model, which has the same drawback as the analogue described above (RU 2234788 C2): low efficiency for the same reason. In addition, when the permanent rotor magnets pass over the stator winding cores, there is a mutual attraction between the permanent rotor magnets and the stator winding cores (the so-called “sticking” effect of the rotor), which makes it difficult to start the generator and creates intense noise during its operation.

The objective of this utility model is to increase the efficiency generator, reducing starting torque and noise level during operation.

According to a utility model, in a magnetoelectric generator, the rotor of which is equipped with permanent magnets, and the stator contains two parallel plates, between which ring windings are placed, the rotor is made of two parallel disks mounted on the shaft, on each of which ring-shaped rows of constant are placed on facing surfaces magnets located in each row equidistantly, the polarity of the permanent magnets of each row alternates, while the poles of the permanent magnets of one row are opposite the positive poles of the permanent magnets of a different row, and the stator ring windings are made in the form of isosceles trapezoidal, 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 ring windings are inserted into each other in pairs, while the distance l between the sections of the annular windings in the bases of the trapezoid exceeds the width b of the annular row of permanent magnets.

The applicant has not identified any technical solutions identical to the claimed one, which allows us to conclude that the utility model meets the criterion of "novelty."

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

figure 1 is a side view;

figure 2 is a section aa in figure 1;

figure 3-adjacent annular windings, paired with each other, in a perspective view;

figure 4 is the same as in figure 3, a top view;

figure 5 is a section bB in figure 4.

The rotor of the magnetoelectric generator is made of two parallel disks 1 and 2, mounted on the shaft 10. In a specific example, the disks 1 and 2 are made of electrical steel. On the surfaces of the disks 1 and 2 facing each other, annular rows of permanent magnets 3 and 4 are placed, respectively. In each annular row, the magnets 3 and 4 are equidistant relative to each other. 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 series (Fig. 1). The stator of the electric generator contains two parallel plates 5 and 6, between which there are ring windings 7, which are made in the form of isosceles trapezoid. The lateral sides 8, 9 of the trapezoid are located radially relative to the longitudinal axis of rotation of the rotor, sections 11, 12 of the windings 7 in the bases of the trapezoid are curved in an arc (figure 5). The windings 7 are paired with each other: inserted into each other (figure 3), while the distance l between sections 11, 12 of the windings 7 exceeds the width b of the annular row of permanent magnets (figure 4). The upstream windings 7 are mounted on the plate 5, and the downstream windings 7 on the plate 6.

Magnetoelectric generator operates as follows. When the rotor rotates with the shaft 10, the magnetic field lines of the permanent magnets 3, 4 intersect the turns of the ring windings 7 and induce an EMF in the windings 7. Since the sides 8, 9 of the ring windings 7 are located between the poles of the magnets with different polarity, induction of multidirectional EMF occurs in the sides 8, 9 of the windings 7 (shown by arrows in figure 2). Thus, an annular electric current flows in each winding 7. The windings mounted on the plate 5 are interconnected, similarly interconnected windings mounted on the plate 6.

Since the conductors of the windings 7 evenly fill the annular gap between the moving magnets 3, 4 (Fig. 5), forming a homogeneous medium for moving magnets, in this design there are no so-called “sticking” of the rotor, which ultimately ensures a noiseless and smooth operation of the generator.

The implementation of the distinguishing features of the utility model provides a new technical result - a more uniform filling of windings of windings of the annular gap between the moving magnets of the rotor, and, accordingly, increasing the efficiency generator, since, practically, there are no interruptions in the induction of EMF characteristic of the prototype.

For the manufacture of the device used conventional structural materials and factory equipment. This circumstance, according to the applicant, allows us to conclude that this utility model meets the criterion of "Industrial applicability".

Claims (1)

A magnetoelectric generator, the rotor of which is equipped with permanent magnets, and the stator contains two parallel plates, between which ring windings are located, characterized in that the rotor is made of two parallel disks mounted on the shaft, on each of which ring-shaped rows of constant are placed on facing surfaces magnets located in each row equidistantly, the polarity of the permanent magnets of each row alternates, while the poles of the permanent magnets of one row are opposite to the opposite poles of the permanent magnets of a different row, and the stator ring windings are made in the form of isosceles trapezoidal, 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 ring windings are inserted into each other in pairs, while the distance l between the sections of the annular windings in the bases of the trapezoid exceeds the width b of the annular row of permanent magnets.