RU194277U1 - MAGNETO-ELECTRIC GENERATOR - Google Patents

Abstract

Usage: in the construction of low-speed electric generators used, in particular in wind power plants. SUBSTANCE: magnetoelectric generator comprises a rotor made of two parallel disks mounted on a shaft, on each of which, on surfaces facing each other, axially ring rows of permanent magnets are placed, the polarity of which alternates in a row and the stator has windings. The poles of the permanent magnets of one row are facing the same poles of the permanent magnets of the other series. The stator windings are made single-layer and equidistantly on an annular magnetic circuit with a step equal to half the step of the permanent magnets, and wound “to fill” with a length equal to the minimum width of the magnets. In this case, the direction of the winding of the windings is reversed in pairs. Technical advantages: increase in efficiency and specific power of the generator while maintaining the lowest starting torque. 2 ill.

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 power installations.

A low-speed magnetoelectric generator is known, comprising a series of stator windings on ferromagnetic cores and a corresponding ring-shaped series of permanent rotor magnets, in particular a synchronous machine with constant magnetization for sinusoidal voltage, where the windings are concentrated and not distributed in grooves; cores with windings alternate with ferromagnetic cores without windings [see US Pat. Russian Federation No. 2234788 for classes Н02К 21/24, Н02К 21/12 published on 08/20/2004 in Bull. No. 23].

The disadvantages of this magnetoelectric generator are low efficiency (power efficiency) and specific power, since the windings in each row are at a considerable distance from each other, and at the time of passage of the magnets in the spaces 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, between which are placed the stator windings, the cores of which are connected at one end to flat ring magnetic circuits [see US Pat. Of the Russian Federation No. 21688062 for class F03D 9/00 published May 27, 2001 in Bull. No. 15].

This technical solution has the same disadvantages as the analogue described above: low efficiency and specific power for the same reason. In addition, during the passage of permanent rotor magnets over the stator winding cores, their mutual attraction (the so-called “sticking” effect of the rotor) occurs, which makes it difficult to start the generator and creates intense noise during operation.

Some increase in efficiency generator and elimination of “sticking” provides a magnetoelectric generator, the rotor of which is equipped with permanent magnets, and the stator contains two parallel dielectric plates, between which are placed in two rows multilayer ring windings 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 at the base of the trapezoid are curved in an arc, while these sections are facing in opposite directions; the rotor is made of two parallel disks mounted on the shaft, on each of which on the surfaces facing each other are ring-shaped rows of permanent magnets, the polarity of the permanent magnets of each row is alternated, while the poles of the permanent magnets of one row are facing the opposite poles of the permanent magnets of the other series, and ring windings are inserted into each other in pairs [see US Pat. Russian Federation №2427067 for classes Н02К 21/24, Н02К 3/24, Н02К 16/02 published on 08/20/2011 in Bul. No. 23].

This device is the closest to the claimed, therefore, is taken as a prototype of this utility model.

The disadvantage of the prototype is that each of its windings, having curved non-magnetized sections with a total length greater than the side sections of magnetization, creates energy losses commensurate with the inevitable losses to induce EMF. This, ultimately, leads to a significant reduction in electrical efficiency generator. In addition, as is known, from Ohm's Law for a magnetic circuit, the magnetic flux in this circuit is inversely proportional to the size of the gap in it. In the prototype, this gap is formed due to the thickness of the multilayer stator winding (see Fig. 5 in the prototype) plus two thicknesses of parallel dielectric plates plus two sizes of the technological gap between the stator and the rotor (see Fig. 1 in the prototype).

Therefore, to compensate for the loss of magnetic flux due to the large gap in the magnetic circuit of the prototype, it is necessary to use more powerful (strong) permanent magnets, which inevitably leads to an increase in their size, and, consequently, to an increase in the mass and dimensions of the generator itself.

The objective of this utility model is to increase the efficiency and specific power of the generator while maintaining the lowest starting torque.

According to a utility model, in a magnetoelectric generator, the rotor of which is made of two parallel disks mounted on a shaft, each of which, on surfaces facing each other, axially arranged ring rows of permanent magnets, the polarity of which alternates in a row, while the poles of the magnets of one row facing the same poles of magnets of another row, and the stator has windings made single-layer and equidistantly on an annular magnetic circuit with a step equal to half the pitch of permanent magnets, with ix winding windings pairwise reversed and performed "to completion" length equal to the minimum width of the magnets.

The applicant has not identified such technical solutions in patent, scientific, technical and other sources of information, the proposed technical solution is new to this field of technology.

A further essence of the proposed technical solution is illustrated in conjunction with illustrative material, which depicts the following: FIG. 1 is a proposed magnetoelectric generator, side view; FIG. 2 is a section along A - A of the magnetoelectric generator shown in FIG. one.

The rotor of the proposed magnetoelectric generator is made of two parallel disks 1 and 2, mounted on the shaft 3. Disks 1 and 2 are made of electrical steel. On the surfaces of the disks 1 and 2 facing each other, axially arranged annular rows of permanent magnets 4 and 5, respectively. In each ring row, magnets 4 and 5 are axially arranged so that their polarity alternates in each row. In this case, the poles of the permanent magnets (4) of one row face the same poles of the permanent magnets (5) of the other row, as shown in FIG. one.

The stator of the proposed magnetoelectric generator is located with technological gaps between the rows of permanent magnets 4 and 5 and is an annular magnetic circuit 6 with single-layer windings 7. Moreover, the windings 7 are located on the magnetic circuit 6 equidistant with a step equal to half the pitch of the permanent magnets 4 and 5, and wound " to fill ”with a length equal to the minimum width of magnets 4 and 5, and the direction of winding of the windings 7 is reversed in pairs (right winding“ P ”through two windings 7, two windings 7 with the left namo with a “L”, etc.). A schematic diagram of the electrical connection of the windings 7 is shown in FIG. 2.

The proposed magnetoelectric generator operates as follows.

When the rotor rotates through the shaft 3, the magnetic lines of the permanent magnets 4 and 5, with the help of the magnetic circuit 6, intersect the turns of the windings 7 and indicate the emf in them.

Due to the fact that the poles of the rows of permanent magnets 4 and 5 face the same poles to each other, in each winding 7, according to the "Rule of the right hand", a unidirectional EMF is induced.

Fundamentally, like the prototype, the claimed generator is a synchronous machine of two-phase alternating current without "sticking", but with almost double electric efficiency and at least several times greater specific power.

Increase in efficiency The claimed device, in comparison with the prototype, is explained by the practical absence in it of a wire that is not involved in the induction of EMF, whereas in the prototype, due to the outer part of the windings curved in an arc, the ohmic energy losses are almost two times higher.

A significant increase in the specific power of the claimed device (W / kg) is explained by a more efficient use of the magnetic flux of permanent rotor magnets, since the non-magnetic gap in their magnetic circuits, due to the single-layer winding of the windings and the absence of two dielectric spacers in the stator design, is several times smaller than at the prototype.

Claims (1)

A magnetoelectric generator, the rotor of which is made of two parallel disks mounted on a shaft, on each of which, on surfaces facing each other, axially annular rows of permanent magnets are placed, the polarity of which alternates in a row, and the stator has windings, characterized in that the poles are constant magnets of one row are facing the same poles of permanent magnets of another series, and the stator windings are single-layer and equidistant on an annular magnetic circuit with a step equal to half the step of constant ma nits and wound "fill up" the length equal to the minimum width of the magnets, the winding direction of the windings of pairwise reversed.

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