UA127886C2 - MAGNETIC AXIAL DEVICE - Google Patents

Abstract

The invention relates to magnetic axial devices used as motors or generators for the production of electrical energy. The magnetic axial device includes mounted on the shaft at least one stator with magnetic components, at least part of which is located on the limited peripheral annular area of at least one of its disk-shaped ends, which is the perspective zone of this disk-shaped end of the stator, and at least one disk-shaped rotor with magnetic components, made of the possibility of axial rotation and interaction with the specified stator, in which at least part of the magnetic components is placed on a limited peripheral annular area, which is the perspective zone of this side of the disk-shaped rotor, turned to the disk-shaped end of the stator with magnetic components. At the same time, the surfaces of the interacting magnetic components of the stator and rotor have compatible volumetric shapes. The design of the device ensures high efficiency of its operation.

Description

The invention belongs to electrical engineering, namely to magnetic axial devices, and can be used in electric machines used as motors or generators in sectors of industry related to systems and devices for the production of electrical energy.

All magnetic axial devices with any number of stators and rotors, as well as their various types and combinations as part of electric machines, are designed and created taking into account various design parameters that must provide the functions for which they are intended. At the same time, for any design of the device for the production of electricity, the efficiency of its operation remains an important issue.

Devices that generate magnetic electrical energy under the influence of kinetic energy or operate as a magnetic drive motor under the influence of electrical energy are known from the prior art.

A known electric machine with permanent magnets, which contains a ring stator, in the grooves of which a winding is placed, a rotor made in the form of a ferromagnetic disk, on the surface of which magnets are placed from the stator side, between which non-magnetic inserts are installed and covered by a non-metallic bandage, made in the form of a cup with by two concentric walls of different heights, between which magnets are installed and which are connected to each other by a bottom directed towards the stator (invention patent, Shaa 106842 C2, published on 10.10.2014 (11). In the known device, the height of the smaller wall placed inside the bandage bowl equal to the height of the magnet, and the wall of the bandage of greater height covers both the disc and the magnets.At the same time, the disc and the cup are connected by a fastener through the inner wall.

The well-known design of the electric machine provides a fairly reliable fixation of the magnets, but due to structural flaws that lead to uneven distribution of the flow, it has a low torque, low power, low efficiency, which leads to low efficiency of its operation.

The closest thing is a magnetic axial device, which includes at least one stator with magnetic components installed on the shaft, and at least one disk-shaped rotor with magnetic components, made with the possibility of axial rotation and interaction with the specified stator (European patent application, EP Z 512 082 AT, published 17.07.2019

I2I). A known magnetic axial device is adapted for use as a generator

From electricity, if kinetic energy is used, or as a magnetic drive motor, if electric energy is used, and has a first disk-shaped rotor with several magnetic poles and a second disk-shaped rotor with several magnetic poles placed on the shaft, between which is mounted a stator consisting of at least two coils, each of which has a magnetic component in the form of a core of magnetic material. At the same time, the magnetic poles in both disk-shaped rotors are located radially with successively changing polarity - positive and negative. At least two cores have a configuration with inclined ends on both sides in the same direction relative to the shaft in such a way as to create a body whose development in the frontal plane is approximately diamond-shaped. In addition, the known magnetic axial device additionally includes an external element that drives the first disc-shaped rotor.

The known magnetic axial device allows you to create a sufficiently large magnetic field, which increases the power of the electrical energy produced, however, like the previous analog, it has a low torque, low power, low efficiency, which leads to low efficiency of its operation.

The reason for the invention was the impossibility of meeting the needs for effective magnetic axial devices with high torque, power and efficiency.

The task of the invention is to improve the magnetic axial device, in which, due to the proposed implementation of its elements and the connections between them, an increase in torque, an increase in power and an increase in efficiency are ensured, which leads to an increase in the efficiency of its operation.

The task is solved by the proposed magnetic axial device, which includes at least one stator with magnetic components and at least one disc-shaped rotor with magnetic components installed on the shaft, made with the possibility of axial rotation and interaction with the specified stator, in which the stator has two disc-shaped ends, while, at least a part of the magnetic components of the stator is located on a limited peripheral annular area of at least one of its disk-shaped ends that interacts with the specified rotor, and the specified limited peripheral annular area is a perspective zone of this disk-shaped end of the stator, at least a part of the magnetic components of the disk-shaped rotor is located on a limited or peripheral annular area at least on one side of the disk-shaped rotor, turned to the disk-shaped end of the stator with magnetic components, and the specified limited peripheral annular area is the perspective zone of this side of the disk-shaped rotor, while the surfaces of the magnetic components of the perspective zone of the disk-shaped stator end and the surfaces of the magnetic components of the perspective zone interacting with them disk-shaped rotor, or the surfaces of the magnetic components of the perspective zone of the two disk-shaped ends of the stator and the surfaces of the magnetic components of the perspective zone of the corresponding disk-shaped rotor interacting with them have compatible volumetric shapes that increase the area of interaction of magnetic components in the region of a limited area.

In the proposed magnetic axial device, the distance from the center of the shaft axis to the near border of the perspective zone of the disk-shaped end of the stator is 0.65...0.75 radius in the plane of this disk-shaped end of the stator, and the distance from the center of the shaft axis to the near border of the perspective zone of the side of the disk-shaped rotor , which interacts with the specified stator, is 0.65...0.75 of the radius in the plane of this side of the disk-shaped rotor.

In the proposed magnetic axial device, the surface area of the perspective zone of the stator disk-shaped end, which includes the sum of the surface areas of the magnetic components and the stator sections of the perspective zone of the stator disk-shaped end, is at least 1.25 of the area of the limited peripheral annular section in the plane of the corresponding disk-shaped stator end, and the surface area the perspective zone of the disc-shaped rotor, which interacts with the specified stator and includes the sum of the areas of the surfaces of the magnetic components and areas of the disc-shaped rotor of the perspective zone of the disc-shaped rotor, is at least 1.25 of the area of the limited peripheral annular section in the plane of this disc-shaped rotor.

In the best embodiment of the invention, the magnetic axial device includes a first disk-shaped rotor with magnetic components and a second disk-shaped rotor with magnetic components placed on the shaft, between which a stator with magnetic components is installed. At the same time, at least part of the magnetic components of the stator are located on the limited peripheral annular area of one disk-shaped end of the stator and on the limited peripheral annular area of the second disk-shaped end of the stator, which represent, respectively, the zone of prospects of the first disk-shaped end of the stator, and the zone of prospects of the second disk-shaped end of the stator,

At least a part of the magnetic components of the first disk-shaped rotor are located on a limited peripheral annular area on one side of this disk-shaped rotor, turned to the first disk-shaped end of the stator, which is the perspective zone of the first disk-shaped rotor, and at least a part of the magnetic components of the second disk-shaped rotor are located on a limited peripheral annular area on one side of this disk-shaped rotor, turned to the second disk-shaped end of the stator, which is the perspective zone of the second disk-shaped rotor, and compatible volumetric shapes have the surfaces of the magnetic components of the perspective zone of the first disk-shaped end of the stator and the surfaces of the magnetic components of the perspective zone of the first disk-shaped rotor interacting with them , as well as, the surfaces of the magnetic components of the perspective zone of the second disk-shaped end of the stator and the surfaces of the magnetic components of the perspective zone of the second disk-shaped rotor interacting with them.

In the specified version, the distance from the center of the shaft to the near boundary of the perspective zone of the first disk-shaped end of the stator and the distance from the center of the shaft to the near boundary of the perspective zone of the second disk-shaped end of the stator is 0.65...0.75 radius in the plane of the corresponding disk-shaped end of the stator , the distance from the center of the shaft axis to the near boundary of the perspective zone of the first disk-shaped rotor and the distance from the center of the shaft to the near boundary of the perspective zone of the second disk-shaped rotor is 0.65...0.75 radius in the plane of the corresponding rotor, the surface area of the perspective zone of the first disk-shaped rotor of the stator end, which includes the sum of the surface areas of the magnetic components and the stator sections of the perspective zone of the first disk-shaped stator end, and the surface area of the perspective zone of the second disk-shaped stator end, which includes the sum of the surface areas of the magnetic components and the stator sections of the perspective zone of the second disk-shaped stator end, are at least 1.25 of the area of the limited peripheral annular area in the plane of the corresponding disk-shaped end of the stator, the surface area of the perspective zone of the first disk-shaped rotor, which includes the sum of the areas of the surfaces of the magnetic components and the areas of the first disk-shaped rotor of the perspective zone of the first disk-shaped rotor, and the surface area of the perspective zone of the second disk-shaped rotor, which includes the sum of the surface areas of the magnetic components and the areas of the second 60 disk-shaped rotor of the perspective zone of the second disk-shaped rotor, are at least

1.25 of the area of the limited peripheral annular area in the plane of the corresponding disk-shaped rotor.

Permanent magnets and/or electromagnets, and/or electromagnets without a core, and/or coils are used as magnetic components of the disk-shaped stator end or disk-shaped stator ends and as magnetic components of the disk-shaped rotor or disk-shaped rotors.

The magnetic axial device described above is an electric motor or generator.

Experimentally, the author discovered a binding zone and a zone of prospects for the placement of interacting magnetic components on the disk-shaped ends of the stator and on the disk-shaped rotor, which made it possible to exclude the binding zone of the magnetic axial device for placing magnetic components, and also found the necessary shape of the surfaces of the interacting magnetic components, namely the presence of volume to increase the area of interaction of magnetic components in a limited space, which collectively influenced the design of the magnetic axial device and provided the opportunity to increase its efficiency due to increased torque, increased power, increased efficiency, and also expanded performance combinations.

New features of the invention are highlighted in the claims, but the following drawings show some variants of the invention for the purpose of a more complete explanation, which demonstrates, but does not limit, the invention.

The invention is demonstrated, but not limited to, by the following illustrations: FIG. 1 - a schematic view of a magnetic axial device with one rotor; fig. 2 - a schematic view of a magnetic axial device with two rotors; fig. C - zone of perspectives of the disk-shaped end of the stator of the magnetic axial device shown in fig. 1; fig. 4 - disk-shaped end of the stator of the magnetic axial device shown in fig. 3, with magnetic components; fig. 5 - zone of perspectives of the disc-shaped rotor of the magnetic axial device shown in fig. 1; fig. 6 - the side of the disk-shaped rotor of the magnetic axial device shown in fig. 5, with magnetic components;

From fig. 7 - perspective zone of the first disc-shaped end of the stator of the magnetic axial device shown in fig. 2; fig. 8 - the first disc-shaped end of the stator of the magnetic axial device shown in fig. 7, with magnetic components; fig. 9 - zone of perspectives of the second disk-shaped end of the stator of the magnetic axial device shown in fig. 2; fig. 10 - the second disc-shaped end of the stator of the magnetic axial device shown in fig. 9, with magnetic components; fig. 11 is a zone of perspectives of the first disc-shaped rotor of the magnetic axial device shown in fig. 2; Fig. 12 is the side of the first disc-shaped rotor of the magnetic axial device shown in Fig. 11, with magnetic components; fig. 13 - zone of perspectives of the second disk-shaped rotor of the magnetic axial device shown in fig. 2; Fig. 14 is the side of the second disk-shaped rotor of the magnetic axial device shown in Fig. 11, with magnetic components; fig. 15 - a fragment of the surface of the magnetic component with a "triangular" relief; fig. 16 - a fragment of the surface of a magnetic component with a "plate" relief.

When explaining the invention, abbreviations are used that within the scope of this description mean the following: 5-P2 - zone of perspectives of the disc-shaped end of the stator;

З-РАз - zone of perspectives of the first disc-shaped end of the stator; 5-P2 - zone of perspectives of the second disk-shaped end of the stator;

В-Р - perspective zone of the side of the disk-shaped rotor;

В-РАз - zone of perspectives of the side of the first disc-shaped rotor;

B-P2" - the perspective zone of the side of the second disk-shaped rotor;

Iv - the distance from the center of the shaft axis to the near boundary of the perspective zone of the disc-shaped end of the stator;

East - the distance from the center of the shaft axis to the near boundary of the perspective zone of the first disc-shaped end of the stator;

Isg - the distance from the center of the shaft axis to the near boundary of the perspective zone of the second disk-shaped end of the stator;

Iv - the distance from the center of the shaft axis to the near border of the perspective zone of the side of the disk-shaped rotor;

Ii - the distance from the center of the shaft axis to the near border of the perspective zone of the side of the first disk-shaped rotor;

Iya2 - the distance from the center of the shaft axis to the near border of the perspective zone of the side of the second disk-shaped rotor; d - the radius of the disc-shaped end of the stator; gv1 - the radius of the first disk-shaped end of the stator; gv2 - the radius of the second disc-shaped end of the stator;

Tv is the radius of the disk-shaped rotor side;

Tv: - the radius of the side of the first disc-shaped rotor;

Gvo - the radius of the side of the second disk-shaped rotor;

Zv-g7 - surface area of the perspective zone of the disc-shaped end of the stator;

ZvirR - the area of the limited annular section of the disc-shaped end of the stator in the plane;

Zv-g7 - surface area of the perspective zone of the disc-shaped rotor;

ZniR - the area of the limited annular section of the disc-shaped rotor in the plane;

Zvme is the surface area of the magnetic component of the stator;

Znms - the surface area of the magnetic component of the rotor;

Zvilmm - the surface area of the stator section without a magnetic component in the stator perspective zone;

Zn/m - the surface area of the rotor section without a magnetic component in the rotor perspective zone.

The described implementation options are described schematically and in partial views. In some cases, details that are not necessary for understanding the present invention or represent other details that are difficult to understand are not shown. Also, it should be noted that this invention is not limited to the specific embodiments described.

The magnetic axial device (Fig. 1, Fig. 2) includes installed on the shaft at least one disk-shaped stator with magnetic components and at least one disk-shaped rotor with magnetic components, made with the possibility of axial rotation and in interaction with the indicated stator.

In fig. 1 schematically presents a magnetic axial device 1, which includes a stator C with magnetic components mounted on a shaft 2 and a disc-shaped rotor 4 with magnetic components interacting with it. Stator C has two disk-shaped ends, on one of which, the disk-shaped end 5, on its limited peripheral annular area, which is the perspective zone 6 (5-P7) of this disk-shaped end 5, at least part of the magnetic components 7 of stator C are located (Fig. C - Fig. 4). Their distance from the center of the shaft axis 2 to the near border of the perspective zone 6 in the plane of the disk-shaped end 5 of the stator Z is from 0.65 to 0.75 of the radius 15 of this disk-shaped end. At least part of the magnetic components 8 of the disk-shaped rotor 4 are placed on one side 9 of it, turned to the disk-shaped end 5 of the stator 3. At the same time, the magnetic components 8 are installed on the limited peripheral annular area of the side 9, which is the perspective zone 10 (B-P2) of this side 9 disk rotor 4 (Fig. 1, Fig. 5 - Fig. 6). The distance Iv from the center of the axis of the shaft 2 in the plane of the disk-shaped rotor 4 to the near border of the perspective zone 10 of the side 9 that interacts with the stator 3 is from 0.65 to 0.75 of the radius g of this side 9 of the disk-shaped rotor 4. The surfaces of the magnetic components of the zone 7 perspectives b of the disc-shaped end face 5 of the stator C and the surfaces of the magnetic components interacting with them 8 of the perspective zone 10 of the disc-shaped rotor 4 have compatible volumetric shapes.

The described design is one of the implementation options (an example of an embodiment of the invention), namely, a single-rotor magnetic axial device.

In fig. 2 schematically presents the magnetic axial device 11, which includes a first disk-shaped rotor 13 with magnetic components and a second disk-shaped rotor 14 with magnetic components mounted on a shaft 12, between which a stator 15 with magnetic components is installed. The stator 15 has a first disk-shaped end 16 and a second disk-shaped end 17. At the same time, at least part of the magnetic components 18 of the stator 15 is located on the limited peripheral annular area of the first disk-shaped end 16, which is the perspective zone 20 (5-R) of this first disk-shaped end 16 of the stator 15; at least part of the magnetic components 19 of the stator 15 is located on the limited peripheral annular area of the second disc-shaped end 17, which is the perspective zone 21 (5-

Рg) of this second disk-shaped end 17 of the stator 15 (Fig. 7 - Fig. 10). The distance Iz: from the center of the axis of the shaft 12 to the near border of the perspective zone 20 in the plane of the first disk-shaped end 16 of the stator 15 is from 0.65 to 0.75 of the radius r: of this first disk-shaped end 16 of the stator 15 (Fig. 7). The distance is from the center of the shaft 12 to the near border of the perspective zone 21 in the plane of the second disk-shaped end 17 of the stator 15 is from 0.65 to 0.75 of the radius g52 of this second disk-shaped end 17 of the stator 15 (Fig. 9).

At least part of the magnetic components 24 of the first disk-shaped rotor 13 are located on a limited peripheral annular area, which is the zone of perspectives 23 (B-P) of its side 22, turned to the first disk-shaped end 16 of the stator 15 (Fig. 2, Fig. 11).

At least part of the magnetic components 27 of the second disk-shaped rotor 14 is located on a limited peripheral annular area, which is the perspective zone 26 (K-P72) of its side 25, turned to the second disk-shaped end 17 of the stator 15 (Fig. 2, Fig. 13). Distance Iv: from the center of the axis of the shaft 12 to the near border of the perspective zone 23 in the plane of the side 22 of the first disk-shaped rotor 13, which interacts with the first disk-shaped end 16 of the stator 15, is from 0.65 to 0.75 of the radius of this side 22 of the first disk-shaped rotor 13 (fig. 11); the distance ng from the center of the shaft axis 12 to the near border of the perspective zone 26 in the plane of the side 25 of the second disc-shaped rotor 14, which interacts with the second disc-shaped end 17 of the stator 15, is from 0.65 to 0.75 of the radius gvg of this side 25 of the second disc-shaped rotor 14 (fig. 13). The surfaces of the magnetic components 18 of the perspective zone 20 of the first disk-shaped end 16 of the stator 15 and the surfaces of the magnetic components 24 of the perspective zone 23 of the first disk-shaped rotor 13 interacting with them have compatible volumetric shapes. The surfaces of the magnetic components 19 of the perspective zone 21 of the second disk-shaped end 17 of the stator 15 and the surfaces of the magnetic components 27 of the perspective zone 26 of the second disk-shaped rotor 14 interacting with them have compatible volumetric shapes.

The described design is another variant of the invention, namely a two-rotor magnetic axial device.

In addition, the described variants can be modules of a multi-rotor and multi-stator magnetic axial device.

In the examples described above of the claimed magnetic axial device, the three-dimensional shape of the magnetic components can have a different relief, including "triangular", "lamella" (Fig. 15 - Fig. 16) and others. The surface area of the disc-shaped perspective zone

From the end of the stator (55-27), which includes the sum of the surface areas of the magnetic components of the disk-shaped stator end (X Ovms) and the sum of the surface areas of the sections of the stator end without magnetic components in the perspective zone of the disk-shaped stator end (X ОЗвдмм), is at least 1.25 the area of the limited peripheral annular section (vv) in the plane of the corresponding disc-shaped end of the stator, and the surface area of the perspective zone of the disc rotor (v.g), which interacts with the specified stator and includes the sum of the surface areas of the magnetic components of the disc rotor (Х Овмс) and the sum of the surface areas areas of the disc rotor without magnetic components in the disc rotor perspective zone (U Ondm/m), is at least 1.25 of the area of the limited peripheral ring area (Oviv) in the plane of this disc rotor (Fig. 4, Fig. b, Fig. 8, Fig. 10, Fig. 12, Fig. 14).

That is:

Zv - HU Zemo z X Ovaimum 2 1.25 x Beast (1);

Zv-gy - X Zvmo same X Znamum 2 1.25 x Znav (2).

Magnetic elements having magnetic poles are used as magnetic components of the disk-shaped stator end or disk-shaped stator ends and as magnetic components of the disk-shaped rotor or disk-shaped rotors, namely: permanent magnets and/or electromagnets, and/or electromagnets without a core, as well as coils.

A magnetic axial device works as a magnetic drive motor when electrical power is applied, as follows.

Stator Z (Fig. 1) is supplied with current pulses of the appropriate polarity, which provides repulsion or attraction of magnetic components 7 located in the perspective zone 6 of the stator 3 and magnetic components 8 located in the perspective zone 10 of the disc-shaped rotor 4. As a result of excitation of the magnetic field of the required polarity, the rotational movement of the disk-shaped rotor 4 is created.

In the case of a two-rotor magnetic axial device (Fig. 2), current pulses of the appropriate polarity are applied to the stator 15, which ensures the repulsion or attraction of the magnetic components 18 located in the perspective zone 20 of the first disc-shaped end 16 of the stator 15 and the magnetic components 24 located in the perspective zone 23 of the first disk-shaped rotor 13, and the repulsion or attraction of magnetic components 19 located in the perspective zone 21 of the second disk-shaped end 17 of the stator 15 and magnetic components 27 located in the perspective zone 26 of the second disk-shaped rotor 14. As a result of the excitation of the magnetic field of the required polarity, the rotational movement of the disk-shaped rotors 13 and 14.

In the generator mode, the magnetic axial device works as follows.

The rotational movement of the disc-shaped rotor 4 (Fig. 1) or the rotational movement of the first and second disc-shaped rotors 13 and 14 (Fig. 2) due to external traction creates a magnetic field that excites the electric current in the stator C (Fig. 1) or in the stator, respectively 15 (Fig. 2).

The proposed magnetic axial device made it possible to ensure high torque, high power and high efficiency of the device due to the placement of magnetic components in a certain limited area and certain performance of their interacting surfaces.

Claims (1)

FORMULA OF THE INVENTION 1. A magnetic axial device, including at least one stator with magnetic components and at least one disk-shaped rotor with magnetic components installed on the shaft, made with the possibility of axial rotation and interaction with the specified stator, which is characterized by the fact that the stator has two disk-shaped ends, at least part of the magnetic components of the stator is located on the limited peripheral annular area of at least one of its disk-shaped ends that interacts with the specified rotor, and the specified limited peripheral annular area is the perspective zone of this disk-shaped end of the stator, at the same time, the distance from the center of the shaft axis to the near border of the perspective zone of the disk-shaped end of the stator is 0.65-0.75 radius in the plane of this disk-shaped end of the stator, at least a part of the magnetic components of the disk-shaped rotor is located in a limited peripheral annular region on at least one side of the disk-shaped rotor facing the disk-shaped end of the stator with magnetic components, and the specified limited peripheral annular section is the perspective zone of this side of the disk-shaped rotor, while the distance from the center of the shaft axis to the near border of the perspective zone of the side of the disk-shaped rotor that interacts with the indicated stator is 0.65-0.75 radius in the plane of this side of the disk-shaped rotor, From the surface of the magnetic components of the perspective zone of the disc-shaped end of the stator and the surfaces of the magnetic components of the perspective zone of the disc-shaped rotor interacting with them, or the surfaces of the magnetic components of the perspective zone of two disc-shaped ends of the stator and the surfaces of the magnetic components of the perspective zone of the corresponding disc-shaped rotor interacting with them, have compatible volumetric shapes, while , the surface area of the perspective zone of the stator disc-shaped end, which includes the sum of the surface areas of the magnetic components and the stator areas of the perspective zone of the stator disc-shaped end, is not less than 1.25 of the area of the limited peripheral annular section in the plane of the corresponding disc-shaped stator end, and the surface area of the perspective zone of the disc-shaped rotor , which interacts with the specified stator and includes the sum of the areas of the surfaces of the magnetic components and the areas of the disc-shaped rotor of the perspective zone of the disc-shaped rotor, is at least 1.25 of the area of the limited peripheral ring section in the plane of this disc-shaped rotor. 2. The device according to claim 1, which is characterized by the fact that it includes a first disk-shaped rotor with magnetic components and a second disk-shaped rotor with magnetic components located on the shaft, between which a stator with magnetic components is installed, where at least a part of the magnetic components of the stator is located on a limited peripheral annular area one disk-shaped end of the stator and on the limited peripheral annular area of the second disk-shaped end of the stator, representing, respectively, the perspective zone of the first disk-shaped end of the stator, and the perspective zone of the second disk-shaped end of the stator, while the distance from the center of the shaft axis to the near border of the perspective zone of the first disk-shaped end of the stator and the distance from the center of the shaft axis to the near boundary of the perspective zone of the second disk-shaped end of the stator is 0.65...0.75 radius in the plane of the corresponding disk-shaped end of the stator, at least part of the magnetic components of the first disk-shaped rotor is located on a limited peripheral annular area on one side of it of the disk-shaped rotor facing the first disk-shaped end of the stator, which is the perspective zone of the first disk-shaped rotor, and at least part of the magnetic components of the second disk-shaped rotor are located in a limited peripheral annular area on one side of this disk-shaped rotor, turned to the second disk-shaped end of the stator, which is the zone of perspectives of the second disc-shaped rotor, while the distance from the center of the shaft axis to the near boundary of the perspective zone of the first disk-shaped rotor and the distance from the center of the shaft axis to the near boundary of the perspective zone of the second disk-shaped rotor is 0.65-0.75 radius in the plane of the corresponding rotor, compatible "capacitive forms have the surfaces of the magnetic components of the perspective zone of the first disk-shaped end of the stator and the surfaces of the magnetic components of the perspective zone of the first disk-shaped rotor interacting with them, as well as the surfaces of the magnetic components of the perspective zone of the second disk-shaped end of the stator and the surfaces of the magnetic components of the perspective zone of the second disk-shaped rotor interacting with them, at the same time, the surface area of the perspective zone of the first disk-shaped stator end, which includes the sum of the surface areas of magnetic components and stator sections in the perspective zone of the first disk-shaped stator end, and the surface area of the perspective zone of the second disk-shaped stator end, which includes the sum of the surface areas of magnetic components and stator sections the perspective zones of the second disk-shaped end of the stator are at least 1.25 times the area of the limited peripheral annular section in the plane of the corresponding disk-shaped end of the stator, and the surface area of the perspective zone of the first disk-shaped rotor, which includes the sum of the surface areas of the magnetic components and the areas of the first disk-shaped rotor of the perspective zone of the first disk-shaped rotor rotor, and the surface area of the perspective zone of the second disc-shaped rotor, which includes the sum of the areas of the surfaces of the magnetic components and the areas of the second disc-shaped rotor of the perspective zone of the second disc-shaped rotor, are at least 1.25 times the area of the limited peripheral annular section in the plane of the corresponding disc-shaped rotor. 3. 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