WO2017014713A1 - Magnetoelectric generator - Google Patents

Abstract

The invention relates to the field of electrical engineering, and specifically to low-speed electric generators, and may be used predominantly in wind-energy and hydropower installations. A magnetoelectric generator contains a plurality of coils (1) with offshoots (2) of windings (3), located on a stator (4) housing along the arc of the circumference thereof in such a way that the centers of the inner openings of each coil (1) winding (3) are disposed on said circumference, coaxially to the centers of the inner openings of the stator windings (3); all annular portions of the coil (1) windings (3)' are encircled by a torus-like modular magnetic conductor made of a magnetically soft material, which has a slot on the side of a carrier disk (5) of modular permanent magnets (6); the magnets (6) are affixed to the carrier disk (5) via washer brackets (21) made of a magnetically soft material, are modular, and contain permanent magnets (22, 23) and magnetic conductors (24) installed at the ends of the permanent magnets (22, 23). The magnetoelectric generator is simple in design, has a decreased moment of resistance when rotating, is efficient at low rotational speeds, and has an increased specific power output.

Description

 Magnetoelectric generator

The invention relates to the field of electrical engineering, namely to low-speed electric generators, which can be used mainly in wind energy and hydropower plants.

Known magnetoelectric axial generator described in the patent of Ukraine for utility model JV ° 71835, published July 25, 12 in bulletin JV »14, IPC indices: Н02К21 / 12, Н02К 21/24, consisting of a fixed stator with a magnetic circuit and windings and a rotating rotor with permanent magnets mounted on it axially relative to the axis of rotation, and axially oriented permanent magnets mounted on the peripheral

the disk-like part of the rotor made of dielectric non-magnetic material, and the stator magnetic circuit is made of a toroidal shape from tape electrical steel, where the planes of the tapes in the axial air gap are installed perpendicular to the poles of the magnets on the end peripheral part of the rotor and parallel to the vector of the peripheral speed of their movement. The disadvantages are that the generator has excess torque

resistance to rotation due to the interaction of permanent rotor magnets with stator magnetic circuits, which makes it necessary to overcome not only useful electrodynamic in the production of electricity

resistance to rotation, and also excessive resistance, which does not bring any benefit, but makes it impossible to use such generators, for example, in wind turbines, since the increased breaking moment makes them inoperative in light winds.

A known electric generator is described in the patent of the Russian Federation J4 ° 2153756, IPC indices ⁷ Н02К21 / 14, Н02К9 / 08, published July 27, 2000, containing many hollow, arched outer bodies that are located close to each other in the axial direction with the formation torus and each of which has a generally circular cross section centered on a substantially circular axis and contains concentric external and internal cylindrical elements curved in an arc and the nearest and remote end plates with holes, thus forming ohm, a closed chamber between said cylindrical elements and a central channel through said case, a plurality of coils arranged in an arc spaced apart from each other in each of said chambers, each coil being wound around said inner cylindrical element and, therefore, around said annular axis of said case and has conclusions

passing through said outer cylindrical element of said outer case, a cylindrical dividing plate of magnetic material placed between each two adjacent coils in the chambers and having a central hole concentric with said annular axis, a hollow annular inner case passing continuously through said central channels in said housings, thus forming a ring along said annular axis, a plurality of magnets mounted inside said inner body ca at a distance from each other, and drive means for moving the inner housing and, consequently, the magnets through the central channels of the outer shells, thereby creating an electric field in the coils for generating current.

 In the generator, said inner casing is made of non-magnetic material.

 The magnets are located in the inner case at equal distances from each other.

 Adjacent magnets in the inner case are separated by spacers,

inserted between them. The drive means are connected to the inner casing in the gap between the outer casing.

 The speed of movement of the inner housing by the drive means through said channel is adjustable.

 The terminals of each coil are connected to an external power tap.

The thickness of each coil depends on the distance between adjacent magnets.

Coils are installed with the possibility of cooling with a refrigerant (liquid nitrogen) supplied to the said chamber.

 The magnets are arranged so that their poles of the same name face each other. A part of adjacent magnets is located so that their opposite poles are facing each other, and the remaining adjacent magnets are located so that their opposite poles are facing each other.

The disadvantages of the known generator include the complexity of the design and, as a consequence, low reliability and efficiency due to the placement of the inner annular housing with magnets on rotating supports of small diameter with drives that do not provide a good enough

mechanical bonding, have increased friction resistance, as well as

reduce the useful length of the torus with external arcuate cases with coils, because the ring structure deforms with increasing size, and it is impossible to increase the strength, because the working gap between the magnets and coils increases, which leads to large energy losses, low efficiency. The operation of the generator is based on creating current whenever the magnet of the inner ring body passes through the coil of the coil. When the north pole of the magnet enters the winding, the current flows in one direction, and when the south pole of the same magnet enters the same winding, the current flows in the opposite direction. The generator uses this principle to create a continuous current flowing as a result of the continuous passage of magnets and their magnetic field through the coils. The circle formed by the magnets, which continuously passes through the centers of the coils, is infinite the supply of magnets continuously passing through a series of coils and thereby causing the flow of continuous current in them. To achieve maximum effect, the orientation of the magnets in the continuous annular housing is important. This is due to the fact that the position, density and speed of movement and, accordingly, changes in the annular magnetic flux influence the magnitude of the current. If neighboring magnets are far away from each other, so that their magnetic fields do not affect each other, then the current will be small or medium. In this case, there is no distortion of the magnetic flux lines and the current will be limited, since the gap between adjacent magnets is large, so that fewer magnets pass through the coils per unit time. This is true both in the case of the same orientation of the magnets, and in the case when their orientation changes. In other words, if the magnets have the same orientation (i.e., NS / NS / NS or SN / SN / SN), then only the north poles or only the south poles of the magnets first enter each coil, but if the orientation of the magnets changes (alternates, t i.e. NS / SN / NS / SN ...), then the north and south poles of the magnets will be the first to enter the coils alternately.

The closest in technical essence is the magnetoelectric generator described in the patent of Ukraine N ° 107615, published on 01/26/2015 in bull. JN ° 24, IPC indices: Н02К 21/14, Н02К 21/24, Н02К 9/08, according to which the magnetoelectric generator contains coils with taps of windings located on the stator housing along an arc of a circle so that the centers

the internal holes of each winding are located on this circle, coaxial to the centers of the internal holes

of each winding are located on this circle, coaxial with the centers of the internal openings of the stator coils along an arc of a circle, permanent magnets are placed on the carrier with gaps between them, inscribed inside the toroidal cavity formed by the stator coils and directed by poles along the indicated circle with the possibility of movement, as well as the drive element connected to the magnet carrier, moreover, the permanent magnet carrier is made in the form of a non-magnetic disk mounted on the drive shaft, the coils are made of at least two windings, each of the windings is curved in the form of two open rings - the first and second, which are the working part of the windings, and the distance between the open rings of each winding is equal to the length of the permanent magnet, open rings are interconnected by longitudinal sections of these windings, in each coil open rings of the first number of subsequent windings are placed coaxially along an arc of a circle between

open by two rings of the previous windings, and the ring connector is deployed in the direction of the center of rotation of the carrier disk on the drive shaft and exceeds the thickness of the permanent magnet carrier.

 The stator housing is made of non-magnetic material.

 The open rings of each winding in the coils are connected by a U-shaped curved longitudinal sections, which are fan-spaced with the possibility of mutual intersection.

 Coils are made by modules in the form of hollow shells made of thin

dielectric material in which the windings are placed and filled

non-conductive compound.

 Permanent magnets are arranged in concert with each other at equal distances from each other, eliminating the formation of a sequential closed magnetic circuit, or so that the magnets on the carrier are fixed in the opposite direction, at a distance that ensures the interaction of magnetic fields between adjacent magnets.

 The carrier is a disk of non-magnetic material mounted on a shaft mounted in angular contact bearings mounted in the stator housing.

 The connector of the winding rings and the connector in the generatrix of the holes in the coils exceeds the thickness of the permanent magnet carrier by a size corresponding to the permissible deviations of the dimensions and deformations of the structure.

The common essential features of the claimed magnetoelectric generator is that the magnetoelectric generator contains many coils with taps of windings located on the stator housing along an arc of a circle so that the centers of the internal holes of each winding are located on this circle, and coaxially with the centers of the internal holes of the stator windings along an arc of a circle located on articulated media, with between them, permanent magnets with the ability to move inside the toroidal cavity formed by the windings of the stator coils and directed by the poles along tangents to the specified circle, the permanent magnet carrier is made in the form of a non-magnetic disk mounted on the shaft with the possibility of connection with the rotation drive element, the coils are made not less than than with two windings, each of the windings is curved in the form of two open rings located at a distance from each other - the first and second, which are the slave whose part windings of an open ring are interconnected longitudinal portions of these coils, rings connector deployed towards the center of the carrier disc and the carrier disc exceeds the thickness of the permanent magnets.

The disadvantages of the known magnetoelectric generator, the prototype, is not enough full use of the magnetic flux from permanent magnets, which does not allow to increase its useful specific power.

The technical result is the creation of magnetoelectric

a generator of simple construction, with a reduced moment of resistance during rotation, effective at low speeds of rotation and having an increased specific power.

Essential features is that a magnetoelectric generator containing many coils with taps of windings located on the stator housing along a circular arc so that the centers of the internal holes of each winding are located on this circle, and coaxially with the centers of the internal holes of the stator windings on a circular arc are mounted on a pivotally mounted medium with gaps between themselves permanent magnets with the ability to move inside the toroidal cavity formed by the windings of the stator coils and directed poles along the tangents to the specified circle, the permanent magnet carrier is made in the form of a non-magnetic disk mounted on the shaft with the possibility of connection with the rotation drive element, the coils are made with at least two windings, each of the windings is curved in the form two open rings located at a distance from each other - the first and second, which are the working part of the windings, open rings are interconnected by longitudinal sections of these windings, the ring connector is deployed in the direction of the center of the carrier disk and exceeds the thickness of the permanent magnet carrier disk, moreover, all ring parts the windings of the coils are externally covered by a prefabricated, like a torus, magnetic core of soft magnetic material, which has a gap on the side of the disk of the carrier of permanent magnets, the magnets are fixed to the disk e carrier on washers-brackets of soft magnetic material, prefabricated, and contain permanent magnets and magnetic conductors installed at the ends of the permanent magnets.

 Each prefabricated magnet contains at least two permanent magnets fixed with ends on both sides on a washer-bracket made of soft magnetic material and fixed with opposite poles facing each other, and magnetic conductors made of soft magnetic material are installed on the outside at the ends of which spherical recesses are made on the outer end, the contour of which begins from the outer diameter of the end face of the magnetic conductor, and between each other on the carrier disk, prefabricated magnets are located opposite the poles of the same name.

The coils are made by modules, in the form of external cases of non-magnetic material, which have flanges, with the possibility of mounting on a stator, and in which sections of C-shaped sections of magnetic circuits are installed, which in a radial section cover from half to three quarters of the circumference of the working part of the windings, and assembled to form a torus-like magnetic core, by providing magnetic conductivity in the direction of the circle through

connecting rods, and the coil windings are filled with a non-conductive compound.

 Each of the sections of the magnetic circuit is assembled of at least two parts of amorphous iron, separated in the plane of a circle of a toroidal surface, and fixed by connecting rods installed in the holes of the side walls of the housing of the coil modules.

In each coil, the open rings of the first number of subsequent windings are placed coaxially in an arc of a circle between open rings

previous windings. In each coil, the connecting longitudinal sections of the windings of one end sections of the open rings are located relative to opposite longitudinal sections at an acute angle, and also relative to the surface of the carrier disk, and in the radial direction in the plane of the carrier disk relative to the tangent to the circumference formed by the windings, with the possibility of compact placement multiple windings in a coil in

direction of the circle.

 The sections of the magnetic circuit are fixed, among themselves, at a distance with the possibility of transmitting magnetic flux along the circumference, and there is at least one zone of rupture of the magnetic flux.

 Each section, like a torus of a magnetic circuit, is assembled from plates

transformer iron, through which the rods pass, with which they are pulled together in packets and which contact the rods of adjacent sections, with the possibility of transmitting magnetic flux along the circumference of the stator.

 The disk carrier of permanent magnets is mounted on a shaft mounted in angular contact bearings mounted in the stator housing.

On the shaft of the disk of the carrier of permanent magnets mounted compensating coupling, which is located in the cavity of the glass mounted on the stator housing, with the possibility of connecting to the shaft of the drive element of rotation.

Distinctive essential features valid in all cases is that all the ring parts of the coil windings are externally covered by a prefabricated, like a torus, magnetic core made of magnetically soft material, which has a gap on the side of the permanent magnet carrier disk, magnets are mounted on the carrier disk on washers-brackets of magnetically soft material , prefabricated, and contain permanent magnets and magnetic conductors installed at the ends of the permanent magnets.

Distinctive essential features valid in some cases is that each prefabricated magnet contains at least two permanent magnets fixed with ends on both sides of the washer bracket from soft magnetic material, fixed by opposite poles towards each other, and magnetic conductors from

soft magnetic material in which spherical recesses are made on the outer end, the contour of which begins with the outer diameter of the end

magnetic conductor, and between each other on the carrier disk, prefabricated magnets are located opposite the poles of the same name.

 The coils are made by modules, in the form of external cases of non-magnetic material, which have flanges, with the possibility of mounting on a stator, and in which sections of C-shaped sections of magnetic conductors are installed, which in a radial section cover from half to three quarters of the circumference of the working part of the windings, and assembled to form a torus-like magnetic circuit, by providing magnetic conductivity in the direction of the circle through

connecting rods, and the coil windings are filled with a non-conductive compound.

Each of the sections of the magnetic circuit is assembled of at least two parts of amorphous iron, separated in the plane of a circle of a toroidal surface, and fixed by connecting rods installed in the holes of the side walls of the housing of the coil modules.

 In each coil, the open rings of the first number of subsequent windings are placed coaxially in an arc of a circle between open rings

previous windings.

 In each coil, the connecting longitudinal sections of the windings of one end sections of the open rings are located relative to opposite longitudinal sections at an acute angle, and also relative to the surface of the carrier disk, and in the radial direction in the plane of the carrier disk relative to the tangent to the circumference formed by the windings, with the possibility of compact placement multiple windings in a coil in

direction of the circle.

 The sections of the magnetic circuit are fixed, interconnected, at a distance, providing the ability to transmit magnetic flux along the circumference, and there is at least one zone of rupture of the magnetic flux.

Each section, like a torus of a magnetic circuit, is assembled from plates transformer iron, through which the rods pass, with which they are pulled together in packets and which contact the rods of adjacent sections, with the possibility of transmitting magnetic flux along the circumference of the stator.

 The disk carrier of permanent magnets is mounted on a shaft mounted in angular contact bearings mounted in the stator housing.

 On the shaft of the disk of the carrier of permanent magnets mounted compensating coupling, which is located in the cavity of the glass mounted on the stator housing, with the possibility of connecting to the shaft of the drive element of rotation.

Due to the fact that in a magnetoelectric generator containing many coils with taps of windings located on the stator housing along a circular arc so that the centers of the internal holes of each winding are located on this circle, coaxial with the centers of the internal holes of the stator windings, also located on a pivotally mounted arc medium with gaps between themselves permanent magnets with the ability to move inside the toroidal cavity formed by the windings of the stator coils and directed by poles along tangent to the indicated circle, the permanent magnet carrier is made in the form of a non-magnetic disk mounted on the shaft with the possibility of connection with a rotation drive element, the coils are made with at least two windings, each of the windings is curved in the form of two open rings located at a distance from each other - the first and of the second, which is the working part of the windings, open rings are interconnected by longitudinal sections of these windings, the ring connector is deployed in the direction of the center of the carrier disk and exceeds the thickness of Single carrier permanent magnets, wherein all the ring portion further winding coils are covered externally similar prefabricated torus yoke of

soft magnetic material, which has a connector on the side of the disk of the carrier of permanent magnets, the magnets are mounted on a rotor on washers-brackets of soft magnetic material, prefabricated and contain permanent magnets and

magnetic conductors installed at the ends of the permanent magnets, which with a simple design and a reduced moment of resistance during rotation, so since there are no losses from the magnetic interaction of permanent magnets with the metal of the stator windings, it allows you to efficiently receive electrical energy even at low speeds, moreover, the generator has an increased specific output power, since there are no losses of magnetic flux outside the coil windings into the surrounding space.

Figure 1 shows a main sectional view of a magnetoelectric generator; Figure 2 shows a section aa;

 In Fig.3 shows a remote element B;

 Figure 4 shows two connected coil windings;

 5 shows a coil module;

 Figure 6 shows a section bb;

 7 schematically shows the interaction of magnetic fields and windings. According to the claims, the magnetoelectric generator contains many coils 1 with taps 2 of the windings 3 located on the stator housing 4 along an arc of a circle so that the centers of the inner holes of each winding 3 of the coils 1 are located on this circle, and coaxially with the centers of the internal holes of the stator windings 3 along an arc of a circle on the pivotally mounted disk of the carrier 5, permanent assembly magnets 6 are located at intervals between each other, with the possibility of movement inside the toroidal cavity formed by the windings 3 of the stator tubes lugs 1. Permanent magnets 6 prefabricated poles are directed along the tangent to said circle.

 The disk carrier 5, permanent prefabricated magnets 6, is made of non-magnetic material and mounted on the shaft 8, with the possibility of connection with the rotation drive element of its part 7 (the drive is not shown, as it can be a wind turbine rotor, and a hydraulic rotor and internal combustion engine and this is clear to specialists, and is not an object of claims), the coils 1 are made with two windings 3, each of the windings is curved in the form of two open rings located at a distance from each other - the first 9 and second 10, which are the working part of the windings, open rings interconnected

longitudinal sections 11 and 12 of these windings, the ring connector is deployed in the direction of the center of the disc media 5 and exceeds the thickness of the disc media 5.

All the ring parts of the windings 3 of the coils 1 are externally covered by a prefabricated like torus magnetic core of magnetically soft material, which has a gap on the side of the disk of the carrier of permanent magnets. Figure 5 shows that the coils 1 are made by modules in the form of external housings 13 of non-magnetic material, which have flanges 14 with holes 15 for mounting on the stator 4, and in which parts C and 16 are installed (see Fig. 6) of sections C -shaped in cross section of the magnetic cores, which in a radial section cover up to three quarters of the circumference of the working part of the windings 3, and when all the modules of the coils 1 are mounted on the stator housing 4 they form a torus-like magnetic circuit, due to the magnetic conductivity around the ends of the connector rods 18, each of the sections of the magnetic circuit in the module of the coil 1 is assembled from at least two parts 16 and 17 of amorphous iron, separated in the plane of the circle of the toroidal structure, and fixed by connecting rods 18 installed in the holes 19 of the side walls 20 of the cases 13 of the coil modules 1. The windings in coils 1 are filled with a non-conductive compound.

 Permanent prefabricated magnets 6 are mounted on a carrier disk 5 on washers-brackets 21 made of soft magnetic material and contain permanent magnets 22 and 23, also magnetic conductors 24, which are installed externally at the ends of the said permanent magnets.

 Moreover, the permanent magnets 22 and 23 are fixed by opposite poles towards each other, and outside the ends there are magnetoconductors 24 made of magnetically soft material in which spherical recesses are made on the outer end, the contour of which starts from the outer diameter, are fastened together by screws 25, and between them on the disk carrier prefabricated magnets 6

located opposite poles of the same name along the circumference.

In each coil 1, the open rings of the first number 9 of the subsequent windings 3 are placed coaxially in an arc of a circle between the open rings of the previous windings (see Fig. 4.) 9 and the second 10, which are the working part of the windings 3, the open rings are interconnected by longitudinal sections 11 and 12 and further, when using more than two windings in the coils, the open rings of the first number of subsequent windings are placed coaxially in an arc circles between the open rings of the previous windings.

 The connecting longitudinal sections 11 are located relatively

opposite connecting longitudinal sections 12 at an acute angle, that is, both of these sections are at an acute angle relative to

the surface of the carrier disk 5, in addition and in the radial direction in the plane of the carrier disk, the longitudinal sections 11 and 12 are at an acute angle

relative to the tangent to the common circle for the magnets and openings of the windings of each individual coil, with the possibility of compactly placing the windings 3 in each coil 1 in the circumferential direction.

 Also, each of the sections 16 and 17 of a magnetic circuit similar to a torus can be assembled from transformer iron plates through which the rods 18 pass, by which they are pulled together in packets and which contact the rods connecting adjacent similar sections with the ability to transmit magnetic flux along a circle, this is a known technology create

the magnetic circuit from the plates and therefore we can’t demonstrate it, but the generator’s operability is ensured even with this design, reflected in the dependent clause. The disk carrier 5, prefabricated permanent magnets 6, is mounted on the shaft 8,

installed in an angular contact bearing 26, mounted in the stator housing 4 in the bottom cover 27, and also its reinforced part 7 is installed in bearings bearing a higher load 28 installed in the sleeve 29, which bear the load from the weight of, for example, a wind wheel, and to exclude the shock load during rotation on the extension of the shaft 8 of part 7, a coupling sleeve is installed that compensates for both distortions and shock loads, which contains a coupling half 30, a shock absorption liner 31, and a coupling half 32 with an aperture 33 with veneer full-time grooves or other fixing elements known in the art, for the possibility of attaching a rotation drive shaft, this assembly is located in the cavity of the cup 34 mounted on the stator housing 4 and closed by a cover 35.

It is also possible to connect the rotational drive element to the shaft 8 through a freewheel, which makes it possible to maintain the rotation of the generator when switching part of the windings to a voltage source and to provide higher stability. Also, within the dependent claims, a version is possible in which sections of the magnetic circuit are fixed with the ability to transmit magnetic flux along the entire circumference, but versions are possible in which, for example, three zones of rupture of the magnetic flux are made, which provides

constructive possibilities to change the switching and have three phases at the output, but we did not describe the switching connections, since this is not an object of claims.

In operation, the magnetoelectric generator operates as follows.

The shaft 8 of the carrier disk 5 with prefabricated permanent magnets 6 is driven into rotation by an external force through a connector mounted on its part 7 with a cushioning insert 31. As shown in Fig. 7, magnetic lines of force cross the conductors of two open rings of the windings of the first 9 and second 10, which are the working part of the windings, and the distance between the open rings of each winding is equal to the length in the circumferential direction of the prefabricated permanent magnets 6 and induce in them coordinated in direction and equal in magnitude of the electric motors astringent power.

 An electric current directed from the viewer is indicated by the (+) sign and to the viewer - (.). It is obvious that when the distance between the open rings 9 and 10 of the windings is equal to the length of the prefabricated magnet 6, a current balance is provided in the parts of the windings 9 and 10, which are transmitted through the switching devices

to the consumer and ensure the full use of the magnetic field energy of prefabricated permanent magnets 6, therefore, when installing the claimed

a magnetoelectric generator in a design with a wind rotor, a wind force of 0.5 points is enough to generate electricity.

 The author actively uses the described generator design in

wind power generators.

Claims

Formula  1. A magnetoelectric generator comprising a plurality of coils with taps of windings located on the stator body along an arc of a circle so that the centers of the internal holes of each winding are located on this circle, and coaxially with the centers of the internal holes of the stator windings on the arc of a circle are located on a pivotally mounted carrier with gaps between permanent magnets with the ability to move inside the toroidal cavity formed by the windings of the stator coils and directed by the poles along the tangents to the indicated circles, the carrier of permanent magnets is made in the form of a non-magnetic disk mounted on the shaft with the possibility of connection with the rotation drive element, the coils are made with at least two windings, each of the windings is curved in the form of two open rings located at a distance from each other - the first and second, which are the working part of the windings, open rings are interconnected by longitudinal sections of these windings, the ring connector is deployed in the direction of the center of the carrier disk and exceeds the thickness of the carrier disk magnets characterized in that all the ring parts of the coil windings are externally covered by a prefabricated, like a torus, magnetic core of magnetically soft material, which has a gap on the side of the disk of the carrier of permanent magnets, the magnets are mounted on the disk of the carrier on washers-brackets of magnetically soft material, prefabricated, and contain permanent magnets and magnetic conductors installed at the ends of the permanent magnets.  2. The generator according to claim 1, characterized in that each prefabricated magnet contains at least two permanent magnets fixed with ends on both sides on a washer-bracket of magnetically soft material, fixed with opposite poles facing each other, and installed on the ends at the ends magnetic conductors of soft magnetic material in which spherical recesses are made on the outer end, the contour of which begins with the outer diameter of the end of the magnetic conductor, and the assembled magnets are located opposite each other on the carrier disk with opposite poles. 3. The generator according to claim 1, characterized in that the coils are made by modules, in in the form of external housings of non-magnetic material, which have flanges, with the possibility of mounting on a stator, and in which sections of C-shaped magnetic cross sections are installed, which in a radial section cover from half to three quarters of the circumference of the working part of the windings, and assembled to form a similar torus magnetic circuit, due to the provision of magnetic conductivity in the direction of the circle through the connecting rods, and the coil windings are filled with a non-conductive compound.  4. The generator according to claim 3, characterized in that each of the sections of the magnetic circuit is assembled of at least two parts of amorphous iron, separated in the plane of a circle of a toroidal surface, and fixed by connecting rods installed in the holes of the side walls of the housing of the coil modules.  5. The generator according to claim 3, characterized in that in each coil the open rings of the first number of the subsequent windings are placed coaxially in an arc of a circle between the open rings of the previous windings.  6. The generator according to claim 3, characterized in that in each coil the connecting longitudinal sections of the windings of one end sections of the open rings are located relative to opposite longitudinal sections at an acute angle, and also relative to the surface of the carrier disk and in the radial direction in the plane of the carrier disk relative to the tangent to the circle formed by the windings, with the possibility of compactly placing several windings in the coil in the direction of the circle.  7. A generator according to claim 3, characterized in that the sections of the magnetic circuit are fixed, together, at a distance to ensure the possibility of transmitting magnetic flux along the circumference, and there is at least one zone of rupture of the magnetic flux.  8. The generator according to claim 3, characterized in that each of the sections, like a torus of a magnetic circuit, is assembled from plates of transformer iron, through which the rods pass, by which they are pulled into packets and which are in contact with the rods of adjacent sections, with the possibility of transmitting magnetic flux along stator circumference. 9. The generator according to claim 1, characterized in that the disk is a carrier of permanent magnets mounted on a shaft mounted in angular contact bearings mounted in the stator housing.  10. The generator according to claim 9, characterized in that a compensating coupling is installed on the shaft of the permanent magnet carrier disk, which is located in the cavity of the glass mounted on the stator housing, with the possibility of connecting a rotation drive element to the shaft.