WO2017018963A1

WO2017018963A1 - Wind power unit

Info

Publication number: WO2017018963A1
Application number: PCT/UA2016/000084
Authority: WO
Inventors: Александр Вилиорович АМИТОВ
Original assignee: Александр Вилиорович АМИТОВ
Priority date: 2015-07-24
Filing date: 2016-07-06
Publication date: 2017-02-02
Also published as: UA104607U

Abstract

The wind power unit relates to the field of wind power engineering and can be used in the construction of wind power stations. The technical problem addressed by the invention is that of simplifying the construction, reducing the metal content and increasing the operating reliability and efficiency. The unit comprises at least one wind wheel (1) which is fastened to a shaft (2) such that the rotor (3) of a generator (4) can rotate, and an immovably fastened housing of a stator (5). In the stator (6), a multiplicity of coils (6) with outputs of windings (7) is arranged on an arc of a circle, and also magnets (8) are arranged in a circle on the rotor (3) with clearances between said magnets. The housing of the stator (5) of the generator (4) is fastened to a support mast (10) by a bracket (9). The shaft (2) of the wind wheel (1) and the shaft (11) of the rotor (3) of the generator (4) are interconnected. The rotor (3) of the generator (4) is in the form of a non-magnetic carrier disc (14) with permanent magnets (8), which are mounted on the external contour thereof and have poles arranged in a direction tangential to the contour, and is fastened to the shaft (11), which is mounted in rotation supports. Each coil (6) of the stator (5) is formed from at least two windings (7), each of the windings (7) is bent in the form of two open rings, a first ring (17) and a second ring (18), which are the working part of the windings and surround the area in which the magnets (8) of the rotor (3) are arranged. The ends of the open rings (17, 18) are interconnected by longitudinal sections (19, 20) of said windings. In each coil (6), the open rings of a first number (17) of subsequent windings are placed coaxially on an arc of a circle between the open rings of previous windings, and the ring junction faces towards the centre of the carrier disc (14) and exceeds the thickness of the carrier disc (14) of the permanent magnets (8).

Description

Wind power unit

It relates to wind energy and can be used in the construction of wind farms.

Known gearless vertical axis wind turbine described in the patent of Ukraine 99662, published September 10, 2012 in bull. JV ° 17, IPC indices: F03D 3/06, F03D 11/00, F03D 9/00 which contains a wind rotor mounted on a common transmission shaft with an electric generator, and a support unit,

equipped with magnetically interacting elements, moreover, the wind rotor is made in two tiers and is framed by a bandage cage mounted on a support, each tier contains aerodynamic profile wings fixed at both ends to different support rings that are rigidly connected to the common shaft using a spoke system, while the wings of the lower tier are turned around a circle relative to the wings of the upper tier by 60 ° in the three-bladed embodiment, the middle ring is common to both tiers and has

increased diameter due to the functional protrusion, the bandage cage consists of two support disks interconnected by racks, the lower and upper disks are solid and equipped with support-bearing units for mounting the shaft, the support unit is transferred from the generator rotor to the windage rotor cage and contains a pendant ring,

mounted on racks, the suspension ring is made in the form of a profiled circular beam that has a channel profile facing the axis of the rotor with a groove, a ferromagnetic ring equal to the width of the shelf is installed on the upper shelf of the channel, a magnetic track is installed on the lower shelf, made of bars of permanent magnets located at intervals and with varying polarity, between the magnetic and ferromagnetic layers

SUBSTITUTE SHEET (RULE 26) minimum air gap, which without touching the protrusion of the middle ring of the rotor of the generator.

The disadvantages are the high complexity of the design made to ensure deformation reduction, which also led to electromagnetic braking of the wind rotor, and the rotor has a large diameter, and sets in motion a traditional generator with a much smaller diameter of the rotor and stator, which should work efficiently at much higher speeds rotations than wind rotors of this design provide.

The closest in technical essence is the wind turbine described in the patent of Ukraine for utility model N ° 64345, published 10.11.201 1 in bull. M> 21, IPC indices: F03D 1/00, Н02К 1/27.

The windmill contains two inverted reverse motion wind turbines coaxially located on the shafts, a generator, which includes a stator with a three-phase distributed winding and a movable part, moreover, the stator is mounted cantilever using brackets to the generator housing, the stator winding is made of sections of a P-like spatial forms with

a two-sided active surface, and the movable part is made in the form of two explicitly polar rotors with magnetoelectric excitation, equidistantly placed relative to the active surface of the stator and mechanically connected to the half-shafts of the corresponding wind turbines, and within each double-pole separation U-like sections are laid with the crossing of the two extreme phases inoperative zone. The mounting points of the brackets are located on the end surface of the stator, free from winding, between the frontal parts of the distributed winding.

The stator is made with a toroidal flat active surface, and the rotors with magnetoelectric excitation are made disk.

Common essential features is that the wind power unit contains at least one wind wheel mounted on a shaft with

the possibility of rotation of the rotor of the generator and the fixed body

SUBSTITUTE SHEET (RULE 26) stator, in which many coils with the conclusions of the windings located on the stator housing along an arc of a circle so that the windings are on this

circles, also circumferentially located on the rotor with gaps between themselves magnets.

The disadvantages of this wind generator include the complexity of the design and, as a consequence, low reliability and efficiency due to the small area of use of the magnetic flux between magnets and coils, which are not solved by installing two wind turbines, the synchronization of which

construction does not guarantee.

The technical result is to simplify the design, reduce metal consumption, increase reliability and work efficiency. The essential features are that the wind electric unit contains at least one wind wheel mounted on the shaft with the possibility of rotation of the generator rotor and fixedly fixed stator housing, in which many coils with the leads of the windings located on the stator housing along an arc of a circle so that the windings are located on this the circumference, also around the circumference are located on the rotor with gaps between themselves magnets, moreover, the fixed housing of the stator of the generator is fixed by a bracket on the support mast, the shaft of the wind wheel and the rotor shaft of the generator are interconnected, the generator rotor is made in the form of a non-magnetic carrier disk with permanent magnets installed along its outer contour with poles located in the direction tangent to the circuit and mounted on a shaft installed in rotation bearings, and each stator coil is made of at least two windings, each of the windings is curved in the form of two, first and second, open rings, which are the working part of the windings covering the area of location of the rotor magnets, and the ends of the open rings are connected interconnected by the longitudinal sections of these windings, in each coil the open rings of the first number of subsequent windings are placed coaxially in an arc of a circle between the open rings of the previous windings and the connector of the rings

SUBSTITUTE SHEET (RULE 26) deployed in the direction of the center of the disc media and exceeds the thickness of the disc media of permanent magnets.

Permanent magnets on the carrier disk are arranged in concert with each other at equal distances from each other, eliminating the formation of

consecutive closed magnetic circuit, or permanent magnets on the carrier disk are fixed with the same poles in the opposite direction, at a distance

providing the interaction of magnetic fields between adjacent magnets.

The distance between the first and second open rings of the windings in each coil is equal to the length of the permanent magnet of the rotor.

In the rotor of the generator, the permanent magnet carrier is mounted on a shaft mounted in angular contact bearings mounted in the stator housing, and is connected to the generator shaft by means of a connecting

of a compensating coupling a wind wheel shaft, also mounted in angular contact bearings.

In the generator rotor, the permanent magnet carrier is mounted on a shaft mounted in angular contact bearings mounted in the stator housing, and a wind wheel shaft, also mounted in angular contact bearings, is connected to the generator shaft by means of an overrunning clutch.

On a supporting structure, which is a mast, mounted on a foundation structure with a lateral stator mount bracket

generator, there is a radially located support at the top, on which a bearing support of the upper part of the wind wheel shaft is installed.

Blue propeller surfaces consist of interconnected plates of the segments themselves, which are T-shape gently bent in the sectional conditional planes perpendicular to the shaft of the _L segments installed in pairs opposite each other relative to the shaft axis and each successive pair of segments turned relative to the previous one around the shaft through the same selected angle provided also twist each segment relatively

perpendicular to the shaft, forming spiral convex-concave surfaces along the shaft.

The wind wheel shaft is vertical or the wind wheel shaft is horizontal.

SUBSTITUTE SHEET (RULE 26) Coils are made by modules in the form of hollow housings made of thin dielectric material, in which windings are placed and filled

non-conductive compound.

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 working deformations of the structure.

The support mast is pivotally mounted on the foundation with the possibility of

failures.

A hydraulic cylinder with a positive shoulder relative to the hinge of fastening the mast to the foundation with the possibility of connecting the piston and rod cavities to the pump station with its fittings is fixed on the support mast and foundation on the eyes.

Distinctive essential features valid in all cases is that the fixed housing of the generator stator is fixed by a bracket to the support mast, the wind wheel shaft and the generator rotor shaft are interconnected, the generator rotor is made in the form of a non-magnetic carrier disk with permanent magnets installed along its external contour with poles located in the direction tangent to the circuit and mounted on a shaft installed in the rotation bearings, and each stator coil is made of at least two windings, each from the windings is curved in the form of two, first and second, open rings, which are the working part of the windings, covering the area of location of the rotor magnets, and the ends of the open rings are interconnected by longitudinal sections of these windings, in each coil the open rings of the first number of subsequent windings are placed coaxially in an arc the circles between the open rings of the previous windings and the connector of the rings are deployed in the direction of the center of the disk of the carrier and exceeds the thickness of the disk of the carrier of permanent magnets. Distinctive essential features valid in some cases is that the permanent magnets on the disk of the carrier are located consistently with each other at equal distances from each other, excluding

SUBSTITUTE SHEET (RULE 26) the formation of a sequential closed magnetic circuit, or permanent magnets on the carrier disk are fixed with the same poles in the opposite direction, at a distance that ensures the interaction of magnetic fields between adjacent magnets.

On the supporting structure, which is a mast, mounted on a foundation structure with a lateral bracket for fastening the stator of the generator, there is a radially located bearing at the top on which a bearing bearing of the upper part of the wind wheel shaft is mounted.

The working surfaces of the wind wheel consist of plates of segments interconnected, which are L-shaped, smoothly bent, in the section with conditional planes perpendicular to the shaft, the segments are pairwise mounted opposite each other relative to the shaft axis and each subsequent pair of segments is rotated relative to the previous one around the shaft axis at the same selected angle twist each segment relatively

The wind wheel shaft is vertical or the wind wheel shaft is horizontal.

Coils are made by modules in the form of hollow housings made of thin dielectric material, in which windings are placed and filled

non-conductive compound.

SUBSTITUTE SHEET (RULE 26) 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 working deformations of the structure.

The support mast is pivotally mounted on the foundation with the possibility of

failures.

Due to the fact that the wind power unit contains at least one wind wheel mounted on the shaft with the possibility of rotation of the generator rotor and a stator in which there are many coils with taps of windings located on the stator body along an arc of a circle so that the windings are on this circle, also in a circle Permanent magnets are located on the rotor with gaps between each other, moreover, the fixed housing of the generator stator is fixed by a bracket to the support mast, the wind wheel shaft and the generator rotor shaft are interconnected, the generator rotor the torus is made in the form of a non-magnetic carrier disk with permanent magnets mounted on its outer contour with poles located tangentially to the contour and mounted on a shaft mounted in rotation bearings, and each stator coil is made of at least two windings, each of the windings is bent into in the form of two, first and second, open rings, which are the working part of the windings, covering the area of location of the rotor magnets, and the ends of the open rings are interconnected by longitudinal sections of these windings k, in each coil, the open rings of the first number of the following windings are placed coaxially in an arc of a circle between the open rings of the previous windings and 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 - the design is simplified and the material consumption of the wind power unit is reduced, since it is not needed high mast, wind wheel sets the generator in motion by wind starting with a force of 0.5 points, since there is no increase in torque due to inefficient pull eniya

SUBSTITUTE SHEET (RULE 26) between the permanent magnets and stator magnetic circuits, as in the well-known constructions common in the art, an increase in reliability and operational efficiency is achieved due to the winding covering an angle of at least 300 ⁰ around the permanent magnets, and the fact that a large number of magnets and coils with windings makes it possible to produce larger generators with respect to typical traditional designs of such power and provide the necessary linear speed and generate electricity at low speeds in a large number of windings to atushki, which allows, due to well-known experts switching switching to various connection schemes, to produce the necessary electricity to the consumer with the provision of the specified power and voltage.

Figure 1 shows the main view of the wind power unit;

Figure 2 shows a top view of a wind power unit;

In Fig.3 shows a remote element A;

Figure 4 shows a section of an electric generator with bearing bearings and a coupling;

Figure 5 shows a section BB in permanent magnets of the rotor and stator coils;

Figure 6 shows the shape of the windings of the coils and their relative position;

7 shows a cross section of a winding;

On Fig shows one coil;

Figure 9 shows the interaction of the magnetic field and the windings in the opposite position of the permanent magnets of the rotor.

According to the application, the wind power unit contains a wind wheel 1 mounted on the shaft 2 with the possibility of rotation of the rotor 3 of the generator 4.

A fixed stator housing 5, in which a plurality of coils 6 with taps 7, located on the stator housing 5 along an arc of a circle so that they are on this circle, are also surrounded by permanent magnets 8 on the rotor 3 at intervals. The stationary stator housing 5 is fixed by a bracket 9 on the support mast 10.

The shaft 2 of the wind wheel and the shaft 1 1 of the rotor 3 of the generator 4 are interconnected by means of a coupling 12, which compensates for distortions and sharp

SUBSTITUTE SHEET (RULE 26) shocks when the load changes, the shaft of the wind wheel 2 is also installed in angular contact bearings 13, so as not to transmit vibration and load to the rotor 3.

The rotor 3 of the generator 4 contains a carrier disk 14 made of non-magnetic material with constant constants installed along its outer contour

magnets 8 with poles located tangentially to the contour and mounted on a shaft 11 mounted in rotation bearings in angular contact bearings 15 and 16, which provide a clear location of the rotor 3 relative to the stator coils 6 not only in the radial direction, but also in height - in the axial direction.

Each coil 6 of the stator 5 is made of at least two windings, each of the windings (see Fig. 6) is curved in the form of two, first 17 and second 18, open rings, which are the working part of the windings covering the area

the location of the rotor magnets, and the ends of the open rings 17 and 18 are interconnected by longitudinal sections 19 and 20 of these windings, in each coil 6 open rings 17 of the first number of subsequent windings are placed coaxially in an arc of a circle between the open rings of the previous windings and the ring connectors are deployed in the direction of the center center non-magnetic disk media 14 and exceed the thickness of the disk of the carrier of permanent magnets.

Permanent magnets 8 on a non-magnetic disk media 14 may be

are arranged in a consistent manner at equal distances from each other, with the possibility of eliminating the formation of a closed magnetic circuit. And in our particular embodiment in FIG. 9 it is shown that the permanent magnets on the carrier disk are counter-mounted with the same poles, at a distance ensuring the interaction of magnetic fields between adjacent magnets and provide a sharp increase in magnetic flux, since the distance between the open rings of the windings in each coil is equal to the length of the permanent magnet of the rotor and the magnets and windings evenly spaced around the circumference, then the phases of the generated voltage in the equally located windings of all the coils coincide in phase.

On a supporting structure, which is a mast 10, mounted on a foundation structure 21 with a side bracket 9 for mounting the stator 5

SUBSTITUTE SHEET (RULE 26) generator 4, at the top there is a radial bearing 22, on which a bearing bearing 23 with a bearing 13 for the upper part of the shaft 2 is mounted

wind wheels 1. Mast 10, for ease of installation and dismantling, can be assembled from sections 24, 25, 26 detachably interconnected. Section 24 is fixed

5 by hinge 27 on the foundation structure 21. For relatively large

of wind power units on a foundation structure 21 on an eye 28 and on a mast 10 on an eye 29 a hydraulic cylinder 30 s is fixed

a positive shoulder relative to the hinge 27, fastening the mast 10 to the foundation structure 21, with the possibility of connecting with its fittings:

10 46 piston cavities and 47 rod cavities to the pumping station and blocking or lifting the mast 10, if necessary, by one person. The pump station is not shown, as it is suitable as a station with a manual drive, and with an electric one and they are supplied to the world markets by many companies, their designs are known to specialists and are not the subject of claims.

15 The working surfaces of the wind wheel 1 consist of segments 31 which are pairwise mounted opposite each other with respect to the axis of the shaft 2 on the shaft 2 and each subsequent pair of segments 31 is rotated relative to the previous one around the axis of the shaft 2 in a horizontal plane, l-shaped smoothly bent in section by conventional planes perpendicular to the shaft plane to the same selected angle. 0 The twist of each segment 31 relative to the perpendicular to the shaft 2 allows the formation of spiral convex-concave surfaces with smooth transitions that are aerodynamically suitable for the effective use of wind power.

The shaft 2 of the wind wheel 1, in our example, is located vertically, but in

5 necessary cases, the shaft 2 of the wind wheel 1 can be located horizontally and is also suitable to effectively perceive the wind flow.

With the aim of sustainability in perceiving wind load in small

wind power units with a fairly expanded foundation

construction, which is on the ground, and for larger, as shown in figure 1, 0, the foundation structure 21 is attached to the studs 32 with nuts 33 and

underlays 34 embedded in a concrete foundation 35.

Coils 6 are made by modules (see Fig. 8) in the form of empty thin shells

SUBSTITUTE SHEET (RULE 26) dielectric material in which the windings are placed and filled

non-conductive compound.

The connector of the rings of the windings and the connector in the forming holes in the coils exceeds the thickness of the disk of the carrier 14 of the permanent magnets 8 by the corresponding size of the permissible deviations of the dimensions and working deformations of the structure.

To protect the bearing assemblies and couplings, the stator housing 5 to the bracket 9 is connected through a cup 36 with a housing cover 37 into which the bearing assembly with the bearing 13 is installed, the housing 38 and the connecting

a compensating coupling 39 with dowels 40 with which it is connected to a shaft 41 on which a coupling 12 is mounted, which comprises a coupling half 42, which, through rubber shock absorbers 43, and a coupling half 44 transmits torque to the shaft 1 1 of the generator 4.

Below the generator is closed by a casing 45. In operation, the wind power unit operates as follows.

The shaft 11 of the rotor of the generator 4 with permanent magnets 8 is driven by the force of the wind, which rotates the wind wheel 1. As shown in Fig.9, the magnetic lines of force cross the conductors of two open rings of the windings of the first 17 and second 18, which are the working part of the windings, and the distance between the open rings of each winding are equal to the length in the circumferential direction of the permanent magnets 8 and electromotive forces are coordinated in direction and of equal magnitude. An electric current directed from the viewer is indicated by the (+) sign and to the viewer - (.). It is obvious that with the equality of the distance between the parts 17 and 18 of the windings and the length of the magnet 8, a balance of currents will be ensured in the parts of the windings 17 and 18 that are transmitted through the switching devices to the consumer and ensure the full use of energy

magnetic field of permanent magnets 8, which are moved by the driving force of the wind, starting with a wind force of 0.5 points.

If it is necessary to repair, prevent or stop the operation, the hydraulic cylinder 30 is connected with its fittings 46 and 47 to the hydraulic pump station and in the mode of controlled movement, mast 10

tilts, and at the end of work rises to the working position.

SUBSTITUTE SHEET (RULE 26)

Claims

Formula

1. A wind turbine unit comprising at least one wind wheel mounted on a shaft with the possibility of rotation of the generator rotor and

a fixed stator housing, in which a plurality of coils with leads of windings located on the stator housing along an arc of a circle so that the windings are located on this circle, are also circumferentially located on the rotor with magnet gaps between them, characterized in that the stationary housing of the generator stator is fixed the bracket on the support mast, the wind wheel shaft and the generator rotor shaft are interconnected, the generator rotor is made in the form of a non-magnetic carrier disk with constant constants installed along its external contour and magnets with poles located in the direction of the tangent to the contour and mounted on a shaft mounted in rotation bearings, and each stator coil is made of at least two windings, each of the windings is curved in the form of two, first and second, open rings, which are the working part of the windings, covering the area of location of the rotor magnets, and the ends of the open rings are interconnected

longitudinal sections of these windings, in each coil, the open rings of the first number of subsequent windings are placed coaxially in an arc of a circle between the open rings of the previous windings and 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.

2. The wind electric assembly according to claim 1, characterized in that the permanent magnets on the disk of the carrier are arranged in concert with each other at equal distances from each other, eliminating the formation of a sequential closed magnetic circuit.

3. The wind electric assembly according to claim 1, characterized in that the permanent magnets on the carrier disk are fixed with the same poles in the opposite direction, at a distance that ensures the interaction of magnetic fields between adjacent magnets.

4. The wind power unit according to claim 1, characterized in that the distance between the first and second open rings of the windings in each coil is equal to the length of the permanent magnet of the rotor.

SUBSTITUTE SHEET (RULE 26)

5. The wind electric assembly according to claim 1, characterized in that the permanent magnet carrier is mounted on a shaft mounted in angular contact bearings mounted in the stator housing in the generator rotor, and the wind wheel shaft, also installed in the rotary shaft, is connected to the generator shaft by means of a compensating coupling angular contact bearings.

6. The wind electric assembly according to claim 1, characterized in that the permanent magnet carrier is mounted on a shaft mounted in angular contact bearings mounted in the stator housing in the generator rotor, and the wind wheel shaft, also mounted radially, is attached to the generator shaft by means of an overrunning clutch - persistent bearings.

7. The wind power assembly according to claim 1, characterized in that on the supporting structure, which is a mast mounted on a foundation structure with a lateral bracket for mounting the stator of the generator, there is a radially located bearing on top of which is mounted a bearing support of the upper part of the wind wheel shaft.

8. The wind electric assembly according to claim 1, characterized in that the working surfaces of the wind wheel consist of plates of segments interconnected, which are L-shaped, smoothly bent, in cross section by conditional planes perpendicular to the shaft, the segments are pairwise mounted opposite each other relative to the axis of the shaft and each subsequent a pair of segments is rotated relative to the previous one around the axis of the shaft by the same selected angle, also provided by twisting of each segment relative to the perpendicular to the shaft, forming spiral convex-concave surfaces.

9. The wind power unit according to claim 1, characterized in that the wind wheel shaft is located vertically.

10. The wind power unit according to claim 1, characterized in that the wind wheel shaft is located horizontally.

1 1. The wind electric assembly according to claim 1, characterized in that the coils are made by modules in the form of hollow bodies of thin dielectric material, in which the windings are placed and filled with a non-conductive compound.

12. The wind power unit according to claim 1, characterized in that the connector rings

SUBSTITUTE SHEET (RULE 26) the windings and the connector in the generatrix of the holes in the coils exceed the thickness of the permanent magnet carrier by a size corresponding to the permissible deviations of the dimensions and working deformations of the structure.

13. The wind power unit according to claim 1, characterized in that the supporting mast is pivotally mounted on the foundation with the possibility of blocking.

14. The wind electric unit according to claim 13, characterized in that a hydraulic cylinder with a positive shoulder relative to the hinge of fastening the mast to the foundation with the possibility of connecting the piston and rod cavities to the pumping station with its fittings is fixed on the support mast and foundation on the eyes.

SUBSTITUTE SHEET (RULE 26)