RU127133U1 - ROTARY WIND UNIT - Google Patents

Abstract

1. A rotary wind turbine containing at least one wind turbine, consisting of a stator with curved guide vanes and a rotor with curved blades installed inside the stator, the shaft of which is mechanically connected to the generator shaft, characterized in that the wind turbine is additionally equipped with a stator installed and rigidly attached to it to it with an air duct having an annular cross section, decreasing from the stator upwards and ending with a pipe at its narrow end. 2. Rotary wind turbine according to claim 1, characterized in that the duct is made in the form of an inverted funnel. The rotor wind turbine according to claims 1 and 2, characterized in that the duct has an annular canopy in the form of a truncated cone, rigidly attached to it from the stator. 4. The rotor wind turbine according to claim 1, characterized in that the stator is made in the form of a spatial structure rigidly mounted on the supporting posts, consisting of a cover and a bottom located one above the other with a central hole for the passage of the rotor with curved blades of the wind turbine, while the cover and bottom of the stator connected to each other by a series of ribs evenly spaced along the outer perimeter, each of which is rigidly attached to the lid and to the bottom and protrudes beyond the lid and bottom, and on the inner perimeter of the lid and days Curved guide vanes are evenly placed, rigidly attached to the respective inner surfaces of the lid and bottom. 5. The rotor wind turbine according to claims 1 and 4, characterized in that the duct is fixed above the stator by means of brackets rigidly fixed to protruding beyond the cover p

Description

The utility model relates to wind energy, in particular, to the construction of wind turbines with fixed wind directing means, the rotor axis of which is vertical, and can be used to drive generators of power plants.

Known wind turbine containing a rotor with curved blades, mounted with the possibility of rotation relative to the vertical axis of the guide apparatus and mounted on it a weather vane. (USSR author's certificate No. 985402, class F03D 3/00, 12/30/1982 (analogue)).

Known wind power installation containing at least one rotary wind generator with a vertical axis of rotation, while the upper rotary wind generator is equipped with a cowl mounted on top. (RF patent No. 2390654, CL F03D 3/04, 2010 (analogue)).

Closest to the claimed combination of essential features is a rotor wind farm containing at least one module consisting of a stator with curved guide vanes and a rotor with curved blades installed inside the stator, the shaft of which is mechanically connected to the generator shaft, while at the upper end of the rotor shaft a tachogenerator is installed. (RF patent No. 2215898, IPC 7 F03D 3/04, 2003 (prototype)).

A disadvantage of the known solution is the insufficient degree of efficiency of the installation due to the fact that in conditions of increased unevenness of the wind, the excess part of the air flow that has got inside the rotor wind turbine slows down the rotation of the rotor.

When creating a utility model, the problem was solved to increase the efficiency of the rotor wind turbine.

The technical result is an increase in the efficiency of the rotor wind turbine in conditions of increased unevenness of the wind by reducing the resistance of the elements of the rotor wind turbine to the air flows passing through it.

The specified technical result is achieved due to the fact that in the rotor wind turbine containing at least one wind turbine, consisting of a stator with curved guide vanes and installed inside the stator of the rotor with curved blades, the shaft of which is mechanically connected with the shaft of the generator, according to a utility model, the wind turbine is additionally equipped installed above its stator and rigidly attached to it by an air duct having an annular cross-section that decreases upward from the stator and ends vayuscheesya pipe at its narrow end.

Moreover, according to a utility model, the duct is made in the form of an inverted funnel.

Moreover, according to a utility model, the duct has an annular canopy in the form of a truncated cone, rigidly attached to it from the side of the stator.

Moreover, according to the utility model, the stator is made in the form of a spatial structure rigidly fixed on the support posts, consisting of a cover and a bottom located one above the other with a central hole for the passage of the rotor with curved blades of the wind turbine, while the cover and bottom of the stator are connected uniformly next to each other located along the outer perimeter of the ribs, each of which is rigidly attached to the cover and to the bottom and protrude beyond the cover and the bottom, and along the inner perimeter of the cover and the bottom evenly curved guide vanes are fixed, rigidly attached to the corresponding inner surfaces of the lid and bottom.

Moreover, according to a utility model, the duct is fixed over the stator by means of brackets rigidly fixed to the stator ribs protruding beyond the cover.

Moreover, according to the utility model, the rotor is made in the form of a spatial structure consisting of rigidly mounted on a shaft mounted for rotation, upper and lower disks with curved blades located between them and rigidly attached to them, adjacent to the outer perimeter of the disks and evenly spaced along it .

Moreover, according to the utility model, curved stator guide vanes and curved rotor blades are made radially curved in opposite directions to each other.

Moreover, according to a utility model, the rotor shaft is hollow.

A distinctive feature of the claimed rotary wind turbine is that the wind turbine is additionally equipped with an air duct installed above its stator and rigidly attached to it, while the air duct has an annular cross section that decreases upward from the stator and ends with a pipe at its narrow end, i.e. the duct is made in the form of an inverted funnel and has an annular canopy in the form of a truncated cone, rigidly attached to the end of the funnel from the upper end of the stator, which improves the efficiency of the rotor wind turbine in conditions of increased unevenness of the wind by reducing the resistance of the elements of the rotor wind turbine to the air flows passing through it due to, on the one hand, the creation of a certain vacuum over the narrow end of the duct and picking up the external air flow through the gap p between the upper end of the stator and an annular canopy duct, on the other hand.

The utility model is illustrated by a description of a specific example of its implementation and the accompanying drawings, where:

figure 1 shows a General view of a rotary wind turbine;

figure 2 - cross section aa figure 1 (the relative position of the elements of the stator and rotor);

figure 3 - section BB (welded frame for installing the upper bearing assembly);

figure 4 - section bb In figure 1 (relative position of the duct and wind turbine);

figure 5 - node G figure 1 (mounting the stator to the base site);

The rotor wind turbine contains, as shown in our example, at least one wind turbine 1, consisting of a stator 2 with curved guide vanes 3 and a rotor 4 with curved blades 5 installed inside the stator 2, the shaft 6 of which is mechanically, for example, by means of a standard design coupling connected to the shaft of the generator (not shown in the drawing).

The stator 2 can be made in the form of a rigidly fixed, for example, on the basis of 7 spatial structure, consisting of a cover 8 and a bottom 9 located one above the other with a central hole 10 for the passage of the rotor 4 with curved blades 5 of the wind turbine 1 (Fig. 1).

The cover 8 and the bottom 9 of the stator 2 can be made, for example, of sheet metal in the form of flat rings 11 (figure 2).

The cover 8 and the bottom 9 of the stator 2 can be connected to each other in a row of ribs 13 evenly spaced along the outer perimeter 12, for example, as shown in our example, the cover 8 and the bottom 9 are used to obtain a rigid structure eight ribs 13, each of which is rigidly attached, for example, by welding, to the cover 8 and to the bottom 9. The ribs 13 protrude both outside the cover 8, acting as a support either for the next wind turbine or for the duct 14, and outside the bottom 9, playing the role of traditional supports with connecting flanges with holes for threaded fasteners, for example, a bolt-nut, for installation either on the platform 15 of the base 7, or when installing wind turbines on top of each other, creating air channels for air intake.

The ribs 13 can be made in the form of segments of the desired metal, for example, tubes of square cross section.

On the inner perimeter 16 of the cover 8 and the bottom 9 are evenly spaced curved guide vanes 3, rigidly attached to the corresponding inner surfaces of the cover 8 and the bottom 9 (figure 2).

The guide vanes 3 of the stator 2 can be made of a metal sheet with a thickness of, for example, 2 mm (the thickness depends on the size of the wind turbine).

The cross section of the guide vanes 3 of the stator 2 can have an arcuate profile, which makes it possible to say that the guide vanes 3 are made radially curved.

The guide vanes 3 are bent so that the gap between two adjacent vanes 3 forms a smoothly tapering aerodynamic channel (confuser). This achieves an increase in dynamic pressure and air flow rate, which in turn allows to increase the overall efficiency of the wind turbine. At the same time, the curved guide vane 3 has greater rigidity than straight, which allows to reduce the thickness of the metal of which it is made, and in general to reduce the total weight of the installation. To give additional rigidity to the blades 3, not directly adjacent to the ribs 13, an edge can be made at the edge.

On the outer surface of the cover 8 of the stator 2 there is a platform 17 in the form of a welded frame of a traditional construction made of rolled metal for fastening the upper bearing assembly 18. (Fig.3 and Fig.4).

Bottom of the bottom 9 of the stator 2 there are places of threaded fastening of a removable welded frame of a similar design and the lower bearing assembly 19 (figure 4).

Top and bottom, the stator 2 ends with the same connecting flanges 20 with through holes made therein for screw fasteners, for example, for a bolt, which allows you to connect individual modules to each other or mount on the platform 15 of the base 7, as shown in our example (Fig. 5).

The rotor 4 is made in the form of a spatial structure, consisting of rigidly mounted on the shaft 6, mounted for rotation, the upper 21 and lower 22 disks placed between them and rigidly attached, for example, by welding, to them curved blades 5 adjacent to the outer perimeter 23 disks and evenly spaced along the outer perimeter 23.

The upper 21 and lower 22 discs and curved blades 5 of the rotor 4 can be made of sheet metal 1 ... 2 mm thick.

The cross section of the curved blades 5 of the rotor 4 may have an arcuate profile, which makes it possible to say that the curved blades 5 are made radially curved.

From the line of the outer perimeter 23 of the upper 21 and lower 22 disks to the center, grooves 24 are cut evenly spaced around the circumference along the outer perimeter 23, each of which follows the shape and dimensions of the profile of the curved blade 5 (figure 2). As a result, when assembling the rotor 2, each of the curved blades 5 is placed in the corresponding grooves 24 of the upper 21 and lower 22 disks, thereby achieving the accuracy of the location of the curved blades 5 of the rotor 4 around the circumference and increasing the total rigidity of the rotor.

It should be noted that the curved guide vanes 3 of the stator 2 made by the radially curved and the curved blades 5 of the rotor 4 are radially curved in opposite directions to each other, i.e. as shown in our example, if the curved blades 5 of the rotor 4 with the convex side are turned to the right, then the curved guide vanes 3 of the stator 2 with the convex side are turned to the left (figure 2)

Openings can be made in the upper 21 and lower 22 disks of the rotor 4 to reduce mass and reduce thermal deformations after welding.

The shaft 6 of the rotor 4 can be hollow, which reduces the total mass of the rotor 4, and also allows wires through the shaft 4 from the generator (not shown) to be placed in the case of the latter being placed between two wind turbines.

The wind turbine 1 is additionally equipped with an air duct 14 mounted above the stator 2 and rigidly attached to it, having an annular cross-section, decreasing upward from the stator 2 and ending with a pipe 28 at its narrow end (Fig. 1).

As shown in our example, the duct 14 is made in the form of an inverted funnel, i.e. end face 29 of large diameter is placed directly above the stator 2 of the wind turbine 1, and can be made, for example, by stamping, for example, metal from sheet metal.

To the end 29 of the large diameter of the duct 14, i.e. from the side of the stator 2, rigidly attached, for example, by welding, an annular canopy 30 in the form of a truncated cone, which can also be made of metal sheet metal.

To ensure rigidity of the structure of the duct 14 from the inner side of the duct 14 along the end 29 is rigidly fixed, for example, by welding, the rim 31, which is the supporting element of the duct 14.

The rim 31 can be made, for example, in the form of a ring from a steel corner directed by the apex to the axis of rotation.

Brackets 32 made in the form of oblique racks of the same material as the rim can be welded to the rim 31 to enable the installation of the duct 14 over the stator 2 of the wind turbine 1.

The duct 14 can be fixed above the stator 2 by means of brackets 32, for example, by means of threaded fasteners, for example, a bolt-nut, on the ribs 13 of the stator 2 protruding beyond the cover 8.

The base 7 can be made in the form of a platform 15, made in the form of a welded frame structure, for example, of channels, rigidly mounted, for example, on six posts 33, each of which is made in the form of a segment, for example, a steel pipe. The racks 33 can be rigidly attached, for example, by welding, support plates 34, which can be fixed on a prefabricated concrete base.

The device operates as follows.

The rotor wind turbine is mounted at the place of its use.

A rotary wind turbine comes into operation with the first gusts of wind.

The air flow is captured by the curved guide vanes 3 of the stator 2, which direct it to the curved blades 5 of the rotor 4, creating an effort to untwist the rotor 4. Part of the air flow penetrates the inside of the installation (behind the rotor blades) and due to the pressure difference arising in the duct 14 and at the outlet of the pipe 28 of the air duct 14, the air flow is redirected to the atmosphere, while the annular canopy 30 in the form of a truncated cone defines an additional suction of air into the air duct 14, increasing the speed of exhaust air ear flow, thereby increasing the air exchange within the wind turbine 1, which increases the efficiency of the wind turbine rotor, reducing the overpressure inside the wind turbine, i.e. increasing the efficiency of the rotor wind turbine in conditions of increased unevenness of the wind by reducing the resistance of the elements of the rotor wind turbine to the air flows passing through it.

Claims (8)

1. A rotary wind turbine containing at least one wind turbine, consisting of a stator with curved guide vanes and a rotor with curved blades installed inside the stator, the shaft of which is mechanically connected to the generator shaft, characterized in that the wind turbine is additionally equipped with a stator installed and rigidly attached to it to it with an air duct having an annular cross-section, decreasing from the stator upwards and ending with a pipe at its narrow end. 2. The rotary wind turbine according to claim 1, characterized in that the duct is made in the form of an inverted funnel. 3. Rotary wind turbine according to claims 1 and 2, characterized in that the duct has an annular canopy in the form of a truncated cone, rigidly attached to it from the side of the stator. 4. The rotor wind turbine according to claim 1, characterized in that the stator is made in the form of a spatial structure rigidly fixed to the support posts, consisting of a cover and a bottom located one above the other with a central hole for the passage of the rotor with curved blades of the wind turbine, the cover and the stator bottom is connected to each other by a series of ribs evenly spaced along the outer perimeter, each of which is rigidly attached to the cover and to the bottom and protrudes beyond the cover and bottom, and along the inner perimeter of the cover and searching evenly spaced curved vanes fixedly attached to the respective inner surfaces of lid and bottom. 5. Rotary wind turbine according to claims 1 and 4, characterized in that the duct is fixed above the stator by means of brackets rigidly fixed to the stator ribs protruding beyond the cover. 6. The rotor wind turbine according to claim 1, characterized in that the rotor is made in the form of a spatial structure consisting of rigidly mounted on a shaft mounted for rotation, upper and lower disks with curved blades located between them and rigidly attached to them, adjacent to the outer perimeter of the discs and evenly spaced along it. 7. The rotor wind turbine according to claim 1, characterized in that the curved guide stator vanes and curved rotor blades are made radially curved in opposite directions relative to each other. 8. The rotor wind turbine according to claim 1, characterized in that the rotor shaft is hollow.

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