WO2010050837A1 - Wind power plant - Google Patents

Abstract

The invention relates to wind power engineering. The wind power plant comprises a wind propeller and a generator which are mounted on the same shaft and are accommodated inside a vertical air duct. An outlet section is arranged in the lower part of the duct. An inlet section is mounted on the upper part of the duct with the aid of a hinged joint, wherein the aperture plane of said inlet section is not horizontal and the area of the aperture is not less than that of the duct cross-section. The inlet section is provided, on the side opposite the aperture, with spring-loaded air bypass flaps. The inlet section is provided with a tail fin. The wind propeller is provided with a front fairing. A boundary layer control system in the form of an outwardly open slot, which is made in the duct side wall and is protected by a deflector on the duct outer surface on the side to which the aperture of the inlet section is oriented, is arranged in front of the wind propeller. The deflector is mounted on the inlet section and has, on the lateral edges thereof, outlet holes which are oriented in a direction opposite that of the outlet section aperture. The technical result is that it is possible to control the boundary layer taking into account the wind direction and to increase the efficiency of the wind power plant.

Description

 WIND POWER PLANT

FIELD OF THE INVENTION

The present invention relates to wind energy and can be used to generate electricity from a wind turbine.

State of the art

Currently, there are many options for wind power plants. For example, a rotary-type wind turbine with a vertical axis of rotation is known for its simple construction (EM Fateev “Motors” - M .: Gosenergoizdat, 1946. - P. 42). This wind turbine has low efficiency: its wind energy utilization coefficient is 2-3 times less than that of modern wind turbines with a horizontal axis of rotation. This drawback is due to the fact that one half of the wind turbine blades (passive part), covered by a cowl with a flow separation, moves against the wind and does not do useful work, creating only unnecessary resistance, in the other half of the blades (active part creating useful torque) also flows around with flow separation and adds unnecessary aerodynamic drag.

Also known wind turbine G.P. Drozdova (Schefter Y.I. et al. “Inventor of wind engines and wind turbines.” - M.: Publishing House of the Ministry of Agriculture of the USSR, 1968. - S. 24-25). This document discloses a wind power installation comprising a windshield and a generator installed on one shaft and placed inside a vertical air duct, in the lower part of which an inlet section is made, and in the upper part an outlet section is made in the form of a knee with 90 ° rotation, co

SUBSTITUTE SHEET (RULE 26) unified with the body of the vertical air duct with the possibility of rotation around the axis of the latter. However, the efficiency of such a wind turbine, as indicated in the same source, is low.

International application WO 2008/086944 (published July 24, 2008) describes a wind power installation with a vertical axis, in the air channel of which a wind wheel is installed in the form of a body of revolution of a cylindrical, barrel-shaped, conical or other shape, and the blades of this wind wheel pass along the generatrix of the body of revolution or cross them at a certain angle, so that the wind wheel resembles a drum with straight or inclined blades.

In the application of the UK Ns 2446467 (publ. 13.08.2008) disclosed a multi-blade wind turbine with a vertical axis, which is an ovoid streamlined body, on the outer surface of which blades are made, which can be deflected or retracted. In US patent Na 7400057 (publ. July 15, 2008) a wind turbine with a vertical axis is presented, in which the turbine blades are multi-tiered and are located on the surface of the rotation paraboloid. At the same time, the air flow guides in the confuser are aerodynamically streamlined in cross section, and air ducts are made inside them. Ducts are made in the blades of a wind wheel. Jumpers supporting the inner body of the wind wheel are made in the form of inclined beams.

The disadvantage of all these three designs is their great complexity in manufacturing, and, as a result, the high cost. In the patent of the Russian Federation N <_ 2331792 (publ. 20.08.2008) a wind power installation is presented containing a diffuser flow accelerator in the air duct, and the central body with the wind wheel is equipped with cylindrical shells attached by radial struts to the central body with the possibility of forming an annular gap with it ,

SUBSTITUTE SHEET (RULE 26) while the blades of the wind wheel and the guide apparatus are mounted on the shells. This wind power installation has increased efficiency, however, its disadvantage is also the great complexity and high manufacturing cost. RF patent N ° 2157920 (publ. 20.10.2000) discloses a vertical power plant with a vertical axis, on the windwheel of which confusers are oriented, oriented in the directions of the prevailing winds. The disadvantage of this rather simple installation is the impossibility of its use in areas with constantly changing wind directions.

RF patent Ns 2231679 (published on June 27, 2004) describes a wind farm with a vertical channel in which the blades of a wind wheel expand outward and can change the angle of attack using an electric motor located in the fairing. Due to this, the efficiency of the installation increases, but its complexity sharply increases.

SUMMARY OF THE INVENTION

Thus, the aim of the present invention is to eliminate the disadvantages of these analogues with obtaining a technical result in the form of increasing the efficiency of a wind power installation by expanding the range of operating wind speeds, which ultimately reduces the cost of kilowatt hours of generated energy.

The goal is achieved in the present invention, which is a wind power installation comprising a wind wheel mounted on one shaft and a generator located inside the upper part of the vertical air duct, in the lower part of which there is an outlet section for air exhaust, and on the upper part of the vertical air duct using a swivel mounted inlet section for air intake, the plane is open

SUBSTITUTE SHEET (RULE 26) which is generally not horizontal, and whose opening area is not less than the cross-sectional area of the vertical air duct, while the lower end of the inlet section is equipped with a boundary layer control system. In one of the possible variants of the wind power installation of the present invention, the boundary layer control system is made in the form of an open outward gap in the side wall of the vertical air duct, protected on the outer surface of the vertical air duct from the side facing the opening of the inlet section, with a deflector installed in the inlet section and having outlet openings on their lateral edges facing in a direction opposite to the opening direction of the inlet portion.

At the same time, it is advisable that the angle of coverage of the slit by the deflector in the side wall of the vertical air duct is at least 100 °.

Another feature of the wind power installation of the present invention is that the inlet section is made in the form of a knee with a rotation of about 90 °.

In this case, it is advisable that the lower envelope of rotation of the elbow of the inlet section was made with a radius of rotation not less than the inner diameter of the vertical air duct. The opening plane of the inlet portion can be almost vertical.

Another feature of the wind power installation of the present invention is that the inlet section is equipped externally with horizontal aerodynamic surfaces to reduce the pressure of the inlet section on the articulation in the presence of wind.

Another feature of the wind power installation of the present invention is that opening the input section

SUBSTITUTE SHEET (RULE 26) may have rounding at its edges.

Another feature of the wind power installation of the present invention is that the inlet portion on the side opposite to the opening is provided with spring-loaded air bypass flaps. Due to this, the present invention provides an additional technical result in the form of an increase in the average annual time of active operation of a wind power installation by expanding the range of operating speeds of the wind flow.

Another feature of the wind power installation of the present invention is that the inlet portion can be provided with a tail unit.

Finally, another feature of the wind power installation of the present invention is that the generator can be installed in the front fairing of the wind wheel.

Brief Description of the Drawings

The invention is explained below with reference to the drawings, in which the same elements are provided with the same reference position. ''

In FIG. 1 is a side view of a wind power plant of the present invention.

In FIG. 2 shows a cross-sectional view of the inlet portion along line A-A in FIG. one.

In FIG. 3 shows an enlarged cross-section of a node I of FIG. In FIG. 4 is a cross-sectional view of assembly I along line G-D in FIG. 3.

In FIG. 5 shows a cross-sectional view of a fairing pylon along the line E-E in FIG. four.

SUBSTITUTE SHEET (RULE 26) In FIG. Figure 6 shows the values of power N obtained in tests on the model depending on the Ap load of the wind wheel in the wind power installation of the present invention at a wind speed of 10 m / s and a wind wheel diameter of 2 m.

DETAILED DESCRIPTION OF THE INVENTION

Shown in FIG. 1, the wind power installation comprises a vertical air duct 3, in the upper part of which there is an inlet section 1 mounted for rotation about the axis of the vertical air duct 3. This rotation can be provided by means known in the art, which are described, in particular, in the aforementioned Shefter's book and others and are not included in the scope of this invention. In particular, this feature is provided by articulation 4, described in more detail below. The inlet section 1 can be made in the form of a knee with a rotation of 90 °, and its upper part has the form of a confuser with an opening, the vertical length of which substantially exceeds its width, and the opening plane is located vertically. This arrangement of the opening plane, however, is not necessary, it is only important that this opening plane is not horizontal. Such an arrangement of the aperture plane can provide the greatest efficiency of this confuser due to the maximum hit of the wind flow in the opening of the inlet section 1. The inlet section 1 can be equipped with a tail unit 2 to orient it in the direction of the wind. In FIG. 2, the tail is made of two-keel, although it can be single-keel or have a larger number of keels. In addition, the inlet section 1 has fillets at its edges 12 to improve streamlining and prevent air flow stall, which could lead to a decrease in the efficiency of the wind power installation.

SUBSTITUTE SHEET (RULE 26) It should be noted that the implementation of the input section 1 in the form of a knee with a rotation of 90 ° is not mandatory. In particular, the inlet section 1 may have an inclined wall opposite to the opening, and the plane of this opening may be slightly inclined relative to the axis of the air duct 3, so that opening B-B will “look” slightly upward. Other versions of the inlet section 1 may be used. It is important here that opening BB of the inlet section 1 is directed away from the axis of the air duct channel 3 and has a substantially larger cross-sectional area than the cross-sectional area of the air duct 3. so that the lower envelope of the rotation of the knee of the inlet section 1 was made with a radius of rotation not less than the inner diameter of the vertical air duct 3.

The inlet section 1 may also be provided with aerodynamic surfaces 21. These aerodynamic surfaces 21 are designed to reduce the pressure of the inlet section on the swivel in the presence of wind due to the creation of lifting force. From this condition, according to the principles known in aerodynamics, the shape of the aerodynamic surfaces 21 is selected, which is not included in the scope of this invention.

In the air duct 3 using, for example, a cross-shaped pylon 13, a wind turbine is fixed (see Fig. 4), consisting of a wind wheel 5 equipped with a passive mechanism for changing the angle of attack, a generator 7 mounted on the shaft 16 of the wind wheel, and a fairing 6. Pylon 13 it is also equipped with drop-shaped fairings 10 that improve its aerodynamic characteristics. These elements can in principle have any suitable form known in the art (see, for example, the aforementioned patents of the Russian Federation ЖН 2157920 and 2331791), and their implementation is not included in the scope of this invention.

SUBSTITUTE SHEET (RULE 26) Before the windwheel 5, a boundary layer control system (see Fig. 3) is made, consisting of inlet slots 17 located around the circumference of the inner surface of the air duct 3, outlet slots 18 located around the circumference of its outer surface, an annular protrusion 14 fixed to the outer surface vertical air duct 3, and the deflector 15, mounted on the outer surface of the inlet section 1. The use of the suction system of the boundary layer is known, in particular, from US patent JsTs 5099685 (publ. 31.03.1992). However, in the present invention, the suction of the boundary layer (control of the boundary layer) is carried out taking into account the direction of the wind through the use of a deflector 15, installed, as described above, at the inlet section 1. The angle of coverage of the deflector 15 of the exit slots 18 in the side wall of the vertical air duct 3 is at least 100 °. Thus, the exit slots 18 on the windward side are always covered by a deflector 15 having outlet openings on their lateral edges facing the direction opposite to the opening direction of the inlet portion 1.

In the lower part of the vertical air duct 3 there is an outlet section 20, which serves to release the air stream after it passes the wind wheel 5. In FIG. 1 arrows indicate the direction of air flow. It is important here that the height of the outlet section of the outlet section 20 relative to the ground should not exceed the diameter of the air duct 3, and the opening angle α of the vertical air duct 3 in front of the outlet section 20 can range from about 17 ° to about 20 °.

As can be seen from FIG. 2, the inlet portion 1 is provided on the side opposite to the opening with air bypass flaps 8. These air bypass flaps 8 are spring loaded with any damping devices.

SUBSTITUTE SHEET (RULE 26) 11, for example, springs, hydraulic cylinders, etc. In addition, the inlet section 1 can be equipped with additional air bypass flaps (not shown) made on its side wall closer to the gap. In FIG. 5 shows a cross section of a pylon 13, the cowling of which 10 has a cross-section in the form of a drop-shaped aerodynamically streamlined shape, tapering down in the direction of air flow.

The wind power plant of the present invention operates as follows.

In the presence of wind, the inlet section 1, due to the tail unit 2, acting as a weather vane, and the swivel joint 4, is set with its opening towards the wind (arrow V). In this case, the pressure on the swivel joint 4 from the mass of the inlet section 1 is reduced due to the aerodynamic lifting force arising on the aerodynamic surfaces 21. The captured wind flow after turning through 90 ° in the inlet section 1 moves down the vertical air duct 3 and rotates the helicopter 5, which drives the generator 7 through the shaft 16. The exhaust air leaves the vertical air duct 3 through the outlet section 20 outward in all directions, while cooling the generator 7.

The suction of the boundary layer by means of inlet slots 17 and exit slots 18 ensures equalization of the velocity field and air flow pressure on the wind wheel 5, and thereby increases the power taken from the wind wheel. The functioning of the boundary layer suction system is provided by means of a deflector 15 and an annular protrusion 14, forming a chamber, the outlet openings of which due to the optimally selected size of the deflector 15 are always located in the zone of reduced pressure, which always arises from the backlight

SUBSTITUTE SHEET (RULE 26) side of the cylindrical part of the installation. This effect is achieved due to the automatic installation of the deflector 15, mounted on the rotary inlet section 1, in the zone of increased pressure of the wind flow (i.e., on the windward side of the wind power installation). When the wind flow reaches a value that exceeds the permissible from the point of view of technical characteristics of the wind turbine, the air bypass flaps 8 located on the surface of the inlet section 1 begin to open, overcoming the force of the damping devices 11 and thereby maintaining the speed of the air flow inside the air duct 3, not exceeding the allowable limit. At the same time, the full opening of the air bypass flaps 8 also allows the structure to withstand the hurricane speeds of the wind flow. The specified mode of operation of the air bypass flaps 8 is ensured by the appropriate choice of spring properties in the damping devices 11.

In FIG. Figure 6 shows the values of power N obtained in tests on the model, depending on the value Ap of the loading of the wind wheel. Rel

The significant value Ap is calculated by the formula Ap = ^p , where Ap is

the pressure drop on the wind wheel (kg / m ² ), p is the density of air (kg c ² / m ⁴ ), and V is the air velocity (m / s). The tests were carried out in the TsAGI wind tunnel on a scaled-down model at a scale of 1: 10. From this graph it is seen that the maximum power values can reach 3 kW, which is about three times more than the power of a wind power installation made according to the traditional scheme. Industrial applicability of the wind power plant of the present invention provides an increase in the efficiency of the wind power unit in the operating range of wind flow speeds and expansion

SUBSTITUTE SHEET (RULE 26) range of working speeds of a wind stream. Due to this, in the present invention is achieved by reducing the cost of kilowatt hours of generated electricity.

SUBSTITUTE SHEET (RULE 26)

Claims

Claim

1. A wind power installation comprising a wind wheel and a generator installed on one shaft and placed inside a vertical air duct in its upper part, in the lower part of which there is an outlet section for air exhaust, and an inlet section is installed on the upper part of the vertical air duct using an articulated joint air inlet, the aperture plane of which is generally not horizontal, and whose aperture is not less than the cross-sectional area of the vertical air duct, the lower end of the inlet portion is provided with a boundary layer control system.

2. The wind power installation according to claim 1, wherein the boundary layer control system is made in the form of an open outside slot in the side wall of the vertical air duct, protected on the outer surface of the vertical air duct from the side facing the opening of the inlet portion with a deflector mounted on the inlet section and having on its lateral edges outlet openings facing in the direction opposite to the opening direction of the inlet section.

3. Wind power installation according to claim 2, in which the angle of coverage of the gap with the deflector in the side wall of the vertical air duct is at least 100 °.

4. Wind power installation according to claim 1, in which the inlet section is made in the form of a knee with a rotation of about 90 °.

5. Wind power installation according to claim 4, in which the lower envelope of the rotation of the knee of the inlet section is made with a radius of rotation not less than the inner diameter of the vertical duct.

SUBSTITUTE SHEET (RULE 26)

6. The wind power plant according to claim 4, wherein the opening plane of the inlet section is almost vertical.

7. The wind power installation according to claim 1 or 4, in which the inlet section is equipped externally with horizontal aerodynamic surfaces, providing pressure reduction of the inlet section to its articulation with a vertical air duct in the presence of wind.

8. Wind power installation according to claim 1, in which the opening of the input section has a rounding at its edges.

9. The wind power plant according to claim 1, wherein the inlet portion on the side opposite to the opening is provided with spring-loaded air bypass flaps.

10. Wind power installation according to claim 1, in which the input section is equipped with tail unit.

11. Wind power installation according to claim 1, in which the wind wheel is equipped with a front fairing, and the generator is installed in this fairing.

'FIXED SHEET "RULE 91 ISA / RU