RU2717195C1 - F-darier wind rotor - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to wind power engineering. Windmotor contains vertical shaft, lower bracket arranged on shaft and upper bracket with hub, three outward bent blades fixed by both ends to upper and lower brackets, and connected to electric generator. Blades are made curved in shape described by formula of chain line of equal resistance. Upper and lower brackets have a streamlined profile.

EFFECT: invention is aimed at improvement of conversion efficiency of wind flow kinetic energy into mechanical energy of rotation and improvement of mechanical strength of wind rotor.

3 cl, 5 dwg

Description

State of the art

Patent US 1835018, 12/12/1931, author Darrius Georges Jean Marie, “Turbine with a rotating shaft, transverse to the wind flow”, adopted by the applicant as the closest analogue, is known from the prior art. The turbine is designed so that a blade with an aerodynamic profile achieves a speed that far exceeds the flow velocity, in which case the energy of the lifting force is very large and is at an angle between the relative speed and the circular one, which in no case will exceed the maximum angle of attack, this will be the separation of streamlines along the profile without oscillation of the blades. The blades may be attached to their support disk in any suitable manner, such as a weld or the like.

The blades can be straight and parallel to the shaft to form, when assembled, a cylindrical drum or squirrel pin

In the presence of unconditional advantages, such as the lack of guidance to the wind, high efficiency - this turbine has several disadvantages: significant loads on a rotating mast associated with the Magnus effect and low mechanical reliability In the case of a turbine with curved blades, fastening them at one point at the top and the lower part requires emergency measures to strengthen both the blades and the mounting points of the blades with the generator assembly, and the mast, which leads to a heavier structure and a decrease in its reliability. When using a turbine with straight blades, the blades are simplified, but the transverse traverses are sharply lengthened and heavier, which also requires balancing the entire turbine and reinforcing both the traverse and the mounting points of the traverse with the generator assembly, and the mast, additional transverse traverses can introduce up to 50 % loss in turbine efficiency (Gorelov D.N., Energy characteristics of the Darier rotor, 2010).

SU 1373860 A1, February 15, 1988, Yu.V. Shevchenko, "Wind turbine rotor." The invention allows to increase the strength of the rotor and manufacturability. Each blade has a screw twist in length, and its axis is made linear. This embodiment reduces the bending moment acting on the blades, and simplifies the manufacturing process of the rotor. Blades m. made both monocoque and spar. In the latter case, the screw twist of the blades is relative to the side members, which ensures uniformity of the rotor torque and prevents the occurrence of vibrations and torsional vibrations of the rotor.

The prior art mobile wind power complex. (RU 119821 119821 U1, F03D 7/06, 08/27/2012). A mobile wind energy complex with a vertical axis of rotation, containing a rotor of two blades mounted on a traverse located on a movable hub, mounted on a bearing on a mast mounted on a mobile vehicle, characterized in that the rotor is made of F-Darier type, and it is additionally introduced the third blade, while the blades have an arcuate, curved outward shape of the aerodynamic profile, the axis of the blades are spaced at an angle of 120 °, in the middle part of the hub there is a synchronizer of rotation of the blades in three short transverse crossbeams with weights at their ends, attached to the middle of each of the blades using hinges and traverses, and both ends of each of the blades are attached using rotary spring hinges to traverses located at the ends of the movable hub, while on the mobile the vehicle is located in a thermally insulated casing, the battery and the control unit.

This utility model patent relates only to a method of adjusting the angle of attack of the blades and placing the unit on special sleds to provide mobility. This utility model considers neither the shape of the blade, nor its profile, nor other geometric parameters.

SUMMARY OF THE INVENTION

The objective of the claimed invention is the creation of a wind rotor with an axis perpendicular to the wind flow, which with a minimum weight and dimensions has close to the theoretically achievable efficiency of converting the kinetic energy of the wind flow into mechanical energy of rotation of the generator and maximum mechanical strength.

The technical result of the claimed invention is to increase the conversion efficiency of the kinetic energy of the wind flow into the mechanical energy of rotation of the generator and to achieve maximum mechanical strength.

The technical result of the claimed invention is achieved due to the fact that the F-Darier rotor contains a stationary vertical shaft, streamlined lower and upper brackets with a hub located on the shaft, three blades curved outward, motionlessly attached by both ends to the upper and lower brackets, an electric generator located in the streamlined hub on the upper bracket, and the blades are made aerodynamic, described by the formula of a chain line of equal resistance:

Where

ρ is the bulk density;

g - accele St. falls;

A is the cross-sectional area;

T ₀ - tension force;

a is the coefficient;

m is the mass of the blade;

V- rotation speed:

r is the radius of the rotor;

x is the abscissa value;

y is the value along the ordinate axis.

In the particular case of the implementation of the claimed technical solution, the blades are made in the form of monolithic, thin-walled composite structures with internal stiffeners and are spaced 120 ° apart.

In the particular case of the implementation of the claimed technical solution, the blades are made with an elongation coefficient of λ = 8, an axisymmetric profile with a thickness of 21% and an angle of attack of 15 °.

Due to the selected shape of the blades described by the parabolic cosine formula, the stresses generated during the rotation of the blades due to centrifugal force are minimized, it also allows, other things being equal, to shorten the transverse upper and lower arms, reducing the load on them, and the spherical shape of the F-Darier wind rotor has the maximum swept area with minimum dimensions. The applied technical solution also allowed the use of a fixed axis and completely solved the problem with increased wind load caused by the Magnus effect. Due to the optimized angle of attack of the blades, it was possible to stabilize the speed of rotation of the wind rotor with strong winds up to 60 m / s.

Brief Description of the Drawings

Details, features, and advantages of the present invention follow from the following description of embodiments of the claimed technical solution using the drawings, which show:

FIG. 1 - appearance of the F-Darier wind rotor;

FIG. 2 - blade shape and aerodynamic profile;

FIG. 3 is a top view

FIG. 4 - F-Darier wind rotor in the context;

Fig 5 - flow around the blades at low (a) and high (b) air flow rates.

The following positions are indicated in the figures: 1 - blades; 2 - aerodynamic brackets; 3 - electric generator; 4 - fixed vertical shaft.

Disclosure of Invention

The F-Darier wind rotor with a vertical shaft (Fig. 1) contains three curved blades (1), made in the form of monolithic, thin-walled composite structures with internal stiffeners and an aerodynamic profile, a stationary vertical shaft (4), in the upper part of which a stator is fixed generator (3), aerodynamic lower and upper bracket (2) with a streamlined hub, to accommodate the rotor of the generator. Three blades (1) are fixedly attached to both upper and lower brackets (2) by both ends. The blades (1) are made in the form described by the formula of a chain line of equal resistance, curved outward, and spaced 120 ° apart.

The invention improves the efficiency and reliability of wind generators

- Due to the selected shape of the blades (Fig. 2), described by the formula of the chain line of equal resistance (parabolic cosine):

Where

T ₀ = mν ² / r,

ρ is the bulk density;

g is the acceleration of gravity;

A is the cross-sectional area;

T ₀ - tension force;

a - coefficient:

m is the mass of the blade;

V is the rotation speed;

r is the radius of the rotor;

x is the value along the abscissa;

y is the value along the ordinate axis.

The optimal blade shape is achieved with the following values along the abscissa and ordinate for specific wind speeds and composite materials;

The claimed shape of the blades minimizes the unevenness and strength of the stresses along the generatrix of the blade, arising from the rotation of the blades (1) due to centrifugal force;

- due to the shortening of the transverse upper and lower brackets, their strength increases with less weight and aerodynamic drag is minimized. So the coefficient of shortening of the transverse brackets is 40% compared with straight blades with a comparable swept area;

- due to the aerodynamic shape of the transverse upper and lower brackets and the presence of the fairing of the generator, aerodynamic losses of the structure are significantly reduced;

- due to the sphericity of the wind rotor, which allows you to have a maximum swept area with minimum dimensions;

- due to the upper location of the generator (3) and the use of a fixed axis, eliminate stresses and vibrations caused by increased wind load due to the Magnus effect (Fig. 4)

- due to the optimization of the aerodynamic profile (Fig. 2), the angle of attack of the blade (1) and the elongation coefficient (λ = L / b, where L is the length of the blade, b is the length of the chord), high efficiency is achieved at low speeds of the incident wind flow and At the same time, the range of winds is expanding at which the effective conversion of kinetic wind energy into electrical energy occurs due to a decrease in torque during strong winds due to stalling of the wind flow.

Simulation showed that the optimal characteristics of the wind rotor are achieved with: an elongation coefficient of λ = 8, an axisymmetric profile with a thickness of 21% and an angle of attack of 15 °. At the same time, a wind flow utilization factor of 0.7 was obtained. This is very close to the theoretical value of 0.72 for the Darier rotor with straight blades (Gorelov D.N. Energy characteristics of the Darier rotor, 2010) and significantly higher than the theoretical value of the wind flow utilization factor of 0.593 for propeller-type wind turbines.

Device operation

At the time of launch, the F-Darier wind rotor behaves like a Savonius rotor, i.e. due to the difference in pressure of the wind flow in the right and left parts relative to the axis of rotation. But then it quickly picks up speed and starts to rotate at a speed 4-5 times higher than the wind speed due to aerodynamic forces. Moreover, the shape of the blade profile and the angle of attack are calculated taking into account the effective operation up to wind speeds of 25-30 m / s. (Fig. 5 a) With a further increase in wind speed, the wind flow begins to stall due to both the shape of the blade profile and the angle of attack, thus the blade’s lifting force decreases sharply and torque decreases, i.e. there is an effective braking of the F-Darier wind rotor with a loaded generator (Fig. 5 b).

Claims (4)

1. A wind rotor comprising a vertical shaft, a lower bracket and an upper bracket with a hub located on the shaft, three blades curved outward, fixedly attached at both ends to the upper and lower brackets, characterized in that connected to the electric generator, while the blades are made curved in the form described by the formula of the chain line of equal resistance, and the upper and lower brackets are made with a streamlined profile. 2. The rotor according to claim 1, characterized in that the blades are made in the form of composite structures with internal stiffeners and are spaced 120 ° apart. 3. The rotor according to claim 1, characterized in that the blades are made with an elongation coefficient of λ = 8 and an angle of attack of 15 °.

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