RU104252U1 - WIND POWER PLANT - Google Patents

Abstract

 1. A wind power installation containing two wind turbines with radial blades mounted on two coaxial horizontal shafts with the possibility of rotation in opposite directions, an electric current generator, the stator of which is kinematically connected to one of the wheels, and the rotor to the other, a movable guide casing enveloping the blades a wind wheel with the possibility of rotation around the wind turbine and fixing the position, wind traps, means of fastening the blades, characterized in that the blades of one wheel have an angle of attack, etc. opposite to the angle of attack of the other wheel, and installed with the possibility of changing the angle of attack, the stator and rotor of the generator are made in the form of cylinders concentrically fastened with flat bases, and the rotor cylinders are located in the annular gaps between the stator cylinders equidistantly last, and the installation is additionally equipped with a weather vane with primary direction sensors the wind. ! 2. The wind power installation according to claim 1, characterized in that the guide casing is made in the form of two pairs of hollow disks of an aerodynamic shape mounted coaxially on the wind wheels, one of which is placed inside the other with the possibility of extension to overlap and remove part of the blades or the entire wind wheel from under the wind. ! 3. The wind power installation according to claim 1, characterized in that the blades are made curved, and wind traps are made in the form of concave-spherical in cross section of the terminal sections on the blades, occupying 60 ... 70% of the length of the blade. ! 4. Wind power installation according to claim 1, characterized in that the means for attaching the blades are supplemented by

Description

The invention relates to wind energy and can be used to generate electricity using wind energy under normal weather conditions and in hurricane winds.

Known wind turbine with gravitational stabilization of rotor rotation (Application for invention of the Russian Federation No. 2004132368, class F03D 1/00, 2006), containing a drum-type wind turbine with a horizontal axis of rotation, in which the blade blades are designed so that the wind acts only on the blades passing the upper position, and the blades passing the lower position are folded into an accordion.

The disadvantage of this technical solution is the inability to use a wind turbine in hurricane winds.

Known wind power installation (Application for invention of the Russian Federation No. 93041300, class F03D 1/00, F03D 1/02, F03D 7/02, 1993), containing one or more wind wheels with radial blades mounted on a central horizontal axis with the possibility of rotation in opposite directions , electric generator, confuser case (wind trap).

The disadvantage of this technical solution is the inability to use the installation in difficult climatic conditions in hurricane winds.

Also known is a wind power installation (VEU), containing two wind motors with radial blades mounted on two coaxial horizontal shafts with the possibility of rotation in opposite directions, an electric current generator and wind traps, equipped with an additional intermediate shaft, at one end of which a generator stator is fixed, at the other end a gear wheel of a gear system, wind motors are installed in pits, and their horizontal shafts are located at ground level, each trap contains an upper fixed guide with a concave outer surface located above the wind turbines, a lower movable guide, the envelope of the wind turbine drum blades with the possibility of rotation around the wind turbine and fix the position of the lap relative to the upper guide, movable rotary visors located at the foundation surface directing the air flow to the wind turbine blades (RU patent No. 2315891, IPC F03D3 / 02, published: 01.27.2008)

The disadvantage of this technical solution is the inability to use the installation in other wind directions, the insufficient efficiency of electricity generation. Another disadvantage is the presence of a mechanical gearbox that provides the opposite rotation of the second wind wheel, which complicates the design of the wind turbine.

The problem solved by the utility model is to provide the possibility of using the installation in difficult climatic conditions with different directions and wind power with high efficiency of electricity generation.

The task is achieved in that the wind power installation containing two wind motors with radial blades mounted on two coaxial horizontal shafts with the possibility of rotation in opposite directions, an electric current generator, the stator of which is kinematically connected to one of the wheels, and the rotor to the other, a movable guide a casing enveloping the blades of a wind wheel with the possibility of rotation around the wind turbine and fixing the position, wind traps, means of fastening the blades, according to the utility model and, the blades of one wheel have an angle of attack opposite to the angle of attack of the other wheels and are mounted with the possibility of changing the angle of attack, the stator and rotor of the generator are made in the form of cylinders concentrically fastened with flat bases, and the rotor cylinders are located in the annular gaps between the stator cylinders equidistantly last, and the unit is additionally equipped with a weather vane with sensors of the preferential direction of the wind.

The guide casing, as an option, can be made in the form of two pairs of hollow disks of an aerodynamic shape mounted coaxially on the wind wheels, one of which is placed inside the other with the possibility of extension to overlap and remove part of the blades or the entire wind wheel from the wind

Alternatively, the blades are made curved and equipped with wind traps in the form of concave-spherical in cross section of the terminal sections on the blades, occupying 60 ... 70% of the length of the blades.

The means of fastening the blades, as an option, are supplemented by rings located around the periphery of the windwheel, which are reinforced by extensions.

The stator, as an option, is made stationary.

The installation of wind motors on two coaxial horizontal shafts with the possibility of rotation in opposite directions, the kinematic connection of the stator with one of the wheels, and the rotor with the other, the installation of blades with the ability to change the angle of attack, the stator and rotor of the generator in the form of cylinders concentrically fastened with flat bases, moreover, the rotor cylinders are located in the annular gaps between the stator cylinders equidistantly last, provide increased efficiency and synchronization of the opposite rotation of the wind wheels for Thu angular velocity addition effect of the opposite rotation of the rotor and stator of the generator and the kinetic energy of the mass.

The presence of the guide casing, made in the form of two pairs of hollow disks of an aerodynamic shape, mounted coaxially on the wind wheels, one of which is placed inside the other with the possibility of extension to overlap and withdraw part of the blades or the entire wind wheel from under the wind.

The supply of wind turbines with a weather vane with sensors of the preferential direction of the wind allows you to capture the preferential directions of the wind.

The execution of the blades curvilinear and supplying them with wind traps in the form of concave-spherical in the cross section of the end sections on the blades, occupying 60 ... 70% of the length of the blades, contributes to the capture and reflection of the air flow in a non-concave portion of the blade. Without stopping the total inert mass of the air flows passing through the blades, this design responds to the slightest air flow, does not change the direction of subsequent air flows, even with low activity.

The outer ring fixes the blades in the working position and ensures the constant aerodynamics of the wind wheels.

The proposed set of features as a whole provides the possibility of using the installation in difficult climatic conditions with different directions and wind strength with high efficiency of electricity generation.

The utility model is illustrated by drawings: where in Fig.1 shows a wind turbine with two wind wheels; figure 2 is a variant with hollow discs; figure 3 - with wind traps; figure 4 - with rings that are reinforced by extensions.

The wind power installation (see figure 1) contains wind motors in the form of wind wheels 1 and 2 with radial blades 3 mounted on two coaxial horizontal shafts 4, 5 with the possibility of rotation in opposite directions. An electric current generator 6, the stator 7 of which is kinematically connected with the wheel 1, and the rotor 8 - with the wheel 2, a movable guide casing 9, enveloping the blades 3 of the wind turbines with the possibility of rotation around the wind turbine and fixing the position. In this case, the blades 3 of the wheel 1 have an angle of attack equal to and opposite to the angle of attack of the other wheel 2, the stator 7 and the rotor 8 of the generator 6 are made in the form of cylinders 10 concentrically fastened with flat bases 11, and the cylinders 10 of the rotor 8 are located in the annular gaps between the cylinders 10 of the stator 7 equidistant last. The wind turbine is additionally equipped with a weather vane 12 with sensors of the preferential direction of the wind and mounted coaxially, and the guide casing 9 is mounted on top of the wind wheel 1.2.

Wind turbine operates as follows (figure 1).

A weather vane 12 with sensors automatically sets wheels 1 and 2 to the preferred direction of the wind perpendicular to their end and the area swept away by the blades 3. The blades 3 of the wheel 1 have an angle of attack equal to and opposite to the angle of attack of the other wheel 2. Both wheels 1, 2 begin to rotate in opposite directions together with their shafts 4, 5. In this case, the wheel 2 rotates both from the incoming flow and from the wheel’s tangled stream 1, amplifying the wind turbine torque. In this case, the angle of attack of the blades is set, for example, by a separate step micromotor according to the signal from the sensors.

The electric current generator 6, the stator 7 of which is kinematically connected with the wheel 1, and the rotor 8 - with the wheel 2, also rotate in opposite directions. Moreover, due to the addition of the angular velocities of the opposite rotation of the rotor 8 and the stator 7, the electric windings of the rotor 8 intersect the magnetic field stator 7 with a higher frequency, which increases the emf and the amount of electricity generated. In addition, in light winds, due to reduction with increasing rotation of the wind turbine generator, it allows to stabilize electricity by current and voltage and generate the so-called clean electricity with higher parameters, as well as use a less high-speed wind wheel.

The wind turbines are driven out of the gale at maximum loads due to the automatic rotation of the blades 3 into the vane position by electric drives, for example, individual stepper micromotors according to a signal from sensors (not shown).

At rated winds, blades 3 are also automatically set to the optimum angle of attack.

An embodiment of the guide casing in the form of two pairs of hollow disks 13, 14 (see Fig. 2) of aerodynamic shape coaxially mounted on wind wheels, one 13 of which is placed inside the other 14 with the possibility of extension is designed to block or remove the wind wheel from the wind. The disk 13 is rotated by a predetermined angle, it extends from the disk 14 and overlaps the blades 3.

The casing 9 protects against atmospheric precipitation, closes the upper part from air currents, directing air down to the open part of the blades 3, forcing them to rotate. This design allows you to increase the volume of the blades, using weak air currents due to the sailing form, relative to the characteristics of the total power of the air flow in the area.

Using a pair of hollow disks 13, 14 of the casing, it is possible to regulate the air flows on two wheels 1 and 2 in different volumes by unequal overlapping of the blades 3, which will allow the wind turbine to unfold without an electric drive in the desired direction, that is, perpendicular to the air flows.

The load on the bearings is distributed evenly, due to the perpendicular arrangement of the engine relative to air flows and the same area of the blades.

The implementation of wind traps (see figure 3) on curved blades 3 in the form of concave-spherical in cross section occupying 60 ... 70% of the length of sections 15 on the blades 3, works as follows. Weak winds with a flow velocity of 4 ... 4.5 m / s are well caught by the concave-spherical sections 15, and then are discarded onto the section of the blade 3 and then other blades 3 of the wind wheel, increasing the wind turbine torque.

The generator with a fixed stator 7 has two rotors 8 included in the stator 7 from two ends. The work is carried out with the rotation of the rotors 8.

Wind turbines designed for unstable air flows use a wide activity diagram. The generator 6 has two rotating rotors 8 and two stator 7 of opposite rotation, extinguishing the centrifugal effect by synchronous rotation, automatically controlled by the blades of both wheels 1 and 2, followed by the intersection of electromagnetic induction in tiers, thereby increasing the frequency of intersection. The generator 6 is located on the same axis with the air flow.

The blades 3 can be connected by rings 16 (see figure 4), which fix the position of the blades 3 around the circumference of the wind wheel, but does not prevent the angle of attack of the blades 3. The rings 16 are strengthened by braces 17 connected with the ends of the shaft 18 protruding beyond the plane of the wind wheels.

The rings 16 can be made in cross section as an aerodynamic wing mounted with an angle of attack to the oncoming flow.

Wind turbines, where the blades are connected by rings 16 due to the movable connection into a single unit, works as follows. The load on the rings 16 is taken by cable extensions 17 connected to the ends of the shaft 18 protruding beyond the plane of the wind wheels 1,2. Ring 16 in cross section has the shape of a wing with a design lifting force. When the wind load, the lifting force stretches the ring 16 in the diametrical direction, which is counteracted by the reactive forces of the stretch marks 17. The counteraction of the forces providing dynamic stiffness of the wind wheels 1, 2 and thereby stabilizes the operation of the wind turbine.

The rings 16 may be provided externally and / or internally with symmetrically located rotary radial blades 19, creating the opposite rotation. Using the effect of the opposing forces of the opposite rotation when exposed to air currents, this design allows you to dampen the axial vibrations of the blades inherent in known wind turbines, destroying expensive blades, reducing the resource of use of wind turbines. The angle of attack of the blades 19 and the blades 3 of the two wind wheels 1,2 is synchronously controlled by separate electric drives that direct air flows to the blades 19 of the second wind wheel at an angle, thereby compensating for the change in air flow, reducing the speed of the air flow to the second wind wheel. This wind turbine is more complicated, but more efficient in terms of power and payback, because can be used in various latitudes with small air flows.

When exposed to active air currents, master sensors with electric drive change the angle of attack of the blades 3 and blades 19 to reduce the load.

Industrial applicability is provided by modern technologies for the production of wind turbines.

Claims (5)

1. A wind power installation containing two wind turbines with radial blades mounted on two coaxial horizontal shafts with the possibility of rotation in opposite directions, an electric current generator, the stator of which is kinematically connected to one of the wheels, and the rotor to the other, a movable guide casing enveloping the blades a wind wheel with the possibility of rotation around the wind turbine and fixing the position, wind traps, means of fastening the blades, characterized in that the blades of one wheel have an angle of attack, etc. opposite to the angle of attack of the other wheel, and installed with the possibility of changing the angle of attack, the stator and rotor of the generator are made in the form of cylinders concentrically fastened with flat bases, and the rotor cylinders are located in the annular gaps between the stator cylinders equidistantly last, and the installation is additionally equipped with a weather vane with primary direction sensors the wind. 2. The wind power installation according to claim 1, characterized in that the guide casing is made in the form of two pairs of hollow disks of an aerodynamic shape mounted coaxially on the wind wheels, one of which is placed inside the other with the possibility of extension to overlap and remove part of the blades or the entire wind wheel from under the wind. 3. The wind power installation according to claim 1, characterized in that the blades are made curved, and wind traps are made in the form of concave-spherical in cross section of the terminal sections on the blades, occupying 60 ... 70% of the length of the blade. 4. The wind power installation according to claim 1, characterized in that the means for attaching the blades are supplemented by rings located on the periphery of the wind wheel, which are reinforced by braces associated with the ends of the shafts protruding beyond the plane of the wind wheel 5. Wind power installation according to claim 4, characterized in that the ring in cross section is made in the form of an aerodynamic wing mounted with an angle of attack to the oncoming flow.