EA023719B1 - Wind-driven plant for power generation and method for power generation using wind-driven plant - Google Patents

Abstract

The invention relates to power engineering, more definite to alternative power generation, using air for rotating an axial-type windwheel mounted in a wind-driven plant for power generation at different, even mostly unfaurable weather conditions (rain, hail, sleet, hurricane, calm). A proposed method of power production using renewable energy sources and a wind-driven plant therefor provide to increase power generation substantially by creating acceleration of air flow before the windwheel due to the use of aerodynamic effects.

Description

The invention relates to alternative energy, namely, environmentally friendly energy wind turbines using the energy of a moving air environment to produce electricity.

State of the art

A known design of a wind turbine that allows you to generate electricity using air currents presented in the patent I8 7214029, R03I 1/04, 2007 [1]. This design of the aerodynamic turbine [1] allows you to convert the kinetic energy of the wind into torque on the shaft of the electric generator with high efficiency due to the use of a multi-blade axial-type wind wheel with a horizontal axis of rotation mounted vertically behind a stationary guide vane. The air flow on the blades of the guide vane deviates to the optimum angle and flows around the blades of the multi-blade wind wheel with maximum efficiency, regardless of wind speed. An aerodynamic turbine is placed on the airship casing, which is lifted to a certain height, where the air masses move at higher speeds, act on the wind wheel and rotate it, generating electricity in a known manner. The airship body with a wind turbine must be oriented in the direction of the wind in order to provide axial flow around the aerodynamic turbine to organize the production of electricity. The generated electricity is transferred to the ground by electric cable and distributed to consumers.

The problem and the main disadvantage of the known wind turbine [1] is that at stormy wind speeds (more than 30 m / s) the design of the tethered airship can be destroyed or torn off the mounts, therefore, to prevent destruction, the airship is attracted by cables and attached to the ground, although it is known that when the wind speed increases, the generated electricity on a wind wheel increases significantly.

Another problem is that the presence of precipitation - rain, snow, hail and icing greatly complicates or makes impossible the operation of such a wind power installation.

If the wind turbine [1] is not oriented in the direction of the wind, i.e. the wind will act on the wind turbine from the back or from the side, and also in the absence of wind, the production of electricity will be impossible.

Known wind power installation pressure and exhaust action with a system of local forcing wind speed according to the patent KI 2101556, R03I 3/04, 1995 [2], partially eliminating these disadvantages.

By appointment, by technical nature, by the presence of similar features, this technical solution is selected as the closest analogue.

In a wind power installation of pressure and exhaust action [2], an axial-type wind wheel with a horizontal axis of rotation is placed horizontally inside the flow part of the exhaust pipe body. A wind wheel connected to the shaft by a generator during its rotation generates electricity. Airflow moves from the bottom of the chimney to the top. In the upper part of the wind turbine, air nozzles are installed in the form of a volumetric cylinder, where the pressure increases due to the increase in the volume of the nozzle design, and this leads to a directly proportional decrease in the air flow rate, according to Bernoulli's law (see p. 48 L. aerodynamics. Kokunin. Moscow: Transport. 1982 [3]), which adversely affects the performance of the wind wheel due to air flow inhibition. A sufficiently long flow part of the chimney, volumetric cylindrical nozzles, a large number of guide planes and movable shutters moving in the wind receiver create significant aerodynamic losses that slow down the movement of air, and this also reduces the speed of the air flow relative to the wind wheel and, accordingly, the generation of electric energy.

The wind wheel of the wind power installation [2] rotates at different angular speeds due to different wind speeds, which is accompanied by a change in the angle of approach of the air masses to the blades of the wind wheel, and this in turn causes unstable and ineffective work of the wind wheel to generate electricity, since the optimal angle of approach of air masses on the blades of a wind wheel is not supported and changes when air movement changes.

The external and internal movable curtains of the guiding planes of the wind receiver, which are placed around the perimeter in the lower part of the wind turbine [2], must be moved depending on the direction of the wind in order to ensure air flow into the exhaust pipe, and the air outlet must be regulated using the safety valves of the cylindrical nozzle.

A large number of moving parts necessary to orient the wind turbine [2] relative to the direction of the wind, reduces reliability and complicates operation, while increasing metal consumption and its cost.

Under adverse weather conditions (hail, snow), the cylindrical nozzles cannot perform the functions of air exhaust from the exhaust pipe due to the fact that snow masses accumulate on

- 1 023719 of its surface, they will block the air channels for venting air, and also make the design of the wind turbine [2] heavier, and in the absence of wind, electricity production ceases.

Disclosure of invention

The objectives of the proposed technical solutions are:

for the method, increasing the efficiency of the process of producing electric energy using a wind power installation, for the installation, simplifying the design, the optimal layout of parts and components of the installation, reducing the cost of its manufacture.

To solve these problems, it is necessary to create conditions for the accelerated movement of the air flow relative to the wind wheel, regardless of the direction of the wind, to organize a constant optimum angle of approach of the air masses to the blades of the wind wheel, to ensure reliable operation of the wind wheel in adverse weather conditions (rain, hail, snow, hurricane).

The technical results are ensuring the production of electricity at various wind speeds and directions, efficient formation of a working air flow, both due to the constructive implementation of nodes and parts, and through the use of aerodynamic and physical effects to change the characteristics of the air flow at the inlet and outlet of the installation with optimization and maximum possible use of energy coming to the installation of the air flow. In addition, it protects the entire internal arrangement of the installation with a fixed guide apparatus, a rotating wind wheel and the electric control part from the effects of the external environment (precipitation in the form of rain, wet snow, hail, various objects moved by air currents), which ensures an increase in both consumer qualities , and increase the overall technical resource of the operation of the installation.

Technical results are achieved by the fact that in a method of generating electricity using a wind power installation, including the interaction of the air with a multi-blade axial-type wind turbine mounted horizontally on a vertical shaft, with changing air flow characteristics, change the characteristics of the air flow entering the wind power installation and change the characteristics the air flow leaving the wind power installation, while forming the incoming air the current to the multi-blade wind wheel by changing the speed and direction of the flow by tapering the inlet air ducts and forming the air flow incident on the wind wheel in the guiding device with optimal aerodynamic characteristics due to the direction of the flow at the optimal angle on the wind wheel blades, create a vacuum in the upper part of the wind power plant above the wind wheel due to the Magnus effect during rotation of the spherical fairing of the wind wheel and due to the flow around the air sweat an eye of a disk-shaped fairing mounted above the wind wheel at the exit of the wind power installation with a gap and with the possibility of vertical movement.

At the same time, the speed of the air flow directed to the wind wheel is increased by reducing the cross section of the open channels formed by the outer surface of the wind power plant tapering to the top of the body and the vertical ribs made on the external surface of the body to form an air flow running on the wind wheel with optimal aerodynamic characteristics fixed vanes of a guide vane installed in the inlet flow part in front of the movable vanes nogolopastnogo propeller, increasing the speed of the air flow directed towards the wind wheel by performing the airfoil inlet flow and the annular part of the fairing, which is mounted inside the stationary guide vanes and rotating wind wheel. In addition, elements for converting solar radiation into electricity and storing it in an electric battery of the wind energy installation can be fixed on the outer surface of the wind power installation.

Technical results are also achieved by the fact that in a wind power installation for the production of electricity, including a symmetrical housing made with a variable cross section, inside of which there is a vertical shaft on which a multi-blade axial-type wind wheel is horizontally mounted and the generator rotor is fixed, a wind receiver with guide vanes, made in the lower parts of the body, devices for changing the characteristics of the air flow, installed above and below the multi-blade wind wheel, working on a cage installed at the outlet of the wind power installation, the wind receiver is made in the lower part of the casing in the form of channels formed by the outer surface of the tapering towards the top of the wind power installation and vertical ribs made on the outer surface of the casing and in the form of an annular fairing made with the aerodynamic profile of the inlet and flow parts , inside which a wind wheel is installed, devices for changing the characteristics of the air flow are made in the form of a fixed guide ap arata equipped with blades mounted in the inlet flow part in front of the wind wheel, in the form of a spherical cowl, which is equipped with a wind wheel and in the form of a disk-shaped cowl mounted above the wind wheel at the outlet of the wind power plant with a gap of 2,023,719 rum and with the possibility of vertical movement, with a disk-shaped fairing made with a diameter exceeding the diameter of the wind wheel.

To exclude the system for orienting the wind turbine towards the wind, changes in the speed and direction of flow, the inlet air channels are made tapering and are formed by the outer surface of the wind turbine tapering to the top of the casing and vertical ribs made on the outer surface around the perimeter of the casing. The body of the wind turbine is made with decreasing in height circular section - tapering from bottom to top. The ribs are diametrically mounted, mounted vertically, made with streamlined surfaces.

An axial-type multi-blade wind wheel with a horizontal axis of rotation is installed horizontally in a wind power installation. To form the incoming air flow, a guiding apparatus is fixed in front of the wind wheel, made in the form of a fixed multi-blade wheel, the blades of which create an optimal and constant angle to the air flow in front of the blades of a rotating wind wheel.

The guide blades and the blades of the wind wheel have an aerodynamic profile with a geometric and aerodynamic twist in their cross section, which allows you to evenly and optimally distribute the aerodynamic forces along the entire length of the blades, to create the maximum possible aerodynamic forces directed towards the rotation of the wind wheel when the air flow is acting on it. Guide vanes and wind wheel blades are mounted in close proximity to each other with minimal gaps in axial and radial directions, which allows to reduce aerodynamic losses during the movement of air masses.

A multi-blade wind wheel and a guiding device are installed inside the annular fairing to prevent adverse effects of external atmospheric conditions and side wind. The inner surface of the annular fairing is made in the form of a tapering cone in order to accelerate the air masses coming to the blades of the wind wheel. The annular fairing is made in the form of a wing profile, the outer surface of which provides acceleration of air masses, both in front of the guide apparatus and behind the wind wheel, regardless of the direction and strength of the wind.

When the wind wheel rotates on a rotating spherical fairing, a vacuum is created, in accordance with the Magnus effect. Thus, air particles carried away by a rotating spherical radome are accelerated, which, in accordance with Bernoulli’s law, leads to a pressure drop, i.e. to rarefaction in this area (see pp. 47-48 [3]) and, consequently, to an increase in the air flow rate behind the wind wheel.

In order to further increase the rarefaction behind the wind wheel and increase the speed of air mass movement in the upper part of the wind power installation above the wind wheel, a disk-shaped fairing is installed with a gap and with the possibility of vertical movement. The fairing is made in the form of a circular disk-shaped profile, creating a vacuum in any direction of movement of the air masses. The disk-shaped fairing, if necessary, stops the operation of the wind power installation, regardless of the strength and direction of the wind, by blocking the cross section of the exit of air masses from the plane of rotation of the wind wheel, by reducing its structural distance to the wind wheel. To protect the wind wheel from adverse weather conditions, the disk-shaped fairing is made with a diameter larger than the diameter of the multi-blade wind wheel, which prevents the penetration of rain in the form of rain, hail and wet snow into the plane of rotation of the wind wheel from above, providing favorable operating conditions for the wind power installation.

In order to produce electricity from renewable energy sources in the absence of wind, elements can be fixed on the outer surface of the wind power plant for converting solar radiation into electricity and storing it in the electric battery of the wind power plant.

In order to improve the environmental situation, reduce costs for the manufacture of individual components and structural elements of a wind power installation, solid plastic household and industrial wastes can be used.

Brief Description of the Drawings

The present invention is described in more detail by way of example and is accompanied by the corresponding drawings, in which:

FIG. 1 is a side elevational view of a Lego Ogei wind power plant in operating position (upper cowl in extreme upper position);

FIG. 2 is a cross-sectional side view of a wind power installation;

FIG. 3 is a schematic diagram of the placement of solar cells on the construction of a wind power installation;

FIG. 4 is a schematic diagram of the movement of air masses when the wind wheel is operating in a side view (upper fairing in its highest position);

FIG. 5 is a schematic diagram of the movement of air masses when the wind wheel is operating in a plan view (upper fairing in its highest position);

FIG. 6 is a schematic diagram of the movement of air masses with a non-working wind wheel in the form

- 3 023719 on the side (upper fairing in the lowest position);

FIG. 7 is a schematic diagram of the movement of air masses when the wind turbine is not working in a plan view (upper cowl in extreme low position);

FIG. 8 is a side elevational view of a wind turbine in a non-operational position (upper cowl in extreme low position).

The best embodiment of the invention

The wind power installation for the implementation of the proposed method consists of a housing 1, tapering from the bottom to the top, mounted on a shock-absorbing base 2. Side surfaces-ribs 3 are vertically fixed to the housing 1, which together with the narrowing housing 1 act as an open flow part for the incoming air flow . The lateral ribs 3 in the upper part of the housing 1 abut against a ring generator 4, on the posts 5 of which an upper disk-shaped fairing is fixed 6. On the inside of the annular fairing 4, a fixed guide apparatus 7 is fixedly fixed on the base 1, over which in the immediate vicinity there is a multi-axial 8-axle wind wheel type with a horizontal axis of rotation, connected to a generator 9, which is electrically connected to the battery 10. A spherical radome 11 is mounted on the wind wheel 8, which rotates together It is natural with a wind wheel 8.

According to the claimed method, a wind power installation operates as follows. In the presence of wind, regardless of its direction, the air masses move along the tapering base 1 along the vertical ribs 3 up to the stationary blades 7 of the guide apparatus. On the blades of the guide vane 7, the air flow acquires an optimal angle and at this angle passes through the blades of the multi-blade wind wheel 8, creating aerodynamic forces directed towards the rotation of the wind wheel 8, similarly to the aerodynamic forces of the turbine of the jet engine, when the air-gas flow passes through the axial turbine type with a horizontal axis of rotation (see p. 17 Theory and design of aircraft blade machines. KV Kholshchevnikov. Moscow, Mechanical Engineering: 1970 [4]). The wind wheel 8 is fixed with a generator 9, which during its rotation generates electricity, accumulating it in the battery 10 for transmission to consumers. When the wind acts on the outer surface of the annular fairing 4, the air flow rushes both on the stationary blades of the guide apparatus 7 and in the rarefaction region formed by the Magnus effect when the spherical fairing 11 of the wind wheel 8 rotates (Fig. 4). Having passed the plane of the wind wheel 8, the air masses rush to the area of low pressure, which is formed on the upper disk-shaped fairing 6 when exposed to wind, in accordance with the theory of N.E. Zhukovsky (see p. 48-49 [3]).

The outer surfaces of the upper disk-shaped fairing 6, the annular fairing 4, the side ribs 3, the housing 1 are covered with sun-absorbing elements, which make it possible to provide electric power additionally from solar radiation regardless of wind speed or in its complete absence (Fig. 3).

In the presence of precipitation in the form of rain, hail and wet snow, the dimensions of the upper fairing 6 and its disk-shaped form, the presence of an annular fairing 4 with a convex outer surface, the organization of the movement of air masses from the lower part of the housing 1 upward, provide protection and efficient operation of the wind power installation.

In case of emergency and emergency, the operation of the wind power installation can be quickly stopped by blocking the air mass outlet by the fairing 6, by reducing the length of the racks 5 (Fig. 6-8). In this case, the wind power installation is reliably protected from adverse external environmental influences with the possibility of further electricity production in the presence of solar radiation.

Industrial applicability

The application of the proposed method and the wind power installation for its implementation can efficiently generate electricity even in the most adverse weather conditions using renewable energy sources.

Technical results include a significant increase in the reliability of the wind turbine and an increase in the utilization of wind energy.

This invention can be used to solve a wide range of problems both in industry and in energy.

The conducted experimental tests of the proposed installation confirmed the high efficiency of this development.

The use of a wind power installation can significantly improve and expand the existing energy system of power generating enterprises, significantly reduce dependence on hydrocarbon fuels and improve the environmental situation in the world.

Claims (7)

1. Wind power installation for the production of electricity, including a symmetrical housing made with a variable cross-section, inside which a vertical shaft is mounted, on which a multi-blade axial-type windwheel is horizontally mounted and the generator rotor is fixed, a wind receiver with guide vanes, made in the lower part of the housing, devices for changing air flow characteristics, installed above and below the multi-blade wind wheel, a working nozzle installed at the outlet of the wind power installation, characterized in that the wind receiver is made in the lower part of the casing in the form of channels formed by the outer surface of the tapering upward casing of the wind power installation and vertical ribs made on the outer surface of the casing, and in the form of an annular fairing made with the aerodynamic profile of the inlet and flow parts, inside of which a wind wheel is installed, devices for changing the characteristics of the air flow are made in the form of a fixed guide apparatus equipped with blades Mounted in the inlet flow part before the wind wheel in the form of a spherical fairing, which is provided with a wind wheel and a disk-like radome installed over the wind wheel at the output of a wind power installation with play and with the possibility of vertical movement, wherein the disk-like radome configured diameter greater than the rotor diameter. 2. Wind power installation according to claim 1, characterized in that the blades of the guide apparatus and the blades of the wind wheel are made in cross section with an aerodynamic profile with a geometric and aerodynamic twist. 3. The wind power installation according to claim 1, characterized in that the wind wheel and the guide apparatus are installed in the flow part of the ring generator with minimal gaps in the axial and radial directions. 4. Wind power installation according to claim 1, characterized in that on the outer surface of the wind power installation there are fixed elements for converting solar radiation into electricity and storing it in an electric battery of the wind power installation. 5. Wind power installation according to claim 1, characterized in that its individual components and structural elements are made of solid plastic household and industrial waste. 6. The method of producing electricity using the wind power installation according to claim 1, characterized in that the change in the characteristics of the air flow passing through the wind power installation is controlled by reducing the cross section of the open channels, changing the speed of rotation of the spherical fairing. 7. The method of producing electricity according to claim 6, characterized in that the elements for converting solar radiation into electricity and storing it in an electric battery of the wind energy installation are fixed on the outer surface of the wind power installation.