RU2214492C2 - Building of wind-solar power station - Google Patents

Abstract

FIELD: construction engineering, particularly, shelters of wind and air current concentrator of wind-solar power stations. SUBSTANCE: building has solar-absorbing surface covered by translucent material and connected by means of air duct with exhaust tube whose mouth accommodates wind turbine. Solar-absorbing surfaces form sections in form of beams diverging from building center to its periphery. Located between said beam ends and exhaust tube are wind-guiding sections covered also with translucent heat insulating material. Solar-converting and wind-guiding sections accommodate air intake devices and mounted solar energy accumulators. Mounted in wind-guiding sections under wind generator are curved wind-guiding surfaces. Building is additionally provided with greenhouse ponds connected with one another. EFFECT: increased complex utilization of solar heat energy and ground surface air currents. 16 cl, 5 dwg

Description

 The invention relates to the field of construction and energy and is intended for use as a shelter-concentrator of wind and air flows of a wind power station.

 Known tent shelter containing two or three collapsible frames interconnected by hinges, side struts, struts between the pillars of the frames and rods with hinges at the ends. The frames are formed by side posts connected by horizontal elements. The flexible roof and walls are made of lightweight moisture and windproof material (see Russian Patent 2029044, E 04 H 15/00, publ. 1995).

 A tent structure is also known, including a frame of elements pivotally mounted on supports, and an awning connected to the frame elements by means of tension ropes passed alternately through the rings and brackets of the tent and frame elements. The awning is attached to the anchors with additional tension anchor ropes passed through the awning rings and anchor eyes (see AS USSR 1645423, E 04 H 15/08, publ. 1991).

 Both of the described analogs do not take into account the features and technological requirements for buildings of shelter-concentrators of wind and air flows of a wind and solar power station.

 Another well-known building of a power plant contains an exhaust high-rise building, in the lower part of which an air turbine kinematically connected with an electric generator is mounted on radial pipes. The building includes a furnace with an afterburner designed to increase the air flow acting on the turbine blades (see AS USSR 1828516, F 03 D 9/00, publ. 1993).

 The invention (see AS USSR 1471756, F 03 D 9/00, publ. 1994) describes the construction of a structure that provides the supply of warm air heated by the sun's rays to the wind turbine. This structure is made in the form of channels located on an inclined earth's surface, having a ribbed light-absorbing base, connected by means of a working duct-duct to a wind turbine. The channels with a ribbed base are covered with transparent material. The ribbed base of the channels contributes to increased flow turbulence and better absorption of solar energy.

 Both last analogs use the kinetic energy of heated air to operate an air turbine (in one case it is a high-rise building with a furnace and afterburner, in the other - channels with a ribbed light-absorbing base and ducts located on an inclined surface), but none of these analogues are not provided for systems and devices for accumulating thermal energy and its subsequent selection in the cold season, on cold days, months.

 The closest analogue accepted for the prototype of the proposed invention is the building of a tower-type solar power station, at the base of which there is a solar-absorbing surface covered with translucent material (see Energy-active buildings. / Ed. By E.V. Sarnatsky and N.P. Selivanov., M .: Stroyizdat, 1988, p. 235-237, Fig. 5-70). The air under the translucent material heated by solar heat is directed through the air ducts to the base of the solar power station, made in the form of a truncated cone, in the upper part of which an exhaust pipe is mounted with a wind turbine located in its mouth. A wind power station with its own rotor-converter of wind energy is mounted in the upper part of the chimney.

 The disadvantage of the described building is the use of various energy carriers for utilization of various energy carriers (a wind power station at the top of the exhaust pipe, an electric generator with a blade turbine at the mouth of the exhaust pipe, a steam turbine with its electric generator outside the base of the station. In addition, the building does not provide a system for the accumulation of solar heat and its selection in the cold season, days, years.

 The objective of the invention is to increase the integrated use of energy of solar heat and surface air currents, as well as creating a system of heat accumulators and its selection to generate energy in the cold season, on cold days and hours. The objective of the invention is the creation of conditions for the production of agricultural products, including fish farming and industrial-scale breeding of other products of pond farming, in the areas occupied by the building of a wind and solar power station.

 This goal is achieved by the fact that the building of the wind power station contains a helioplastic surface covered by translucent material, connected by an air duct to an exhaust pipe, in the mouth of which a wind turbine is mounted. Helium-absorbing surfaces form sections made in the form of rays diverging from the center of the building to the periphery, between the ends of which and the exhaust pipe there are wind-guiding sections, which are also covered by a translucent heat-insulating material. In the solar converting and wind-guiding sections air intake devices are placed and solar energy accumulators are mounted. Helium-converting sections are separated from the wind-guiding sections articulated along the upper edge of the longitudinal vertical and inclined walls from translucent heat-insulating material. In the wind guide sections at the mouth of the chimney under the wind generator, curved wind guide surfaces are mounted. The roof of the helium-converting sections is made with a ridge inclined from the exhaust pipe to the periphery, and curved guide walls are attached to the roof in the adjoining zone to the exhaust pipe. The roof ridge of the helioconversion sections is made of composite materials.

 The building is additionally equipped with greenhouse ponds, some of which are located between the longitudinal and inclined walls separating the helium converting and wind-guiding sections, while the others are located under curved wind-guiding surfaces mounted at the mouth of the chimney, and the ponds are connected to other channels. The building is equipped with a management center. Solar energy batteries are made in the form of helioplastic panels or blinds of a dark color, equipped with a drive for adjusting their position, connected to a control center. Helium-absorbing panels can be made of flexible metal foil, one of the ends of which is mounted on a winding drum-drive equipped with an electric drive. The blinds can be made automatically adjustable of various lengths and combined into groups located at different spatial angles relative to each other with respect to the azimuthal direction to the south. The overlap of the wind-guiding sections is made in the form of helium-converting sections fixed on the roof ridge and resting on intermediate supports of the bearing ropes, on which a translucent heat-insulating coating is mounted. The translucent heat-insulating coating of the wind-guiding sections can be made in the form of autonomous sections docked with each other in the working position and fixed to the bearing ropes by means of sliding joints, each of which is connected to a drive connected to a control center. Air intake devices contain water-air heat exchangers. In the wind-collecting sections, auxiliary open water bodies are additionally mounted. In the central part of the building there are open air intake openings, from which underground air channels depart, equipped with water-air heat exchangers and connected to the internal cavities of the air intake devices of the solar converting sections. A water-air heat exchanger can be made in the form of a water intake basin and an inlet water line located above it, the beginning of which is connected to an auxiliary open water reservoir at a depth below the level of its probable ice cover, and the end is placed in the underground air channel and is provided with openings in its lower part for free fall of water jets over the entire horizontal cross section of the air channel. The underground air channel can be located near the greenhouse pond and is equipped with an additional water-air heat exchanger, the inlet and outlet water lines of which are connected to the greenhouse pond, and the heat exchanger is located in front of the exit of the underground air channel. An underground air channel can be located under the bottoms of greenhouse ponds and an auxiliary open reservoir. Each of the exits of the underground air channel is connected to the internal cavity of one or more air intake devices of the helioconversion sections.

 A comparative analysis of the claimed building with the prototype shows that it differs in that the solar-absorbing surfaces form sections, which are made in the form of rays diverging from the center of the building to the periphery, between the ends of which and the exhaust pipe there are wind-guiding sections, which are also covered by a translucent heat-insulating material. In the solar converting and wind-guiding sections air intake devices are placed and solar energy accumulators are mounted. Helium-converting sections are separated from the wind-guiding sections articulated along the upper edge of the longitudinal vertical and inclined walls from translucent heat-insulating material. In the wind guide sections at the mouth of the exhaust pipe under the wind turbine, curved wind guide surfaces are mounted. The roof of the helium-converting sections is made with a ridge inclined from the exhaust pipe to the periphery, and curved guide walls are attached to the roof in the adjoining zone to the exhaust pipe. The building is additionally equipped with greenhouse ponds, some of which are located between longitudinal vertical and inclined walls separating the helium-converting and wind-guiding sections, while others are located under curved wind-guiding surfaces mounted at the mouth of the chimney, and the ponds are connected by channels. The building is equipped with a management center. Solar energy batteries are made in the form of helioplastic panels or blinds of a dark color, equipped with a drive for adjusting their position, connected to a control center. Helium-absorbing panels can be made of flexible metal foil, one of the ends of which is mounted on a winding drum-drive equipped with an electric drive. The blinds can be made automatically adjustable of various lengths and combined into groups located at different spatial angles relative to each other with respect to the azimuthal direction to the south. The roof ridge of the helioconversion sections is made of composite materials. The overlap of the wind-guiding sections is made in the form of helium-converting sections fixed on the roof ridge and resting on intermediate supports of the bearing ropes, on which a translucent heat-insulating coating is mounted. The translucent heat-insulating coating of the wind-guiding sections can be made in the form of autonomous sections joined to each other in the working position and fixed to the bearing ropes by means of sliding joints, each of which is connected to a drive connected to a control center. Air intake devices contain water-air heat exchangers. In the wind-collecting sections, auxiliary open water bodies are additionally mounted. In the central part of the building there are open air intake openings, from which underground air channels depart, equipped with water-air heat exchangers and connected to the internal cavities of the air intake devices of the solar converting sections. A water-air heat exchanger can be made in the form of a water intake basin and an inlet water line located above it, the beginning of which is connected to an auxiliary open water reservoir at a depth below the level of its probable ice cover, and the end is placed in the underground air channel and is provided with openings in its lower part for free fall of water jets over the entire horizontal cross section of the air channel. The underground air channel can be located next to the greenhouse pond and is equipped with an additional water-air heat exchanger, the inlet and outlet water lines of which are connected to the greenhouse pond, and the heat exchanger is located in front of the exit of the underground air channel. The underground air channel can be located under the bottoms of the greenhouse ponds and auxiliary open reservoir. Each of the exits of the underground air channel is connected to the internal cavity of one or more air intake devices of the helioconversion sections.

 This analysis allows us to conclude that there is novelty in the claimed device.

 Comparison of the proposed building of a wind and solar power station with other well-known technical solutions of the same purpose shows that it is carried out in plan from alternating wind guiding and solar converting sections covered with translucent heat-insulating material, supplying sections with solar energy batteries, the design and method of installing such batteries, the arrangement of greenhouse ponds in limited heat-insulating translucent walls of the building sections, as well as additional device open x auxiliary reservoirs in the wind-guiding sections, the arrangement of underground air channels with water-air heat exchangers and their constructive implementation and connection with thermal ponds, as well as the constructive solution of blocking the wind-guiding sections, can increase the integrated use of solar heat and surface air flows, as well as create battery systems heat and its selection for energy production in the cold season, on cold days and hours. In addition, conditions are also being created for the production of agricultural products, including fish farming and the industrial scale cultivation of other pond products, in the areas occupied by the building of a wind and solar power station. Two energy flows are connected constructively and technologically in the building: concentrated natural wind and heated air in a closed helioconversion space, while the energy of natural wind after compaction in the space of the wind guide section is not only summed up with the energy of the heated air stream from the closed space of the helioconversion section, but it significantly accelerates movement of heated air, which in turn enhances traction in the exhaust pipe.

 The use of thermal energy of non-freezing water volumes located in the wind-guiding sections of open reservoirs is an effective means of increasing the generation of electricity in the northern regions (water of northern rivers, seas and lakes can be used for these purposes). The depth of such ponds should be 10-20 m. The freezing of the surface of ponds in the wind-guiding sections of the building is associated with a large heat release of the phase transition of water into ice. These large heat releases are utilized, increasing traction in the exhaust pipe. These reservoirs, if filled with sea water, can be used in winter to produce marketable ice and extract many valuable products from the remaining brine.

 Thus, the proposed building wind turbine installation exceeds the prior art and allows us to solve the problem posed by the invention.

 In addition to these positive effects, the proposed technical solution creates the conditions for improving the human environment by eliminating air pollution from fuel combustion products. The cost of production of environmentally friendly food products produced on the technological areas of the building is reduced: on vegetable plantations, orchards and agricultural industries, as well as ponds and open reservoirs located under the translucent heat-insulating coating of the station building.

The invention is illustrated by the example of its implementation. The drawings show:
- figure 1 - the building of a wind power station in the plan;
- figure 2 is a diagram of the formation of air and wind flows;
- figure 3 is a fragment of the wind-guiding section of the building;
- figure 4 is a diagram of an underground air channel;
- figure 5 - water-air heat exchanger.

 In plan, the building of a wind and solar power station is made in the form of beams, which are helium-converting sections 1 and containing helium-converting surfaces (not shown), diverging from the center of the building to the periphery. Between the beams there are wind-guiding sections 2. In the embodiment shown in the drawings, the building has four helium-converting sections, but their number can be large: a building with five to six helium-transforming sections is more efficient 1. The ends of the heli-transforming sections are limited by translucent heat-insulating walls 3. The roof is 4 of helioconverting sections made with a large slope relative to the vertical longitudinal walls 5. And the roof 4, and the walls 5 are also formed of translucent heat-insulating material. The roofs 4 of each section are made inclined from the exhaust pipe to the periphery of a translucent heat-insulating material. The ridge 6 of the roofs 4 is made of composite materials. The implementation of heliotransforming sections 1 elongated in height, comparable with their width, is necessary for self-collapse of snow from the roof and for the development of the volume of the wind-guiding space of adjacent sections. In the center of the building, the skates 6 of the roof 4 are adjacent to the neck of the exhaust pipe 7, which serves as the installation site for the wind turbine 8 with a vertical shaft, in front of which the inlet cavity 9 is located. The neck is adjoined by the overlap 10 of the wind-guiding sections 2. The overlap 10 is mounted by means of load-bearing ropes 11 stretched between skates of 6 adjacent helium converting sections, and are additionally held by intermediate supports 12. Overlappings 10 are formed from separate sections 13 made of translucent heat-insulating material, jointly interconnected by the sides and installed with the possibility of movement along the ropes 11 under the influence of the drives 14 connected to the computer center (not shown) of the building. Drives 14 are used to form temporary openings in the ceilings to shake down the accumulated snow during the snowfall. Adjacent to the input cavity 9, the portion of the wind-guiding sections 2 is closed by the wind-guiding surfaces 15, also formed of a translucent heat-insulating material. Since the wind-guiding surfaces 15 are heavily loaded by the concentrated wind flow, they have a strong supporting frame and are equipped on the inside with a mesh of nylon or glass filaments (not shown in the drawings).

 The vertical longitudinal walls 5 of the heliotransforming sections 1 are covered from the side of the wind-guiding sections 2 with additional walls 16 installed with the same slope as the roof 4, and made of translucent heat-insulating material. In order to give the wind flow oriented upward (towards the entrance cavity 9) to give a smooth rotation to the center, curved guide walls 17 are installed on the roofs 4.

 Under the wind-guiding surfaces 15 and additional walls 16 there are greenhouse ponds 18 and 19, forming 1 single U-shaped greenhouse pond between each pair of adjacent helium converting sections. These greenhouse ponds in the building are interconnected by channels 20 originating from air intake devices 21 located at the corners of the joints of the vertical longitudinal walls 5 and end walls 3. The space between the longitudinal walls 5 and the inclined surfaces 16 is common for helium-converting sections 1 and wind-guiding sections 2 .

 The wind guide sections 2 contain, in addition to the greenhouse ponds 19, auxiliary open water bodies 22. In the central part of the building are open air intake openings 23, from which underground air channels 24, arranged with water-air heat exchangers 25 and 26, located along the air flow path next to water volumes of hothouse 18, 19 and open 22 reservoirs to outlet openings 27 connected to internal cavities of air intake devices 21. Auxiliary open reservoir 22 is connected by thermal contact through the root The draw water line 28 with a moving air stream in the underground air channel 24 by means of jets and splashes of water 29 freely falling into the water intake pool 30, limited by the housing 31 of the air channel 24, and adjoins the wall, behind which there is a part of the volume of water of the auxiliary open reservoir 22. The discharge water line 32 is used to divert water from the intake basin 30 to the auxiliary open pond 22. Further heating of the air can be carried out in helioconversion sections 1, from where it enters the wind turbine inu 8, and through it into the exhaust pipe 33. For additional concentration of thermal energy in the helioconversion sections 1, vertically arranged helioplastic panels 34 are installed. Similar helioplastic panels are also installed in the wind guide sections 2 for preheating the wind flow, which is mixed with the heated air stream into the air outlet the pipe 33, increasing the force on the wind turbine 8.

 The air supply to the wind turbine 8 in the building is as follows. The sun's rays penetrate through a translucent heat-insulating material, from which the roof 4, vertical longitudinal walls 5 and end walls 3 of the helioconversion sections 1 are made, inside the helioconversion sections, where the solar radiation energy is converted into heat. This conversion takes place on helioconverting surfaces located inside sections 1. Air enters the helioconverting sections 1 through an open air inlet 23, is heated on an aqueous helioconversion surface of channel 20, on a soil surface with cultivated vegetation on it, located under a translucent heat-insulating material, as well as from technological equipment, which in its technological features is an additional heat generator emitting thermal energy, e if it is located in the helioconverting section, as well as on vertical helioplastic panels 34, made in the form of curtains or blinds, suspended at various levels from the roof 4 and walls 3 and 5 or advanced sectionally from below.

In addition, the sun's rays are converted into thermal energy on the components included in the wind guide sections 2:
- greenhouse ponds 18 and 19, for which the translucent heat-insulating roof is wind-guiding surfaces 15 and inclined surfaces 16 and which are interconnected by air cavities and in the aquatic environment with helioconversion sections 1 and with each other;
- auxiliary open reservoirs 22;
- helioplastic panels 34.

 Auxiliary open water reservoirs 22 serve as accumulators of thermal energy, which they accumulate in the summer and return to useful use due to the presence of heat-insulating ceilings 10 throughout the autumn-winter period, including when their surface freezes, because during the phase transition of water into ice, about 80 kcal of heat is released from each kilogram of water at a temperature of 0 degrees Celsius.

 The main solar thermal converter, especially in the northern regions in the colder half of the year, are the surfaces of vertical solar absorbent panels 34. During sunrise and sunset, the solar absorbent panels are lowered as much as possible (or extended as far as possible, depending on the design solution): they rise as the sun rises above the horizon, for example, by winding on horizontally located drums (not shown in the drawings). These drums can rotate around a vertical axis, tracking the position of the sun relative to the east-west direction. In the case of making solar-absorbing panels 34 in the form of blinds, the principle of their rotation relative to the east-west direction is maintained. In another case, they can be divided into groups, each of which is given a corresponding position relative to the east-west direction.

If the building has, as in the above example, four helium-converting sections 1 each 1000 m long and 100 m high, then about 400 thousand m ^{2 of} vertical helium-absorbing panels 34 can be placed in it. An even larger surface of them can be placed in the wind-guiding sections 2, when such panels are staggered throughout the volume of the section. Helium-absorbing panels 34 can be made in the form of narrow strips, which simplifies the movement of the wind flow. In the proposed version of the building, more than 50 thousand kW can be allocated to them in the year-averaged value.

 The wind entering the peripheral openings in the wind-guiding sections 2, is concentrated to the center along the surfaces of the walls 5 and the roofs 4 of the heliopads sections 1, increasing its volumetric power. At the same time, the wind-guiding surfaces 15 and the inclined surfaces 16 orient the lower layers of the wind flow when they move to the level of the input cavity 9 of the wind turbine 8, and in the case of lateral wind, the reflecting curved guide walls 17 along with the rise of the lower layers of the wind stream orient them in the direction of the wind turbine 8. the energy content of the wind flow at the entrance to the wind turbine increases 8 5-7 times compared with the state of the peripheral inlet opening of the wind-guiding sections 2. When passing through the wind turbines in 8, the wind flow, through an injection effect on the heated air stream in the helioplastic sections 1, produces a secondary, indirect effect on the wind turbine 8, which further increases the generation of electricity. In the proposed version of the building at a wind speed of 8 m / s, the energy component of the concentrated wind flow will exceed 50 thousand kW.

At the same time, under the influence of air intake devices 21, atmospheric air in the case of a negative temperature through the open air intake opening 23 of the underground air channel 24 is preheated to 0 degrees Celsius, passing through a water-air heat exchanger 25 and exposed to falling jets of water 29, which enters the water main 28 from non-freezing water volumes of auxiliary open reservoirs 22. By the time the water surface reaches the water intake basin 30, the falling water jets acquire t temperature 0 degrees Celsius and are located near the threshold of the phase transition to ice. This water from the intake basin 30 is immediately diverted to the auxiliary open pond 22, where the temperature is 4 degrees Celsius, and due to the convective process, the temperature of the wastewater is restored to 4 degrees Celsius. In order for the energy supply of auxiliary open water reservoir 22 to last for 6-7 months of continuous operation (in the cold season) with the transfer of thermal energy to the moving air stream in the amount of 100 thousand kW, the required volume of auxiliary open water reservoir 22 should be 5 million m ^{3 of} water . A significant reserve is the thermal energy of the earth, whose heat at the bottom of the reservoir 22 is transferred to its water. If the auxiliary open reservoir 22 is connected with a natural source of water with a temperature of 4 degrees Celsius by the water main 28, then the size of the reservoir can be relatively small, approximately 200-300 thousand m ^{3 of} water. At the same time, from a natural source of non-freezing water (sea or large river), a volume of water of about 30 cubic meters must flow every minute. m ³ .

 Then, the air flow heated to 0 degrees passes through the second heating stage: through the air-water heat exchanger 26, the difference of which from the first stage is that water enters it from the greenhouse pond 19. Its water temperature is about 20 degrees Celsius, and the air is heated due to the water of this pond to a temperature above 10 degrees Celsius. Hothouse ponds 19 play the role of heat accumulators and contain sections for heating water obtained by electric energy during the increase in the speed of natural wind to 10 m / s and above. Greenhouse ponds 19 may have special heating pools with periodic water exchange.

 Additionally heated to a temperature of 10-20 degrees Celsius in the air-water heat exchangers 26, the air flow through the underground channel enters the outlet openings 27, which are located in the peripheral zones of the heliotransformation sections 1 and connected to the internal cavity of the air intake devices 21. Each of these devices has its own executive an organ (not shown in the drawings) that draws in atmospheric air through an open air intake opening 23 of the underground air channel 24. This actuator can be made in as an electric air pump, however, a portioned air supply circuit with a frequency of about 1 Hz is more effective: for this, oscillatory systems with periodic opening and closing of the outlet openings 27 of the underground air channel 24 can be used. From the intake device 21, the air flow is heated to a temperature of 10-20 degrees Celsius for the most part directed through the air channel located above the greenhouse channel 20, and partially directed into the open space of the helioconversion sections 1, where additionally heats up in the process of moving to the inlet cavity 9 of the wind turbine 8. Most of the air flow passing through the air duct above the hothouse channel 20 is additionally heated and saturated with moisture in the jets of falling water, which previously passes under the helioplastic surface and is additionally heated (not shown in the drawings).

 Further, the air flow passes through the final heating stages in the helioconversion sections 1 and enters the wind turbine 8 and then into the exhaust pipe 33. Due to the temperature of the heated air and the speed of the concentrated wind flow, in interaction with the energy medium above the exhaust pipe 33, the draft in the exhaust pipe 33 increases creating additional energy potential for generating electricity. With a chimney height 33 of 500 m, this additional energy potential may exceed 150 thousand kW.

 The proposed building of a wind and solar power station, built in the northern regions of Russia, on the coast of the northern seas and lakes, in the Republic of Belarus, allows you to create powerful solar energy complexes of 20-50 or more thousand kW.

Claims (16)

 1. The building of a wind and solar power station, containing a solar-absorbing surface covered by a translucent material, connected by an air duct to an exhaust pipe, in the mouth of which a wind turbine is mounted, characterized in that the solar-absorbing surfaces form sections made in the form of rays diverging from the center of the building to the periphery, between the ends of which and the exhaust the wind-guiding sections are located in the pipe, which are also covered by a translucent heat-insulating material, moreover, in heli-transforming and wind-guiding ce The air intake devices and solar energy accumulators are mounted in the sections, while the solar converting sections are separated from the wind guide sections articulated along the upper edge of the longitudinal vertical and inclined walls from translucent heat-insulating material, and in the wind guide sections at the mouth of the exhaust pipe under the wind turbine, curved surfaces are mounted on the curved surface helium-converting sections made with a ridge inclined from the exhaust pipe to the periphery of the building, in the adjoining zone to the exhaust pipe has curved guide walls.  2. The building of a wind power station according to claim 1, characterized in that it is additionally equipped with greenhouse ponds, some of which are located between longitudinal vertical and inclined walls separating the solar converting and wind-guiding sections, and others under curved wind-guiding surfaces mounted at the mouth of the exhaust pipe moreover, the ponds are connected to each other by channels.  3. The building of a wind power station according to claim 1, characterized in that it is equipped with a control center.  4. The building of a wind power station according to claim 1 or 3, characterized in that the solar energy accumulators are made in the form of helioplastic panels or blinds of a dark color, equipped with a drive for adjusting their position, connected to a control center.  5. The building of a wind and solar power station according to claim 4, characterized in that the solar-absorbing panels are made of flexible metal foil, one of the ends of which is mounted on a winding drum-drive equipped with an electric drive.  6. The building of a wind power station according to claim 5, characterized in that the blinds are automatically adjustable of different lengths and are combined into groups located at different spatial angles relative to the azimuthal direction to the south.  7. The building of a wind power station according to claim 1, characterized in that the ridge of the roof of the solar conversion sections is made of composite materials.  8. The building of a wind power station according to claim 1, characterized in that the overlap of the wind-guiding sections is fixed on the upper part of the roof of the heliotransformation sections and rests on the intermediate supports of the bearing ropes.  9. The building of a wind and solar power station according to claim 3 or 8, characterized in that the translucent heat-insulating coating of the wind-guiding sections is made in the form of autonomous sections joined to each other in the working position and fixed to the bearing ropes by means of sliding joints, each of which is connected to the drive connected to the control center.  10. The building of a wind power station according to claim 1, characterized in that the air intake devices comprise water-air heat exchangers.  11. The building of a wind power station according to claim 1, characterized in that auxiliary open water bodies are additionally mounted in the air-intake sections.  12. The building of a wind and solar power station according to claim 1 or 10, characterized in that in the central part of the building there are open air intake openings, from which underground air ducts are provided, equipped with water-air heat exchangers and connected to the internal cavities of the air intake devices of the solar conversion sections.  13. The building of a wind power station according to claim 1, or 10, or 12, characterized in that the air-water heat exchanger is made in the form of a water intake basin and a supply water line located above it, the beginning of which is connected to an auxiliary open water body at a depth below its probable level ice cover, and the end is placed in the underground air channel and provided in its lower part with openings for free fall of water jets over the entire horizontal cross section of the air channel.  14. The building of a wind power station according to claim 1, or 10, or 12, characterized in that the underground air channel is located next to the greenhouse pond and is equipped with an additional water-air heat exchanger, the inlet and outlet water lines of which are connected to the greenhouse pond, the heat exchanger being located before the exit of the underground air channel.  15. The building of a wind and solar power station according to claim 1, or 12, or 13, or 14, characterized in that the underground air channel is located under the bottoms of greenhouse ponds and an auxiliary open reservoir.  16. The building of the wind power station according to claim 1, or 10, or 12, characterized in that each of the outputs of the underground air channel is connected to the internal cavity of one or more air intake devices of the solar conversion sections.

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