EA032692B1 - Solar and wind power plant - Google Patents

Abstract

A solar and wind power plant relates to the field of wind and solar energy, and can be used for self-contained and year-round power supply for domestic and industrial consumers. The invention addresses the problem of reducing the consumption of materials and the cost and weight of the solar and wind power plant. The problem is solved in that in the solar and wind power plant, containing a vertical axis wind turbine which is made of blades in the form of cylindrical surfaces and is mechanically connected to an electrical power generator; a solar concentrator; a unit for tracking the position of the sun; and a heat absorber designed in the form of tubes with a heat-transfer agent, the concave surfaces of the blades are made of a material which reflects solar radiation onto the heat absorber disposed on the axis of rotation of the wind turbine, functioning as a solar concentrator. In alternative embodiments, the blades of the wind turbine are designed so as to be capable of rotation about the vertical axis thereof. The wind turbine with the electrical power generator can be secured so as to be capable of deviation from the vertical axis. The convex surfaces of the blades can be made of a material which converts light energy into electricity. The joint use of solar energy and wind energy makes it possible to produce a year-round, self-contained power supply.

Description

The invention relates to the field of wind and solar energy and can be used, for example, for autonomous and year-round energy supply for both domestic and industrial consumers, including on balconies of multi-storey buildings. It is most advisable to use the invention for energy supply of country houses, cottages, tourist centers, motels, roadside cafes or shops, remote from the central electricity and heating systems.

It is known that in the temperate and circumpolar latitudes (40-65 °) not a single type of alternative energy source is capable of covering the energy costs necessary for a comfortable stay of even one person all year round. Therefore, they resort to the simultaneous use of two or even three sources of energy in order to smooth out seasonal fluctuations in the supply of solar or wind energy.

For example, a solar-wind installation is known, containing wind turbines and photovoltaic solar panels (RF patent 2182674, F03D3 / 00 of 05.20.2002 http://www.freepatent.ru/patents/2182674). This installation is the sum of two independent devices that generate electricity. Therefore, the material consumption, cost and weight of this installation will equal or even exceed the sum of the cost and the sum of the weight of each of the devices separately. It should also be noted that the use of electricity from solar panels for heating and hot water supply is not rational, since the efficiency of the batteries is only 15-17%. To do this, it is better to use 45-70% of solar heat directly using solar collectors.

A known solar-wind installation (RF patent No. 2309339 F24J2 / 42 dated 10.27.2007 http://www.freepatent.ru/patents/2309339) containing a wind turbine mechanically connected to the generator and a solar collector. Like the previous analogue, this installation is the sum of two devices: a wind generator and a solar collector. The material consumption, cost and weight of this installation will also be equal to the sum of the costs, material intensity and weight of each device taken alone. In addition, the specified solar-wind installation occupies a large area, also equal to the sum of the areas of each device taken separately, which does not allow its use on the balconies of high-rise buildings.

The closest analogue is a solar-wind installation containing a vertical-axis wind turbine made of blades in the form of a cylindrical surface and mechanically connected to an electric generator, a unit for tracking the position of the sun and a solar radiation concentrator optically connected to a heat receiver made in the form of tubes filled with a heat carrier ( http://bio-energy.com.ua/index.php?option=com_content&view=article&id=1856:wind&catid=47:2012-08-0418-07-56&Itemid=129), date of publication: 05/13/2013.

Despite the fact that the specified solar-wind installation is more compact than the previous analogues, it also represents the sum of two independent devices combined on a common frame. Therefore, the material consumption, cost and weight of this installation will also consist of the sum of the cost, material intensity and weight of each device taken separately. In addition, the design features of this installation do not allow its use on the balconies of apartment buildings.

The basis of the invention is the task of reducing the material consumption, cost and weight of a solar-wind installation, in order to combine with high compactness to ensure the possibility of its use even on balconies of apartment buildings.

The problem is solved in that

1) a solar-wind installation containing a vertical-axis wind turbine made of blades in the form of cylindrical surfaces, mechanically connected to an electric generator, a solar radiation concentrator, a tracking unit for the position of the sun and a heat receiver made in the form of tubes with a coolant, characterized in that it is concave the surfaces of the blades are made of material reflecting solar radiation to a heat sink located on the axis of rotation of the wind turbine, performing the function of a solar energy concentrator;

2) the solar-wind installation according to claim 1, characterized in that the blades of the wind turbine are rotatable around its vertical axis and mechanically connected to the control unit of the rotation angles, which provides focusing of solar radiation reflected from each blade to the heat sink, while the generator connected to the tracking unit for the position of the sun;

3) the solar-wind installation according to claim 1, characterized in that the wind turbine together with the electric generator is mounted on a frame having the ability to deviate from the vertical so that the axis of rotation of the wind turbine is perpendicular to the sun's rays;

4) the solar-wind installation according to claim 1, characterized in that the convex surfaces of the blades are made of material that converts solar radiation into electricity.

According to the proposed invention, the implementation of the concave surfaces of the blades of a material that reflects solar radiation well, turns the wind turbine into a solar energy concentrator, making it possible to collect solar energy.

The implementation of the blades of a wind turbine with the possibility of rotation around its vertical axis and their

- 1 032692 mechanical connection with the control unit of rotation angles leads to the fact that the blades can be positioned so that they reflect the incident solar radiation so that the reflected beams intersect on the axis of rotation of the wind turbine and fall on the radiation heat receiver. To achieve maximum results, the rotation angles of each blade must be well defined, and these angles depend on the number of blades of the wind turbine. If the number of blades is even, then based on the laws of geometric optics, the rotation angles α for each blade are determined by the formula a = 180 / n (1/2 + m), where n is the number of blades, am = 0,1,2 ..., n-1 is the number of the blade for which the rotation angle is determined. If the number of blades in the wind turbine is odd, then the calculation is performed according to the formula a = 180m / n. It does not matter which blade to take zero, all the blades will occupy a position in which the sun's rays reflected from them intersect on the axis of rotation of the wind turbine.

Wind turbine blades, as a rule, have a certain radius of curvature. The maximum effect of collecting solar energy will be achieved if the radius of curvature of the cylindrical surface of the blades is chosen equal to the diameter of the circle on which the axis of rotation of the blades of the wind turbine are located, since the blades will focus solar radiation on the surface of the heat sink.

The location of the heat sink, made in the form of at least one tube filled with coolant on the axis of rotation of the wind turbine, allows you to collect thermal energy reflected from each of the blades of the wind turbine. In this case, the heat sink is not mechanically connected to the wind turbine and always remains stationary. This allows you to pump the coolant and effectively deliver thermal energy to the consumer.

In order for the heat sink to be uniformly lit over its entire length and so that the front blades do not obscure the rear, the wind turbine is tilted so that the solar radiation is perpendicular to the axis of rotation of the wind turbine. For this, the wind turbine together with the electric generator is mounted on a frame, which has the ability to deviate from the vertical by an angle depending on the height of the sun above the horizon.

Connecting the electric generator to the tracking unit for the position of the sun leads to the fact that the electric generator in this case works as an engine and provides constant orientation of the wind turbine blades in the sun, which also contributes to an increase in the efficiency of collecting thermal energy.

The implementation of the convex surfaces of the blades of the wind turbine from a material that converts the energy of light into electricity, allows the solar-wind installation to give energy even when the sun is behind the clouds and there is no wind. In this case, the wind turbine rotates so that the convex surfaces of the blades are directed to that part of the sky where the sun is behind the clouds. Diffused sunlight is converted into electrical energy and charges the battery. This mode of operation can also be used when electrical energy is of paramount importance, and not thermal, for example, in summer.

Thus, the proposed invention enables the wind turbine to additionally perform the function of a solar energy concentrator. As a result, the material consumption, cost and weight of the installation are almost halved, because each element performs two functions without any burden. Since the heat sink is located inside the wind turbine, the geometric dimensions of the entire solar-wind installation are determined solely by the dimensions of the wind turbine. That is, the solar-wind installation is reduced to the size of a wind turbine. Given the compactness and the fact that the vertical-axis wind turbine perceives wind of any direction, it can even be used on balconies of apartment buildings.

The combined use of solar and wind energy allows for year-round autonomous energy supply. This is due to the fact that the maximum productivity of wind and solar systems occur at different times of the day and year.

The above causal relationship between the totality of the essential features of the invention and the technical result is not obvious to the average specialist, is not known from the prior art, which indicates that our invention meets the criteria of novelty and inventive step.

The invention is illustrated by drawings. In FIG. 1 shows the location of the blades of the wind turbine in the mode of a wind generator, where it is indicated: 1 - the body of the wind turbine, 2 - the blades of the wind turbine, 3 - the control unit for the angles of rotation of the blades, 4 - heat sink, 5 - wind flow.

In FIG. 2 shows the arrangement of the blades of the wind turbine in the mode of a solar radiation concentrator, where it is indicated: 1 - the body of the wind turbine, 2 - the blades of the wind turbine, 3 - the control unit for the angles of rotation of the blades, 4 - the heat sink, 6 - the flux of incident solar radiation, 7 - the direction of reflected solar radiation .

In FIG. 3 shows a solar-wind installation in the optimal orientation to the sun, where it is indicated: 1 - wind turbine body, 2 - wind turbine blades, 6 - incident solar radiation flux, 8 - electric generator, 9 - frame with the possibility of deviation from the vertical, and 10 - mouth

- 2 032692 swarm deviation of the frame from a vertical position.

The solar-wind installation works as follows. In the morning, when the intensity of solar radiation is sufficient to start heating the heat carrier located in the heat sinks 4, and the wind turbine does not rotate or does not provide the rated power, the blade angle control unit 3 turns on and puts them into a position that corresponds to the concentration of solar radiation, i.e. as shown in FIG. 2. In this case, the wind turbine stops feeling the wind and stops. The stop is significantly accelerated when the electric generator 8 is connected to the tracking system for the position of the sun. By supplying the appropriate signals from the unit for tracking the position of the sun to the device 10 of the deviation of the frame from the vertical position and to the windings of the electric generator 8, the blades of the wind turbine are accurately oriented to the sun, ensuring maximum solar radiation flux to the heat receiver 4. As the sun moves through the sky, the tracking system constantly corrects the orientation of the wind turbine, holding the heat sink 4 at the intersection of all the rays reflected by the concave surfaces of the blades 2. In the evening, when st solar radiation falls below an acceptable threshold, turns back unit 3 controls the rotation angles of blades and translates them into a position corresponding vetroelektrogenerator mode, i.e. as shown in FIG. 1. The generator 8 is disconnected from the tracking system for the position of the sun. The device 10 deviation of the frame from a vertical position returns the frame to a vertical position, and the wind turbine continues to generate electricity in the presence of wind. If the next morning the sun is behind the clouds, then the solar-wind installation will continue to operate in the mode of a wind generator until the sun tracking unit detects a sufficient level of solar radiation. If the sun in the morning behind the clouds and there is no wind, then the blades rotation angle control unit 3 again puts them in a position corresponding to the concentration of solar radiation, but the tracking system orientates the wind turbine so that the convex surfaces of the blades are directed to the part of the sky where the clouds are located the sun. In this case, the source of energy will be electrical energy received from the converters of the energy of light into electricity deposited on the convex surfaces of the blades. This mode of operation of the solar-wind installation is also possible in the case when the water in the boiler is already heated to the desired temperature, the intensity of solar radiation is high, and the wind is absent. It should be noted that the converters of light energy into electricity deposited on the convex surfaces of the blades will also work when the solar-wind installation is in the regime of a wind generator. That is, whatever the weather conditions, the solar-wind installation will not stand idle, and will always give energy either in the form of heat, or electricity, or both at the same time.

In one embodiment of the solar-wind installation, the wind turbine housing 1 was made of a composite material (polystyrene laminated on both sides with aluminum foil) 3 mm thick. The diameter of the wind turbine is 45 cm, the height is 47 cm. The blades of 2 wind turbines are made of mirror aluminum with a thickness of 0.5 mm and have a width of 9 cm, a height of 45 cm and a radius of curvature of the cylindrical surface of 36.5 cm. A flexible photovoltaic film is applied to the convex surface of the blades 2, close in characteristics to this (http://vipmart.com.ua/p21505986-gibkaya-solnechnayabatareya.html). The rotation angles of the blades were controlled manually by fixing each blade in the desired position. The number of blades is 12, therefore, the rotation angle was a = 7.5 + 7.5m, where m = 0.1.2 ... 11. As a heat sink 4, a vacuum tube manufactured by Star-energy (http: // www. star-energy.com.ua) with a length of 85 cm and an external diameter of 58 mm. The tracking unit for the position of the sun is made according to a scheme close to that described here http://www.solarhome.ru/biblio/pv/tracking.htm. As a concentrator of solar radiation, the specified solar-wind installation had a power of 140W. When the solar-wind installation was switched to the wind power generation mode, the blade installation angle (or, as it is also called, the jamming angle) was selected at 45 °. In this case, one of the blades does not change its position, because in the solar concentrator mode it was also at an angle of 45 ° to the tangent to the circle. The generator 8 was made in the form of permanent magnets glued to the lower disk of the housing 1 of the wind turbine, and coils of copper wire mounted on the frame 9. As a wind generator, this solar-wind installation had a power of 10 W, and as a solar battery - 15 W.

In another embodiment of the solar-wind installation, the wind turbine housing 1 was made of a composite material (polystyrene laminated on both sides with aluminum foil) 3 mm thick. The diameter of the wind turbine is 85 cm, the height is also 85 cm. The blades of 2 wind turbines are made of mirror composite material 3 mm thick and have a width of 29 cm, a height of 84 cm and a radius of curvature of 67.5 cm. The number of blades is 7. A flexible photovoltaic is applied to the convex surface of the blades a film with parameters close to that described here http://www.ataba.com.ua/productinfo.php7products id = 438 & osCsid = 2581f95d428598a48c4f88994ece43e4 The blade rotation control unit 3 is made in the form of a lever mechanism, has two fixed positions, respectively: for the mode of concentration of solar radiation exercises and for the wind mode

- 3 032692 power generation. Switching from one mode to another is carried out either using an electromagnet or manually. As a heat sink 4, a vacuum tube manufactured by Star-energy (http://www.star-energy.com.ua) with a length of 85 cm and an external diameter of 58 mm was used. As a solar radiation concentrator, this solar-wind installation produced up to 500 W of thermal energy. This is enough to heat 80-100 l of water to a temperature of 50-70 ° during the day. In the wind power generation mode at a wind speed of 7-8 m / s, the indicated solar-wind installation produced up to 50 W of electric power and the same in the solar battery mode. This is enough to always have charged batteries with a capacity of 80-120 ampere-hours.

Thus, our proposed technical solution meets all the criteria for the protection of the invention, since it has a world novelty, a high inventive step, is not obvious to the average person skilled in the art, and has industrial applications.

Claims (2)

1. Solar-wind installation containing a vertical-axis wind turbine made of blades in the form of cylindrical surfaces, mechanically connected with an electric generator, a solar radiation concentrator, a unit for tracking the position of the sun and a heat receiver made in the form of tubes with a coolant, characterized in that it is concave the surfaces of the blades are made of material that reflects solar radiation to a heat sink located on the axis of rotation of the wind turbine, performing the function of a solar energy concentrator, at The blades of the wind turbine are mechanically connected with the control unit for the angles of rotation of the blades around its vertical axis, providing focusing of the solar radiation reflected from each blade on the heat sink, and the electric generator is connected to the tracking unit for tracking the position of the sun. 2. The solar-wind installation according to claim 1, characterized in that the wind turbine together with the electric generator is mounted on a frame having the ability to deviate from the vertical so that the axis of rotation of the wind turbine is perpendicular to the sun's rays.