RU2597729C1 - Solar power plant with a fibre-optic guidance system - Google Patents

Abstract

FIELD: energy.

SUBSTANCE: invention relates to power engineering, namely to conversion of solar radiation to electricity by means of thermal machines, and can be used, in particular, in turret-type solar power plants. Solar power plant comprises a turret, on the upper end of which there is a solar radiation receiver, associated with a thermal machine, connected to an electric generator. Near the turret there are heliostats, made of concentric elements consisting of a lens with large focal distance F, lens with a small focal distance f, a compound conical concentrator of total internal reflection and an optical cable, in the concentric elements the lens with focus f is located at distance F+f from the lens with focus F, an inlet the compound conical concentrator is in the lens with focus f, and its outlet is connected to a fibre-optic cable with a diameter equal to a diameter of an output of the compound conical concentrator. Outlet ends of the fibre-optic cables of the concentric elements are combined into a bundle, which is attached to a post, placed near the heliostat, and is directed so, that beams of concentrated solar radiation coming out of fibre-optic cables, fall on the solar radiation receiver.

EFFECT: invention enables conversion of solar radiation into a parallel concentrated light flux.

3 cl, 3 dwg

Description

The invention relates to energy, and in particular to the energy of converting solar radiation into electricity using thermal machines, and can be used, in particular, in solar power plants of a tower type.

Known solar power plant modular type, converting solar radiation using Stirling engines (Energy: economics, technology, ecology. Journal of the Presidium of the Russian Academy of Sciences No. 10, 2006, pp. 33-37). Each station module consists of a quasi-parabolic concentrator, the reflective surface of which is made of mirror squares. The focus of the concentrator is a Stirling engine connected to an electric generator, with the help of which concentrated solar radiation is converted into electricity.

The disadvantage of this solar station is the low efficiency of converting solar radiation into electricity using heat engines. This is because the conversion is carried out using several low-power heat engines, namely, using low-power Stirling engines located in each module of the solar station.

From the energy using traditional fuels, it is known that the efficiency of a power plant increases with increasing capacity of a heat engine.

The closest adopted for the prototype is a solar power station of a tower type. (Alekseev V.V., Chekarev K.V. Solar energy. - M .: Knowledge, 1991). The solar station contains a tower, at the upper end of which there is a solar radiation receiver, made in the form of a tank with water, which is connected to a heat engine connected to an electric generator. Around the tower are heliostats, the position of which relative to the sun is regulated by a control system.

The solar station operates as follows. With sunrise, each heliostat with a control system is oriented so that the solar radiation reflected from the heliostat falls on the receiver to convert it into electricity using a heat engine connected to an electric generator.

The disadvantage of a tower-type solar power station is the low efficiency of converting solar energy into electricity using heat engines, due to the following reasons.

To ensure high power of the solar power plant, it is necessary to direct the reflection of solar radiation from many heliostats to the solar energy receiver, which at large distances between the receiver and heliostats makes the task of precise guidance extremely difficult.

When the sun moves in the sky, the flow of solar energy entering the receiver all the time changes from the maximum value at sunrise and sunset to the minimum values at noon, since with an increase in the height of the position of the sun the effective reflective surface of the heliostats decreases according to a sinusoidal law.

In addition, if the heliostats are located around the tower with the solar energy receiver, a change in the position of the sun in the sky leads to the fact that in the first half of the day only one part of the heliostats works, and the other part of the heliostats does not work, and in the second half of the day the other part of the heliostats works. Thus, to ensure a given station power, it is necessary to use a double number of heliostats. If the tower is located in front of the field of heliostats, their effective reflecting surface decreases both at a high position of the sun and at a low position, which also requires the introduction of an additional number of heliostats to ensure a given station power.

The objective of the invention is to increase the efficiency of converting solar energy into electricity using a heat engine.

The technical result is to increase the conversion efficiency of solar radiation into electricity using a heat engine.

The technical result is achieved by the fact that in a solar power station containing a tower, at the upper end of which there is a solar radiation receiver connected to a heat engine connected to an electric generator, and heliostats located next to the tower, the position of which relative to the sun is regulated by a control system, heliostats are made from concentrating elements consisting of a lens with a large focal length F lens with a small focal length f, a conical foclin of total internal reflection and opt cable, while in the concentrating elements the lens with focus f is at a distance F + f from the lens with focus F, the inlet of the conical focline is located at the lens with focus f, and a fiber optic cable is connected to its output hole, the diameter of which is equal to the diameter of the outlet conical foclin, while the output ends of the fiber optic cables of the concentrating elements forming the heliostat are connected in a bundle, which is attached to the rack, installed at the heliostat, and is directed so that the rays of the concentrated of solar radiation coming out of a bundle of fiber optic cables, hit the receiver of solar radiation.

The implementation of heliostats from the concentrating elements of the proposed design eliminates the disadvantages of solar power plants of the tower type. With their help, solar radiation turns into a parallel concentrated light stream, which enters the fiber optic cables and is sent to the solar radiation receiver by fixing the output ends of the fiber optic cables in the desired direction. In this case, the task of orienting the heliostats relative to the sun is reduced to directing the normal to the plane of the heliostats to the sun, which is a simple task for the control system. With this orientation of the heliostats to the sun, the magnitude of the solar flux arriving at the solar radiation receiver does not change when the sun moves around the sky, which allows the use of a smaller number of heliostats to provide a given power to the solar station.

The invention is illustrated by the diagrams shown in FIG. 1, 2 and 3. As shown in FIG. 1, the solar power station comprises a tower 1, at the upper end of which there is a solar radiation receiver 2. Its implementation depends on the type of heat engine. For heat engines, in which the working fluid is water vapor, the solar radiation receiver can be made in the form of a tank with water connected to a heat engine connected to an electric generator. Near the tower 1 are heliostats 3 made of concentrating elements 4, a diagram of which is shown in FIG. 2. The concentrating element contains a lens 5 with a large focal length F, a lens 6 with a small focal length f, a conical foclin of total internal reflection 7 and a fiber optic cable 8. Lens 6 is located at a distance F + f from lens 5, which allows to obtain a concentrated parallel beam solar radiation. The lenses 5 can be made in the form of Fresnel lenses with a focal length F of the order of 50 cm. At the lens 6 there is an inlet of the conical foclin 7 made in the form of a truncated glass cone. The base of the truncated cone, which is the inlet of the conical foclin 7, exceeds the diameter of the lens 6 by about 3 times, which reduces the accuracy requirements for pointing the concentrating element to the sun. With inaccurate guidance, a parallel beam of concentrated solar radiation emerging from the lens 6 and entering the conical foclin 7, as a result of total internal reflection, will exit the outlet of the conical foclin 7 and fall into the fiber optic cable 8 connected to the outlet of the conical foclin 7. Diameter of the fiber optic cable 8 is equal to the diameter of the outlet conical foklin 7.

As can be seen from FIG. 3a) and b), the concentrating elements 4 are arranged in rows on the heliostat 3. The output ends of the fiber optic cables 8 of the concentrating elements 4 forming the heliostat 3 are connected in a bundle 9, which is attached to the stand 10, placed at the heliostat 3, and is guided so that concentrated solar radiation emerging from the beam 9, fell on the receiver of solar energy 2. Stand 10 is located at the rear and side of the heliostat so as not to interfere with its rotation when tracking the sun.

Solar power station operates as follows. Using the control system, all heliostats 3 are set so that the normal to the plane of the heliostat is always directed towards the sun. Solar radiation, falling on the concentrating elements 4 of heliostats 3, turns into a parallel stream of concentrated solar radiation, which is sent to the solar radiation receiver 2 using a bundle of fiber optic cables 9 attached to the rack 10 to convert it using a heat engine connected to an electric generator, into electricity.

A mock-up of a solar power station with fiber optic guidance was built. The experiments showed the efficiency and effectiveness of the proposed design of the solar station.

Claims (3)

1. A solar power station comprising a tower, at the upper end of which there is a solar radiation receiver connected to a heat engine connected to an electric generator, and heliostats located next to the tower, the position of which relative to the sun is regulated by a control system, characterized in that the heliostats are made of concentrating elements consisting of a lens with a large focal length F, a lens with a small focal length f, a conical foclin of total internal reflection and a fiber optic cable. 2. The solar power plant according to claim 1, characterized in that in the concentrating elements the lens with focus f is located at a distance F + f from the lens with focus F, the inlet of the conical focline is located at the lens with focus f, and attached to its outlet fiber optic cable, the diameter of which is equal to the diameter of the outlet conical foklin. 3. The solar station according to claim 1, characterized in that the output ends of the fiber optic cables of the concentrating elements forming the heliostat are connected in a bundle that is attached to a rack placed near the heliostat and is guided in such a way that concentrated solar radiation coming out of the beam fiber optic cables hit the receiver of solar radiation.

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