EA028239B1 - Solar energy concentrator - Google Patents

Abstract

The invention relates to the field of solar heat utilization and can be used for converting solar energy into mechanical, thermal or electrical energy. A solar energy concentrator comprises a support structure, the fastening mounting seats of which have a reflector disposed therein which concentrates solar radiation on an elongate receiver located in the focal region. The concentrator is in the form of a closed cylindrical surface, light-reflecting facets are disposed in mounting seats at a variable angle to the cylindrical surface and with spaces therebetween, the total area of the facets being equal to or greater than the area of the concentrator, and the receiver is situated along the axis of the cylindrical surface. The invention provides for a reduction in wind load and eliminates the risk of harm to nearby objects and humans.

Description

The invention relates to the field of use of solar heat and can be used to convert solar energy into mechanical, thermal or electrical energy in various fields of technology, as well as in everyday life, in particular, for heating water, space heating, cooking.

It is known to use solid parabolic cylindrical mirrors for the concentration of solar energy (Russian patent 2300058 MKI P241 2/14 of 05/27/2007. Parabolic cylindrical solar energy concentrator with an absorber and a sun tracking system).

Such systems make it possible to concentrate solar energy of high power in the focal region, but at the same time they have high windage, which requires the use of powerful load-bearing structures and, as a result, considerable energy expenditures for ensuring the tracking of the concentrator over the position of the Sun. In addition, with gusts of wind, the tracking system may not cope with the loads and a powerful flow of energy goes beyond the limits of the radiation receiver and can harm surrounding objects, birds, animals and humans.

A well-known solar energy concentrator (USSR author's certificate No. 1633238, P241 2/10, 1991) with flat reflective elements that rely on guides in the form of a parabolic cylinder surface.

A disadvantage of the known device, as well as the previous one, is a rather high windage, since the slit-like gaps between the reflecting elements have a small area compared to the area of the entire concentrator and cannot be sufficiently increased due to defocusing of solar energy. This also necessitates the use of powerful supporting structures of both the concentrator itself and the tracking system for the position of the Sun.

The closest in technical essence is a solar energy concentrator (RF patent 2188364, P241 2/14 of 08/27/2002), which includes a support structure, in the fixing seats of which are light-reflecting facets that form a cylindrical surface and concentrate solar energy for extended radiation detector located along the axis of the cylindrical surface.

The specified hub also has a high windage, since the area of the gap spaces between the facets, as in the above analogues, is a small part compared to the area of the hub. It also leads to the fact that it is necessary to use heavy and material-intensive load-bearing structures of both the concentrator itself and the tracking system for the position of the Sun. In addition, the design features of the known concentrator do not eliminate the danger of harming surrounding objects, birds, animals and humans in the event of strong gusts of wind or a failure of the tracking system, since the powerful energy flow in this case uncontrollably goes beyond the limits of the radiation receiver.

The basis of the invention is the task of reducing the wind load on the elements of the concentrator, reducing the weight and material consumption of the supporting structures of both the concentrator itself and the tracking system for the position of the Sun, as well as eliminating the danger of harm to surrounding objects, birds, animals and humans.

The problem is solved in that in a solar energy concentrator including a support structure, in the fixing seats of which there are light-reflecting facets that form a cylindrical surface and concentrate solar energy on an extended radiation detector located along the axis of the cylindrical surface, according to the invention, the cylindrical surface of the concentrator is made in the form of a closed cylindrical surface, while the reflecting facets are located along a closed cylindrical curve surface with a variable angle to it, providing the maximum concentration of solar energy on an extended radiation detector, and with gaps between the reflecting facets, the total area of which is equal to or greater than the aperture of the concentrator.

The execution of the surface of the concentrator in the form of a closed cylindrical surface leads to the fact that, while maintaining the same aperture of the concentrator as that of the closest analogue, large gaps can be formed between the reflecting facets, almost the width of the facet. This dramatically reduces the windage of the hub, as the wind flow has the ability to almost seamlessly pass through the hub. Since gaps have formed between the facets, to ensure the maximum concentration of solar energy (not less than that of the analogue), they must be placed along a closed cylindrical surface at variable angles to it. The location of the facet with a variable angle allows you to change the distribution of solar power in the focal band in accordance with the geometric dimensions and shape of the radiation receiver, providing the maximum level of energy collection. In addition, by changing the angles of the reflecting facets relative to the focal strip, you can change the position of the focal strip by placing it either in the center of the cylindrical supporting structure, or shifting it in one direction or another. This extends the functionality of the concentrator, since for any receiver it is possible to create an optimal power distribution, which will provide the maximum solar energy conversion coefficient. The location of the reflecting elements on one side of the focal plane, opposite the gaps between the reflecting elements located on the other side of the focal plane, provides the maximum degree of energy collection.

If the reflecting facets that are on one side of the concentrator are located opposite the gaps between the reflecting facets located on the other side of the concentrator, then the concentrator will collect the largest amount of solar energy, since the facets will not obscure each other. Those. not a single quantum of solar energy that has entered the aperture will pass by the reflecting facet of the concentrator and will necessarily hit the radiation receiver. In this case, it even becomes possible to almost halve the total thickness of the concentrator while maintaining the same aperture. As a result, the shape of the concentrator from the cup-shaped, which has the closest analogue, turns into a symmetrical and well-streamlined shape of a flattened cylinder. The total area of the gaps between the reflecting facets may be equal to or even exceed the area of the input aperture of the concentrator.

If the facets are made flat and of the same width, then the transverse dimension of the extended radiation receiver cannot be smaller than the width of the facet. For otherwise, the receiver will not be able to absorb all the energy collected by the facet, which will lead to a decrease in the efficiency of the concentrator. If the facets are made in the form of cylindrical surfaces, then in this case they will focus solar energy on the receiver, and its transverse size, as well as its weight, can be reduced several times. The greatest effect will be achieved if the radius of curvature of the cylindrical facet surface is twice as large as the distance between this facet and the radiation receiver.

If the reflecting facets are made in the form of diffraction gratings, then in this case it becomes possible to influence the spectral composition of concentrated energy and the possibility of separate use of different parts of the spectrum of solar radiation. For example, the infrared portion of the spectrum is used to heat the coolant, the portion of visible light is used to generate electricity using photovoltaic panels, and ultraviolet radiation is used to disinfect and disinfect water. And all this in one device.

If the reflecting facets are made in the form of holograms, then in this case it becomes possible not only to influence the spectral composition of the concentrated energy, but also to arbitrarily change the place and shape of its localization. This greatly expands the functionality of the hub and its scope.

Distinctive features of the invention provide the ability to form the focal region of radiation in the geometric center of symmetry and in the center of gravity at the same time. This leads to a significant simplification of the design of the tracking system and a reduction in energy costs for controlling the position of the concentrator relative to the Sun. In addition, the receiver located in the center of symmetry of the hub does not require mechanical connection with the hub, which allows the use of heavy and bulky receivers, such as a steam boiler or complex transducers with water cooling systems with a lightweight hub design, for example, in the form of a symmetrical openwork balanced wind-resistant design , which controls a small amount of energy.

The fact that the focal region, in which large thermal energy is concentrated, is located inside the concentrator, completely eliminates the possibility of even accidental contact with foreign objects, birds, animals and people. In addition, when the tracking system fails and the Sun moves from the optical axis, the concentrated energy does not go beyond the concentrator, but breaks up into separate streams from each reflecting facet. The energy of these flows is small and can not harm either the elements of the concentrator or the surrounding objects, birds, animals and humans.

Thus, 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 in the drawing, which shows a cylindrical supporting structure 1, reflecting facets 2 in front of the focal strip, reflecting facets 3 located behind the focal strip, solar energy receiver 4, solar energy stream 5 and the projection of the plane 6 in which the focal strip lies.

The solar energy concentrator operates as follows. The solar concentrator is oriented so that the plane 6 in which the focal band lies is perpendicular to the solar energy flux 5. Then, the solar energy flux 5, having reached the reflecting facet 2, is reflected from them and sent to the solar energy receiver 4. The flow of 5 solar energy, which passed through the gaps between the reflecting facets 2, falls on the reflecting facets 3, is reflected from them and also sent to the receiver 4 of solar energy. Thus, the entire flow of solar energy entering the aperture of the concentrator is directed to the receiver 4 of solar energy.

When the angle of the solar concentrator with respect to the flow of solar energy changes, a shading of the reflecting facets 3 with reflecting facets 2 occurs on the one hand, and on the other hand, a smaller flux from the reflecting facets 2 enters the solar energy receiver 4. As a result, the focal band smoothly blurred. This is a very important property for systems where it is necessary to maintain a constant temperature for a long time, for example in a solar desalination plant. And, in addition, solar radiation goes beyond the limits of the concentrator weakened and can not harm surrounding objects, birds, animals and humans.

In one of the options for manufacturing a solar energy concentrator, cylindrical supporting structures 1 are made in the amount of 4 pieces of sheet transparent acrylic 3 mm thick, in which cuts were made to fix the reflecting facets 2 and 3. Reflecting elements 2 and 3 are made of mirror sheet polystyrene with a thickness of 3 mm, having a reflection coefficient of 0.75-0.85 in the visible range. As a receiver 4 of solar energy, a vacuum tube of 85 cm length was used. The size of the concentrator is 0.77x0.75 m, weight 4.4 kg and thermal power 500 W.

In another embodiment of the solar energy concentrator, the cylindrical support structures 1 are made of a composite material (polystyrene laminated on both sides with aluminum foil) 3 mm thick in an amount of 8 pieces. Reflecting facets 2 and 3 are made of mirror aluminum with a thickness of 0.4 mm and having a reflection coefficient of 0.92-0.95. As a receiver 4 of solar energy, a vacuum tube 180 cm long was used. The size of the concentrator is 1.75x0.8 m, weight 10.5 kg and thermal power 1 kW.

Thus, the proposed technical solution meets all the criteria of a protected invention, since it has a world novelty, a high inventive step, is not obvious to a person skilled in the art and is industrially applicable.

Claims (5)

CLAIM 1. The solar energy concentrator, including the supporting structure, in the fixing seats of which are light-reflecting facets that form a cylindrical surface and concentrate solar energy on an extended radiation detector located along the axis of the cylindrical surface, characterized in that the cylindrical surface of the concentrator is made in the form of a closed a cylindrical surface, while the reflecting facets are located on a closed curve of the cylindrical surface with a variable angle to providing the maximum concentration of solar energy on an extended radiation detector, and with gaps between the reflecting facets, the total area of which is equal to or greater than the aperture of the concentrator. 2. The solar energy concentrator according to claim 1, characterized in that the reflective facets that are on one side of the concentrator are located opposite the gaps between the reflective facets that are on the other side of the concentrator. 3. The solar energy concentrator according to claim 1, characterized in that the reflecting facets are made in the form of cylindrical surfaces, the radius of curvature of which is two times greater than the distance of the facet to the radiation receiver. 4. The solar energy concentrator according to claim 1, characterized in that the reflecting facets are made in the form of diffraction gratings. 5. The solar energy concentrator according to claim 1, characterized in that the reflecting facets are made in the form of holograms.