DE3211339A1 - Solar installation - Google Patents

Abstract

The use of light guides for the purpose of energy transport in solar installations with concentrating reflectors and (Fresnel) lenses (10-12) is described. The radiant energy concentrated in the respective focal plane is coupled in each case into one or more receptor cones (15a-17a), relayed to one or more light guides (15-17) and guided in the light guide by means of multiple total reflection to an energy transducer (13) whose installation site can thereby be selected independently of the location of the reflector or lens system. The beam exit end (25) of the light guides is directed perpendicular to an irradiation plane (26) of the energy transducer and is arranged at a selectable distance from the irradiation surface (26). The result is that the highly concentrated radiation which emerges from the respective guide is distributed over a relatively large area in order to avoid problems with materials in the energy transducer. <IMAGE>

Description

Solar system

The invention relates to a solar system with an energy converter and with at least one concentrator that directs the sun's rays onto a focal point concentrated in the focal plane, the focal spot being speckled, in particular can be circular or linear.

Previously known systems consist of a field with reflectors Init either several absorbers each connected to one of the reflectors or one A radiation receiver arranged in a tower, which concentrated the radiation from the reflectors Absorbs and converts radiation.

However, these systems are not yet too satisfactory Results come because the high investment costs in an unfavorable proportion stand for the relatively low degree of effectiveness. Material problems also arise the radiation receiver materials used and safety problems the heliostats on.

The invention is based on the object of a system of the initially to create mentioned type, which on the one hand has a higher degree of efficiency, but In terms of production technology, it is simpler than previously known systems, but on the other hand is inherently safe and avoids material problems The task Invention is solved by the fact that between your focal point and the energy converter a receiving cone and then a cone that transmits the bundled rays Light guide is provided.

The radiation concentrated in the focal plane is above the reception cone further concentrated and coupled into the light guide with low energy losses and forwarded to the energy converter. This means that the energy converter does not need it more, as before, are arranged in the focal plane of the concentrator.

This ensures that the concentration on the one hand and the energy converter on the other hand as two separate systems according to the respective optimal conditions can be made, both in terms of performance improvement and also represents a significant improvement for production.

This eliminates the need for expensive facilities such as the towers in the Sun urine systems or the long piping, as they are in so-called solar farms with absorbers arranged in the focal plane of reflectors are necessary. Of the Concentrator, which can be a mirror reflector or a Fresnel lens, can be independent on the type of energy conversion and removed from any pipes to be carried Easy to manufacture and designed to be optimally adaptable to the respective location will.

In addition, the energy converter can be convenient and weatherproof in one The machine house is located on the ground and even below the surface of the earth will.

Geinaß one embodiment of the invention is a quartz light guide with low attenuation in the spectral range of solar radiation or a plastic light guide provided with similar properties, especially polymethyl methacrylic. Herewith let it guide sunlight of high concentration, and also a relatively small one Absorption loss is recorded, which is less than 25% for a length of 250 m. The exit end of the light guide is perpendicular to the radiation surface of the energy converter directed and kept at a distance from the irradiation surface.

The radiation emerging from the light guide is divided into one Cone so that the energy density increases with the distance of the light guide exit decreases. By appropriate choice of the distance between the light guide and the The radiation surface of the energy converter can create optimal conditions for low-loss Energy conversion can be created. Through the hereby achievable and selectable Large-area distribution from the focal plane recorded over the Aufnahlnekegel Energy, local overheating - such as hot spots "- can be avoided, the choice of materials for the energy converter is increased and the converter is manufactured be simplified. The efficiency is optimized by the fact that the reflection is reduced by annealed material.

According to the required effect, several light guides can be provided which are each fed by the Aufahiekegel and those above the irradiation surface of the energy converter are regularly divided.

This allows the concentrated radiation energy of several reflectors or Fresnel lenses on a genleinsallle irradiation surface of an energy converter conduct.

The regular division of the light guide openings creates a approximately uniform irradiation and thus uniform heating of the Reached the surface of the energy converter, which at the same time caused thermal effects Tension and material problems are avoided.

According to a further embodiment of the invention it is provided that the focal plane of the concentrator lies in the receiving cone. In this case it will the light guide end spatially following the receiving cone in a simple manner with the thinnest possible (i.e. optically as little disruptive as possible) connecting cables tied together.

But it is also possible with the help of a secondary reflector the solar energy focus on a location that is advantageous for the arrangement of the receiving cone is.

An advantageous arrangement is that the entry surface of the receiving cone is located in the apex of the main concentrator in which the focal point of the secondary reflector falls. The inlet opening of the receiving cone can be so large that all of the energy drawn by the concentrator is made in the focal plane is collected, is coupled into the Aufnahiiiekegel. When training a symmetrical-roof-shaped entry plane of the receiving cone can also be the acceptance w can be increased in kel despite the small size of the cone.

If the focal spot is shifted over a long period of time, e.g. due to irregularities The main part can still be tracked by the concentrator according to the position of the sun of the concentrated sunlight are coupled into the receiving cone. Included can also capture a certain amount of diffuse radiation.

In the drawing are three exemplary embodiments according to the invention shown schematically.

In Fig. 1 is a first arrangement with three designed as lenses Concentrators 10 to 12 and an energy converter 13 are shown. The ones on the lenses 10 to 12 incident sun rays 14 are each in focal planes 15 to 17 concentrated. The concentrated solar energy hits a flat entry surface a receiving cone 15a to 17a and is further concentrated in the cone, then forwarded via a light guide 20 to 22 and your regardless of the Lens system 10 to 12 arranged energy converter 13 supplied. For this are the Light guides 20 to 21 combined in a protective cover 23. For irradiating the Energy converter 13, the exit end 25 of the respective light guide is perpendicular directed to the irradiation surface 26 of the transducer 13 and with the opening on one Distance 27 from the Einstrahiflåche 26 kept.

The divergent emerging from the respective light guides 20 to 27 Radiation strikes the irradiation area 26 in a circular area 28, the Circle diameter 29 in front of distance 27 and the light guide aperture is given. the In this way, controllable irradiation energy per unit area is provided by appropriate Interpretation of the distance 27 so that, on the one hand, there is a loss due to scattering minimized and on the other hand the heating of the energy converter 13 within selectable limits y will keep that of the nature of the converter and of desired efficiency depends. After determining the distance 27, the distance 30 between the individual light guides 20 to 22, taking into account the diameter 29 of the irradiation surface 28 so selected that the irradiation surfaces 28 as precisely as possible adjoin each other.

The energy converter 13 shown schematically can be any of the known absorbers or radiation receivers, with which the radiation energy is converted either into heat or directly into electrical energy.

In the embodiment according to FIG. 2, a parabolic concentrator is used as the concentrator Reflector 35 is used, the sun rays occurring on its reflection surface 36 concentrated on a circular focal spot 37 in the focal plane 34. Means thin struts 38 become a receiving cone 41 with an adjoining light guide 39 so held that the focal point 37 koiiimt to lie within the receiving cone 41. The entry surface 40 of the receiving cone 41 is to increase the acceptance angle Convex or roof-shaped ground. This can cause irregularities, for example stray radiation from the optical reflector surface caused by the optical reflector surface are still partially absorbed by the receiving cone 41. Furthermore, thereby are also small shifts in the position of the focal spot are less critical.

When using cones made of light guides made of quartz or Due to the different refractive index between the Material of the receiving cone or the light guide and the air on the face 40 impinging rays 45 and absorbed within the recording keys 41 and of Light guide 39 passed through multiple total reflections. The reflection within the receiving cone 41 can additionally be achieved by reflection layers be improved.

The receiving cone 41 can also be formed hollow. In this case the receiving cone 41 is depending on the application and required temperature resistance made of metal or a temperature-resistant material and nlit a radiation-reflective Layer coated.

In the embodiment according to FIG. 3, a Prilnar reflector is used as the concentrator 50 and a secondary reflector 51 are provided, the secondary reflector 51 forming the beam path the front primary reflector 50 kinks and on a point at the apex of the primary reflector 50 located focal point 52 concentrated. At this point there is an opening iia Primary reflector which is so large that it can accommodate the receiving cone 55. in the The light guide is connected to the receiving cone 55 and extends over the light guide strany 56 conducts the energy to an energy converter (not shown).

The reflectors 35 or 50 and 51 according to FIGS. 2 and 3 can be circular as in the examples above, but also be designed in a parabolic cylinder shape. In this last case, in which the representations in FIGS. 2 and 3 show a cross section could represent, focal lines are formed, along which a series of receiving cones be arranged side by side.

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Claims (12)

P a t e n t a n s p r ü c h e 1. Solar system with an energy converter and at least one concentrator that directs the sun's rays onto a focal point in the focal plane concentrated, characterized in that between the focal point (15 - 17) and the energy converter (13) a coupling in the concentrated sunlight optical recording cone (15a -17a) and then a concentrated one Solar energy transmitting light guide (20-22) is provided. 2. Plant according to claim 1, characterized in that the light guide (20 - 22) made of quartz or a material with low attenuation for solar energy, in particular, there is polymethyl methacrylic. 3. Plant according to one of the preceding claims, characterized in that that the exit end (25) of the light guide (22) perpendicular to the irradiation surface (26) of the energy converter (13) directed and at a distance (27) from the irradiation surface is arranged. 4. Plant according to one of the preceding claims, characterized in that that several light guides (20-22) are provided, which over the irradiation surface (26) of the energy converter (13) are arranged regularly divided. 5. Plant according to one of the preceding claims, characterized in that that the focal point (37) of the concentrator (35) lies in the receiving cone (41). 6. Plant according to one of claims 1 to 4, characterized in that that the beam path of the concentrator (50) is bent by a secondary reflector (51) is, and that the focal point (53) of the secondary reflector in the receiving cone (55) containing vertex of the concentrator. 7. Plant according to one of the preceding claims, characterized in that that the entry plane of the Aufnahlnekegels (41) roof-shaped symmetrically is. 8. Plant according to one of the preceding claims, characterized in that that the receiving cone (41) is funnel-shaped. 9. Plant according to claim 8, characterized in that the receiving cone (41) is fully formed and made of quartz or a material with low attenuation for solar energy exists. 10. Plant according to claim 8, characterized in that the funnel-shaped Receiving cone (41) is hollow. 11. Plant according to claim 10, characterized in that the receiving cone (41) is made of metal. 12. Plant according to claim 10, characterized in that the funnel-shaped Receiving cone (41) is coated with a radiation-reflecting layer.