DE2850967A1 - SOLAR RADIATION RECEIVING SYSTEM - Google Patents

Description

The invention relates to an improved solar energy conversion system.

Various solar energy concentration and conversion systems are already known. Thereby becomes a central tower used at a height of more than 50 m around the mirror, i.e. H. Solar radiation reflectors, are distributed on the floor. These redirect the radiation to the upper end of the turin, on which a receiver for absorbing the radiant energy is arranged is. The receiver has essentially a tubular or other flow channel configuration, with radiation absorption surfaces heat a heat exchange medium and / or a working medium which flows through. the Reflectors on the ground follow the course of the sun and always direct the radiation towards the tip of the Turin. Typical arrangements of this type are z. Described in U.S. Patents 3,924,604 and 3,906,927.

As with all energy conversion systems, occur here too certain losses of the collected energy. Some of these losses are based on the fundamental laws of thermodynamics. Other losses are due to certain defects inherent in the equipment used. It was found that solar converters with a receiver of the type mentioned are subject to comparatively high heat losses. This heat loss come about through reflection from the isolation and through Radiation of a different kind from the receiver to the outside, d. H. out of the overall system. Of course, one strives to be at such systems affect the absorption properties of the receiver to maximize ^ as possible. Nevertheless, a considerable part of the radiation directed from below to the receiver is made up of the System reflected out. In addition, the black radiation from a device is typically stronger their absorption properties are better.

It is therefore the object of the present invention to

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degree and the effectiveness of solar energy conversion systems with one receiver and a variety of around the Arranged receiver and to improve the solar energy to the receiver directing reflectors.

In particular, it is the object of the invention to create an improved solar energy conversion system in which a receiver is arranged at the top of a tower and in which a large number of adjustable and positionable mirrors on the floor are arranged around the tower.

According to the invention, the upper part of the receiver of the solar energy conversion system covered with a screen, which preferably has a frustoconical shape and such · is arranged that from the reflector system to the receiver Solar radiation reflected and reflected back by the receiver is captured by this screen. The umbrella has one reflective surface and serves to reflect the radiation back to the receiver, where it is absorbed. The receiver has a surface that has a high emittance to maximize absorption. The recipient The screen surface facing it has a very low emittance in order to maximize the back reflection of the radiation towards the receiver. This radiation to be reflected back to the receiver has left the receiver due to the aforementioned residual reflection. Furthermore, due to its increased temperature, it is transmitted from the screen to the radiation by the receiver Receiver reflected back.

In the following the invention is explained in more detail with reference to drawings. Show it:

1 shows a schematic representation of an improved solar energy conversion system according to the present invention Invention and

Fig. 2 is a section through the screen of the system according to Fig.l.

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Fig. 1 shows the overall system in a schematic representation of the improved solar energy conversion system according to the invention. This comprises a central tower which has a receiver unit 11 at its top. These is designed to convert solar energy into thermal energy and heat a suitable liquid. The receiver unit 11 absorbs the solar energy and heats a working fluid contained therein and flowing through channels of the receiver 11. The heated liquid can enter into a heat exchange relationship with another liquid or it can itself be led down through the tower and are used in a power plant 12. These parts of the system are conventional in nature. These are essentially about the conversion of thermal energy into electrical energy. To utilize the thermal energy can also use a thermal buffer, which has been described by the applicant in earlier applications.

The solar energy is collected by a large number of reflectors 13, which are placed on the ground around the tower 10 in fields or rows are arranged. The reflector field can consist of a large number of platforms, which individual Wear reflectors and which follow the course of the sun. All of these reflectors direct the solar energy to the receiver 11 at the top of the tower 10. The tower can be 100 to Be 300 m high. The part of the energy conversion system described so far is of conventional type. The improvement according to the invention will now be described, namely a screen 20, which is like a hood at the top of the Receiver 11 is arranged on the tower 10. This screen and the structure of the tower 10 at the top are detailed shown in fig.

The screen consists essentially of a frame 21, the upper end of which has a cylindrical shape. This configuration is chosen mainly for the sake of convenience, particularly with a view to the positioning of the screen 20 at the upper end 15 of the

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Tower 10. Around this upper end 15 of the tower 10 are Channels and pipes 16 arranged, which the receiver 11 represent. As mentioned, a heat exchange medium flows through these tubes. They exhibit one to a great extent absorbent outer surface to collect solar energy on.

The screen has a frustoconical frame 22 which is similarly frustoconical on the inside formed reflector 25. The angle of the reflector cone is in the range of 60 to 120. Thus forms the screen reflector surface is at an angle to the tower axis of 3O to 6O. In a typical application, the The screen mirror has an apex angle of 90 °, so that the reflector surface is inclined at 45 ° to the nearest one Has receiving surface. In addition, the screen is like this arranged that its outer lower edge 23 is at least up to half the vertical dimension of the actual Receiver extends downward, d. H. over at least half the length of the tubes 16 down.

As mentioned, a reflective surface 25 is provided to achieve a strong mirror reflection. A part of Radiation is from the receiver 11 and in particular from the External surfaces of the pipeline parts not absorbed. Rather, this radiation is subject to a considerable extent the mirror reflection and / or the diffusion reflection. This reflected radiation is made up of the reflective Area 25 of the screen 20 captured. Generally speaking, the mean direction of radiation should be that of the reflector system 13 upward reflected radiation (in any vertical plane through the -axis of the tower and the cylindrical receiver) have such an angle of incidence relative to the receiver that a reflected component of this central ray has an angle of incidence on the screen of about 90. Hence this reflected radiation

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reflected back to about the same location of the receiver 11, from which the radiation was reflected. In this way, only a very small fraction of the amount escapes from the recipient reflected solar radiation from the system. Hence will any reflected and unabsorbed by the receiver 11

and

Radiation directed towards / from the screen through mirror reflection sent back to the recipient.

The receiver 25 can be made of highly polished steel. A balance has to be achieved between structural cohesion (strength) and thermal stability on the one hand and the highest possible reflectivity on the other. It has been observed that the screen temperature rises rapidly with the screen reflector emissivity and, given an emissivity (ratio of the emitted radiant energy to the radiant energy) for an ideal black body of the same area and temperature (of 0.2), is on the order of 150 ^° C . Such a screen is extremely effective and reduces the heat losses of the receiver system by around 30% overall.

It should be noted that a considerable amount of radiation leaks from the receiver and parts thereof. This is based on the fact that the surface of the receiver naturally covers the widest possible spectral range for solar energy has a high absorption capacity. On the other hand, the receiver parts themselves get quite hot. Due to the law of radiation from a black body, these heated, highly absorbent surfaces radiate Very strong receiver, especially in the infrared range. Also a significant part of this radiated Energy is sent back to the receiver through the reflector of the screen.

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Finally, it should be noted that the screen also loses heat due to heat conduction processes between the hot receiver parts and the surrounding atmosphere reduced. A convection flow is created through the reflector surfaces the air is considerably reduced and the more or less stagnant air under the screen becomes quite hot. As a result, the effective temperature gradient becomes in the vicinity of and from the outer surface of the receiver Parts are reduced, which in turn reduces heat losses to the environment.

The present invention is not limited to the embodiment described. You can z. B. arrange the floor reflectors so that they do not completely surround the tower. You can z. B. do without reflectors on the south side of the tower. In this case, the receiver 11 does not have to have any south-facing tubes 16 and the ¹ screen does not have to have a reflector surface in this area.

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Claims (8)

PATENT CLAIMS / Λ.) Solar radiation conversion system with a receiver for the absorption of solar energy and a reflector system for deflecting the solar radiation towards the receiver, characterized in that a screen (2.0) is arranged on the receiver (11) in such a way that it receives the signals from the receiver (11) intercepts reflected radiation and sends it back to the receiver 11 by mirror reflection. 2. Solar radiation conversion system according to claim 1, characterized in that the receiver (11) has a cylindrical Has overall configuration and is arranged in an elevated position and fully or partially of reflectors (13) of the reflector system arranged on the floor is surrounded and that the screen (20) above the receiver (11) has a frusto-conical shape. 3. Solar radiation conversion system according to claim 2, characterized in that the apex angle of the frustoconical Screen is in the range of 60 to 12O. 4. Solar radiation conversion system according to one of claims 1 to 3, characterized in that the The screen (22) extends downward to a point which is more than half the length of the receiver (11) below dom the upper end of the receiver (11). 5. Solar radiation conversion system according to one of claims 1 to 4, characterized in that the screen (2O) a reflective surface (25) made of polished Has steel. 6. Solar radiation conversion system according to one of claims 1 to 5, characterized in that the screen (20) 909823/0843 ORIGINAL iHSPECTBD surrounds the receiver (11) but is open in the region of the radiation path of the reflector system (13). 7. Solar radiation conversion system according to one of claims 1 to 6, characterized in that the receiver (11) is arranged at the upper end of a tower (10) and that the screen (20) is arranged at the upper end of the receiver (11) is. 8. Solar radiation conversion system according to one of claims 3 to 7, characterized in that the screen (20) has an apex angle of about 90. 809823/0643