EP1954989A2

EP1954989A2 - Solar collector comprising a heat engine

Info

Publication number: EP1954989A2
Application number: EP06805520A
Authority: EP
Inventors: Jürgen UEHLIN
Original assignee: Durlum Leuchten GmbH Lichttechnische Spezialfabrik
Current assignee: Durlum Leuchten GmbH Lichttechnische Spezialfabrik
Priority date: 2005-11-15
Filing date: 2006-11-14
Publication date: 2008-08-13
Also published as: WO2007056985A2; DE112006003683A5; DE102005054366A1; WO2007056985A3; US20080230111A1

Abstract

The invention relates to a method for generating energy from concentrated solar radiation by means of photovoltaic and thermally usable solar cells in which the absorbed heat radiation evaporates a fluid which drives a turbine connected to a generator.

Description

(Solar collector with heat engine)

The present invention relates to a solar collector with photovoltaic and thermally usable solar cells, which is equipped with at least one concentrating reflector.

Such photovoltaic modules are used for the direct conversion of solar radiation into electrical energy or heat.

The spectrum of electromagnetic radiation emitted by the sun can be used only to a small extent for conversion into electricity because the sensitivity of the voltaically acting solar cells is given only in the range of about 350 to 900 nm. The energy of the UV radiation lying below 350nm and the infrared radiation lying above 900nm causes the warming of the cells. At temperatures around -20 ⁰ C their efficiency is highest and from 80 ° C so low that the power production is no longer worthwhile. At even higher temperatures, the cells can be destroyed and these sizes are highly dependent on the type of solar cell. This problem is drastically worsened when the solar cells are operated with concentrated light. At a concentration factor above 10, on a clear summer's day, it only takes a few minutes to reach a destructive temperature. These cells must be cooled.

According to the prior art, the heat is either attempted to be dissipated via large heat sinks or to connect the solar cells or their carrier to a heat sink through which a coolant flows. It is also known to flow around the solar cells of a cooling medium to improve the heat transfer with a variety of problems in terms of corrosion and short circuit resistance occur and for the operation of the coolant circulation pump a considerable part of the electrical energy produced by the cells must be spent.

The object of the invention is to provide a method which is simple and inexpensive to produce and improves the efficiency of solar collectors equipped with it.

The object is achieved by the claim 1. Further ausgestaltende features are described in claims 2 and 3 and the dependent claims. By the present invention, the effective, combined use of global solar radiation by means of photovoltaic solar cells and solar thermal driven heat engines is possible. The spectral separation of the collected radiation is preferably but not exclusively so that the flat photovoltaic cells are irradiated as evenly as possible with the usable spectrum of them and the solar thermal cells line with the decoupled radiation component. The stronger the concentration of the thermal radiation and correspondingly narrow the thermally irradiated surface, the higher the achievable temperature and this proportional to the efficiency of the downstream heat engine. The decoupling of the photovoltaically usable radiation is preferably effected by means of partially transmissive spectral filter, which additionally leads to the advantageous effect that the photovoltaic cells remain relatively cool and the thermal radiation by means of optically active aids such as lenses, mirrors, reflectors, etc. on the solar thermal cells can be concentrated.

Another method to keep unwanted heat radiation from the solar cells is the spectral filtering of the incident radiation by means of a transparent coolant which wets or surrounds the cells at least in the irradiated area, converts the non-photovoltaic usable radiation into heat and transported in a heat exchanger cooled at least partially by evaporative cooling becomes . If the cooling medium is neither water nor water-like, for example monopropylene glycol or tripropylene glycol, this must be conducted in a closed container or circuit. If water is used as a filter and heat exchanger liquid, it can be fed to open evaporative heat load. The heat transfer fluid evaporated in the solar thermal cells must be condensed after work has been completed. This process takes place according to the invention predominantly in containers which can be cooled by open evaporation and which are preferably formed and / or carried at least in part by the collectors and / or solar cells or their supports. The heat extraction by open evaporation is several times greater than by convection or radiation.

If the reflector area is increased to increase the concentration factor, the usable cooling area is also increased at the same time. Since the sensitive surface of the solar cells or the reflective side of the concentrators are aligned with the sun, their back, which is in the shade, can be used as an evaporation surface or carrier of an evaporation device. The medium to be evaporated is water, preferably in the form of rainwater and / or tap water. This can evaporative substances, such as surfactants are added. The water is preferably supplied via the capillary action of the porous materials which are immersed in the liquid in the

5 a gutter, tub or similar collecting vessel is stored, which is preferably arranged below or / and above the evaporation devices. Additionally or alternatively, the evaporation devices can be sprayed with water, which is supplied to them by a pump or from the pipeline network with pressure. In order to increase the evaporation capacity, the evaporation area of highly porous

10 sem material which has a large surface area formed. Particularly suitable are felts, nonwovens, fiber mats, foams of organic and / or inorganic substances, preferably metal foams, baked pottery, sintered elements, ceramic plates and the like. Become evaporator with a few cm distance parallel or slightly conical

15 staggered mounted, creates a chimney effect which enhances the cooling effect. In lying arrangement of modules on an inclined surface, it is advantageous if a rear ventilation is present.

In the following, the invention will be explained in more detail by schematic exemplary embodiments. Show it :

Fig. 1 shows a cross section through a solar collector according to the invention.

The solar radiation 5 is directed by the reflector 6 onto the beam splitter 4, which disengages the thermally usable frequencies 8 in the UV and infrared range and directs them to the .5 thermally active solar cell 9, which evaporates directly or indirectly the heat carrier of the heat engine 7. The photovoltaically usable radiation 3 is converted into electricity by the solar cell 2, which is connected to a cooler 1. The reflector 6 connected to the heat engine 7 by means of the casing 12 is used as a condenser whose cooling capacity is favored by coating 11 having iθ porous and / or large surfaces and preferably having a dark color and which has a slightly evaporating liquid Water, wetted, is enlarged. The cooler can be connected by means of the casing 12 with the cooling chamber 10 of the reflector 6.

Claims

claims

1 . Process for the production of energy from concentrated solar radiation by means of photovoltaic and thermally usable solar cells in which the absorbed radiation 5 vaporizes a heat transfer fluid which drives a turbine connected to a generator with the electrical energy is obtained, characterized in that the cooling of the solar collector by open evaporation of water is effected.

.O

2. A method for generating energy from concentrated solar radiation by means of photovoltaic and thermally usable solar cells in which the absorbed radiation vaporizes a heat transfer fluid which drives a turbine connected to a generator with the electrical energy is obtained, characterized in that the condensation of the heat transfer fluid by open Ver

[5 evaporation of water is effected.

3. Process for the production of energy from concentrated solar radiation by means of photovoltaic and thermally usable solar cells in which the absorbed

^; Radiation a heat transfer fluid evaporates the one connected to a generator

.0 dene turbine drives is obtained with the electrical energy, characterized in that the cooling of the solar collector is effected by open evaporation of water on the dark side of at least the reflector.

4. Process for the production of energy from concentrated solar radiation by means of 25 photovoltaic and thermally usable solar cells in which the absorbed

Radiation evaporates a heat transfer fluid which drives a turbine connected to a generator is obtained with the electrical energy, characterized in that the condensation of the heat transfer fluid by open evaporation of water on the shadow side of at least the reflector 30 causes.

5. The method according to any one of the preceding claims, characterized in that the cooling effect is caused by open evaporation of water in porous material. 5

6. The method according to any one of the preceding claims, characterized in that the cooling effect is caused by open evaporation of water in porous material on the shadow side of the solar collector and / or concentrator.

7. The method according to any one of the preceding claims, characterized in that the cooling effect is caused by open evaporation of water in porous material.

8. The method according to any one of the preceding claims, characterized in that the cooling water wets the voltaisch effective solar cell first on the irradiated side and then the evaporation surface is fed.

9. The method according to any one of the preceding claims, characterized marked, that the cooling water first flows around the voltaically active solar cell and then the evaporation surface is fed.

10. The method according to any one of the preceding claims, characterized in that by spectral filter voltaically little or ineffective radiation is kept away from the photovoltaic solar cell to reduce the heat load.

11. The method according to any one of the preceding claims, characterized in that the cooling water is supplied by pressure.

12. The method according to any one of the preceding claims, characterized in that the cooling water is transported by capillary action.

13. The method according to any one of the preceding claims, characterized marked, that the cooling water tank is a self-filling rainwater tank.

14. The method according to any one of the preceding claims, characterized in that the cooling is constructed at least two stages and consists of a preferably closed primary circuit and open evaporation.

15. The method according to claim 10, characterized in that the cooling medium in the primary circuit is not water or water-like substance.

16. The method according to claim 10, characterized in that the cooling medium is equipped in the primary circuit with Spektralfilterfunktionen.