DE2830745A1 - Solar energy recovery system - uses sunblind slats reflecting and absorbing on their opposite sides - Google Patents

Abstract

The system recovers electromagnetic radiation energy, particularly from sunlight from behind the windows of buildings. It uses sunblind slats. The slats (11) absorb the radiation on one side (12), and reflect it on the other (13). They can be so arranged as to form convection currents flowing over their surfaces and into the room inside, and may be rotated about their lengthwise axes. The reflecting sides can be used to protect the room from heating or direct heat into it, and the slats can be of polished pure or platinised aluminium.

Description

The invention relates to measures for the production of electro = magnetic Radiant energy, especially solar or thermal radiation behind translucent Elements of buildings with the help of sun protection slats.

Combined sun protection and energy generation systems have been developed been. These provide that the sun protection slats from a heat transfer medium are flowed through and the heat energy to a storage and / or consumer system ab = lead. The disadvantage of such systems are flexible connections for the rotatable Storage of the slats and the amount of resin required for transport and the Storage of the heat transfer medium and the devices for heat dissipation the room air is required. The rigid connection of the slats with front and return lines, these must not be removed from the window opening. Of the The use of such systems is therefore very limited in residential and administrative buildings.

If the solar energy is used to heat room air, special air collectors are required, which are placed on roofs and communicate with indoor spaces via an air duct system. The air circulation is effected by a fan. Such systems are uneconomical because the Installation costs for collectors, duct system and fans are too high The installation of such systems requires extensive renovation work.

The invention has therefore set itself the task of the solar energy to obtain hardware for heating purposes with a minimal amount of hardware and to design it in such a way that that the device is particularly suitable for subsequent installation and equals early sun protection and thermal energy radiation protection for the interior, thus represents an energy saving and energy generation measure.

This object is achieved according to the invention in that the sun protection slats Radiation energy absorbing on one side and light and heat radiation energy reflecting on one side are trained.

The light and / or heat radiation energy reflecting training is a bright, but advantageously a selective coating or a Mirror for visible light and / or infrared radiation. The radiation reflective Education consists of painting, coating or mounting reflective foils. The radiation = absorbing training consists of one black coating, which are not subject to any special requirements, because the energy absorbed by emission and heat transfer or convection currents is to be released into the room air.

The lamellas are arranged in such a way that convection currents develop train and brush past the lamellar surfaces.

The slats are rotatably mounted about their longitudinal axis and accordingly the desired functionality with the reflecting side to the interior and rotate with the absorbing side facing the incidence of radiation. This will make the incident Radiation absorbed, converted into thermal energy and emitted. The emission shines on the reflective coated underside of the upper lamella and is supported by it radiated into the interior. The slats provide warmth to the inside of the room radiation protection, so that heat is radiated but not radiated. Of the The lamellar curtain acts like an energy trap. The diffuse radiation component, which radiates from the inside on the lamellas is reflected on the absorbing side, converted into thermal energy and fed back into the interior. The reverse is true for Alignment of the reflecting side of the lamella to the incidence of radiation is a good one Light and thermal energy protection given.

The slats are made of polished pure or plated with particular advantage Manufacture aluminum and are according to the static requirements and Arched around its longitudinal axis according to radiation geometry. The La = Mells can be trained and arranged in such a way that they act as a concentration system at the same time a concentrating system for solar energy generation can be used. One of the = like system is shown in patent application P.

The slats are to be arranged vertically or horizontally. The suspension the slat surfaces are made in the manner of a blind or a vertical slat blind and can be removed from the window opening by closing or pushing them away. The control of the blind according to the different modes of operation takes place via temperature sensor, computer program, light sensors or by hand.

A special embodiment of the inventive concept consists in the Arrangement of the slats in a double window, the box frame with at least a supply air and an exhaust air opening and in the manner of an air collector is usable. The supply air is in the lower part above the parapet as Um = air out drawn in from the interior or as fresh air from the outside.

In the upper part under the window lintel, the lamellar surfaces are used heated air is released into the interior for heating or into the exterior. (Fig. 2) There is also the possibility of ventilating the window in the manner of To equip bottom hung or tilt and turn windows. In fully air-conditioned buildings, this will be Penster element connected to a supply air and / or exhaust air duct and with a Air conditioning coupled.

(Fig. 4) The window element can also simply be used for reheating the circulating air can be used by sucking in the supply air from the interior and is released back into the interior.

This is particularly advantageous in open-plan offices, as it makes it in winter the temperature gradient to the window zones can be absorbed. This simplifies the function of an air conditioning system is very important. To get a build-up of heat under avoiding the ceiling, the natural convection cycle created by the Buoyancy of the heated air is created, turned around by the installation of a blower by sucking in air from above and expelling it from below.

The inventive design type of an air collector window "is especially in noise-protected apartments and when exposed to external smog or dust cheap, as the windows do not need to be opened and the fresh air above Can be drawn in through the roof or through a filter, which can be arranged in the air intake openings are. The blind results in an increased level of soundproofing, as the slats reflect the sound and as a result damping of the elastic suspension works.

Another idea that is essential to the invention is the training of the Slats for energy storage. This is done by making the slats made of a material with a high specific density, such as steel or concrete. It it is also possible to design the lamella as a fluid reservoir or latent reservoir. To train as a heat store, the lamella is on the shadow side with a See thermal insulation. The lamella is combined with the absorbent to dissipate heat Side turned to the interior. (Fig. 7) Another alternative is to use the To immerse the lamella in a liquid = medium to give off heat and to heat it. Such methods are particularly advantageous in the construction of greenhouses set. (Fig. 5) The exemplary embodiments serve to further explain the concept of the invention. It show: Pig. 1 shows the vertical section through an outer wall with a lamellar Air collector system Fig. 2 shows the vertical section through an air collector window Fig. 3.1 to 3.4 different modes of operation of the air collector = window Fig. 4 Scheme a warm air system Fig. 5 greenhouse with storage basin Fig. 6 two-layer Slats Fig. 7 Concrete slats with heat storage Figure 1 shows the cross section through an outer wall with the sun protection blind 10 according to the invention. The slats 11 are absorbent on the irradiation side 12 and on the one facing the interior Page 13 reflective, which turns the blind into an energy trap0 The energy radiated onto the blind is reflected into the interior and can no longer escape, due to the heated ambient temperature of the lamellas 11 there are convection currents14 that draw the heat energy from the window opening transport away into the interior. Through a light-reflecting side 13 is Despite the shading of the interior, a high level of daylight tient guaranteed, In this example the slats are moved downwards and serve as a radiator. This is useful if the slats have a certain storage capacity and are made of steel, for example. A horizontal arrangement the slats, as in this example, is of particular advantage on a south facade. On a south-east or south-west facade it is because of the azimuth angle of the sun cheap to train the slats in the manner of a vertical lamella lenstores.

2 shows the cross section through a double window element 17. The blind according to the invention is located between the outer window 18 and the inner window 19 10 arranged. This can be pushed together upwards and is powered by an electric motor (20) served. The double window sits in a box frame, the one above and one below is provided with opening slots 21, 22, 23 and 24 on the inside and on the outside, through which air is sucked in from below and released upwards. The warmed Air is guided upwards on the inside 19. The outer window (18) is to to prevent the air from cooling down, designed as double glazing.

Figures 3.1 to 3.4 show schematically different modes of operation of the collector window. This example assumes a lamella arrangement, as is necessary when the lamellae on the irradiation side 13 reflect = are designed in an animal-like manner and are used as a concentration system.

The starting position when using the slats as a concentration system Figure 3.1 shows. The radiation energy is transferred to a receiver located in front of the facade reflected0 This results in the inclination of the individual slats, due to the density Lamella arrangement results in a blocking portion 26, which is converted into thermal energy and creates a job. As a result of the buoyancy is through the lower opening 22 Air sucked out of the interior and discharged through the opening nunp: 24. The ones from Separation space to the me n1it lp radiated energy 27 is absorbed and also dissipated, so that with the help of solar energy a certain cooling the window front is reached. In this particular example, = takes over the window thus the following functions: 1. Sun protection 2. Concentration of the radiation energy in a receiver = system - utilization of the generated radiation energy 3. ventilation of the interior and suction of the warm air in the window zone 4. Discharge of the heat radiation from the interior Figure 3.2 shows a fundamentally different function; Lons = wise. The lamellas are aligned with the absorbing side 12 to the incidence of radiation and with the reflective side 13 to the interior. The radiant energy generated from outside is absorbed, converted into thermal energy and used to heat the interior the opening drained. The supply air is sucked in through opening 21 and / or 22 and formed from circulating air and / or fresh air. There is one through opening 21 and 22 Cross ventilation takes place without heat energy losses occurring. The collector window thus offers the possibility to ventilate the room draft-free, without the convection cycle disturb. In this application example, the collector window takes on the following Features: 1. Radiation protection 2. Heater 3. Heat radiation protection This application is particularly suitable in winter with diffuse radiation.

Figure 3.3 shows the possibility to ventilate the room and the warm air sucking in the inside air in the collector window with the same slat orientation is further heated and pressed through opening 24 to the outside. The collector window So works in the manner of a pump, through the cool air of a shaded one Is sucked in on the building side.

In this application example, the collector window serves as the first protection against radiation 2, suction device for coal air In the application example figure 3.4 the 'night position' is shown, in which the heat energy in the upper part of the room is stowed and cross ventilation takes place over the parapet.

The collector window has the capability of opposing punctures such as heating, cooling or shading, exercising exposure and setting by solar energy fed respiratory organ of a building. Through the collector window, the used for falling direct and diffuse radiation energy. When using the blind as a concentration system is also = the hot water for the domestic water supply or a solar air conditioning system provided. This is a completely new concept created for the air conditioning and energy supply of a building.

Figure 4 shows an application example for the air conditioning of a Building with the help of a collector window wall. The one heated on the south side 30 Air is sucked off above the blind 10 in air conditioning ducts 31 and on the Shaded side 29 supplied to lying rooms. The dashed lines 33 show the exhaust air, which is cleaned in a washing system 32 and fed into the collector window wall 17 is supplied again as circulating air 34, however, such an air-conditioning system is only possible as additional heating.

Figure 5 shows a greenhouse. The slats 44 are for heat storage formed and are heated up by the incidence of radiation. As well as the sun radiates on the opposite side of the greenhouse, the slats 44 are on rails 39 driven into water basins 35 which are arranged below the plant basins 36. There is an exchange of heat to the water. The warmth rising from below 37 and the heat energy emitted by the fins 44 is reflected by the the back of the lamellas is blasted directly onto the plants and enables a for the growth favorable thermal radiation. It should be emphasized that as a result of the reflective Slats = there is a high daylight quotient on the sides. With reference to the Application of the invention in greenhouse construction should also be mentioned that the simple slats as in Fig. 1 be = written, especially with top heating very are to be used economically. The slats are provided with rollers at the ends and stored in the I-profile roof racks.

Fig. 6 shows a different type of lamella formation. The lamella: ind two-layer and shaped in such a way that the convection currents 16 have a favorable contact surface for heat absorption. The one facing the interior Layer 13 is again made reflective.

FIG. 7 shows a further possibility of forming the lamellae 44. This is a horizontal section.

The slats 44 are made of concrete and around a vertit kale Axis rotatably mounted. The opposite side to the incidence of radiation is with Distance through reflectors 45 ver = disguises, so that a heat storage effect in the concrete slats takes place.

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Claims (26)

USE OF SUN SHOE SLATS FOR SOLAR ENERGY. PATENT CLAIMS : The invention relates to measures for the generation of electromagnetic radiation energy, in particular solar or thermal radiation behind translucent elements from Buildings with the help of sun protection slats, characterized in that the Sun protection lamellas (11, 43, 44) absorbing radiation energy on one side (12) and a tig light and / or heat radiation energy reflecting (13) are formed. 2. Plant according to claim 1, characterized in that the slats are arranged so that # onvektionsströmun = gene (16) can form, the Brush past the lamellar surfaces and flow into the interior. 3. Plant according to claim 1, characterized in that the slats are rotatably mounted about their longitudinal axis. 4, use of the heat-reflecting louvre sides (13) as thermal energy radiation protection for the interior. 5.Use of the heat-reflecting lamella sides (13) as thermal energy radiation protection. 6. Manufacture of the lamellas from polished pure or plated Aluminum. 7. Plant according to claim 1 and 3, characterized in that the slats (11) are arranged and designed so that they can be used as a concentration system concentrating plant to solar energy are usable and the radiant energy reflect into a receiver located in front of or behind the facade. (Fig.3.1) 8, system according to one or more of the preceding claims, characterized in that that the lamellas according to the requirements of the statics and the beam geometry are curved around their longitudinal axis. 9. Plant according to several of the preceding claims, characterized in that that the slats (11) are arranged vertically or horizontally. 10. Plant according to claim 10, characterized in that the suspension the slats (11) takes place in the manner of a blind or a vertical slat blind. 11. Plant according to claim 10, characterized in that the blind or the vertical slatted blind via temperature sensors, computers or sensors is controlled. 12. Plant according to several of the preceding claims, da = characterized by, that the slats (11) are arranged between a double window (17) and the Space between the windows with at least one supply air and with at least one Exhaust air opening is provided (Fig. 2) 13. Plant according to claim 12, characterized in that that the supply air in the lower part of the double window element (21, 22) from the interior and / or outside space and sucked in in the obe ren part (23, 24) in the inside and / or Outside space is given. 14. Plant according to claim 13, characterized in that the supply air and exhaust air openings with the help of ventilation blades in the manner of tilt or tilt and turn windows be effected. 15. System according to one or more of the preceding claims, characterized in that the air heated on the lamellas (11) is in air ducts (31) is sucked off and conveyed to a place of use. (Fig. 4) 16. Plant after Claim 12, characterized in that filters are arranged in the air inlet openings are. 170 Plant according to claim 12, characterized in that the air circulation takes place in the double window element (17) by a fan and the heated air is discharged in the lower part (21, 22). 18. Plant according to one or more of the preceding claims, characterized in that the lamellae (44) are designed kör = perhaft and for energy storage. (Fig. 7) 19. Plant according to claim 18, characterized in that that the energy storage in the Lemellen 44 by a liquid = keitsmedium or takes place in a solid and is stored as heat = energy and / or chemical energy will. 20. Plant according to claim 18, characterized in that the lamellae (44) are designed as latent storage. 21. Plant according to claim 18, characterized in that the lamellae (11, 44) are made of steel and / or concrete. 22. Plant according to claim 18, characterized in that the energy-storing Lamella (44) on the shadow side designed to be heat-insulating and of heat insulation and / or a reflective surface / is surrounded. (Fig. 7) 23. Plant after a or more of the preceding claims, characterized in that the lamellae (43) two or more layers and the individual layers for absorption, Heat emission, reflection and convection currents are shaped favorably. (Fig. 6) 24. Plant according to several of the preceding claims, da = characterized by, that the energy-storing lamella len (44) for the purpose of heat dissipation with their absorb = the side to be turned to the interior. 25. System according to one or more of the preceding claims, characterized in that the heated lamellae for dissipating heat into a liquid medium be dived. (Fig. 5) 26. Use of the lamellas in greenhouse construction