DE3524509A1 - Sun collector composed of absorption elements - Google Patents

Abstract

The intention of the invention is to improve the cost-performance ratio of solar absorption systems, to increase their range of applications and to ensure that they can be fitted to a roof in a visually appropriate way with the minimum degree of expenditure. In order to achieve these aims, it is proposed according to the invention that the collector system be formed of transparent double-hose elements. The heat absorption is effected by means of a suitable strip-shaped absorption element which is inserted into the hose and divides the hose into an upper and a lower channel, a connection being formed between the channels at one end of the hose. The heat which is produced in the middle of the hose is conducted away by a transparent heat-transporting medium which flows through the hose according to the counterflow principle (Fig. 2). In order to increase the range of applications of the solar system, the absorption element can be coated on its upper side with photo-sensitive cells, as a result of which a combined generation of heat and electrical current is possible. Since the flexible hose elements are easy to mount they are highly suitable for retrofitting.

Description

The invention relates to a solar collector from individual Absorbent elements that have a corresponding absorption contain body that is surrounded by a heat transfer medium and the incident solar energy in heat and electrical Electricity - or alternatively one of the two types of energy - converts.

Solar panels are used to convert solar energy used in heat or electrical current.

The generation of electrical energy has so far for cost reasons and because of conspicuous assembly devices not enforced.

When converting solar energy into heat by known Solar collectors are similar to a wide spread Factors in the way.

Constructions are used that are of a heat have absorbent bodies through which the carrier medium flows, wherein the radiation absorption takes place on their surface and the heat generated inside to the heat transfer medium medium is delivered.

To keep efficiency low, i.e. the radiation externally to a large extent, it is imperative the absorption body in elaborate, visually striking and to integrate expensive housings.

There is no housing and the absorption body e.g. as in DE-GM 79 32 797 from a roof shown black finned tube, so reduced the small Temperature increase the possible use on the low temperature range.

The technical improvements in terms of the cost factor and favorable installation conditions for solar collectors therefore in the direction of transparent tube absorption body to use that of colored absorption liquids  be flowed through. (DE-33 05 838 A1).

The radiation energy is only inside the absorber tion body in heat energy, which is a significant An increase in efficiency and a housing makes redundant.

The same effect is achieved with transparent plastic hoses achieved by a colored heat transfer flow through medium (DE-30 32 096). Nevertheless, the devices mentioned have considerable evidence split up.

So the absorption liquid is in when leaks occur the plant either for environmental reasons, or at least problematic in terms of pollution of the building. There is frost especially when using tube absorbers damage caused by the freezing absorption liquid cannot be excluded. Will be a trade for frost protection usual antifreeze is used, e.g. Ethanediol, has this results in the disadvantage of toxicity.

In addition, difficulties arise after own experiments with colored absorption liquids in relation to color deposits and changes on the vessel walls. Is this happen, the efficiency of the system and one decreases hardly feasible cleaning action would be necessary. The previously known systems also make one clear recognizable foreign bodies on the roof surface. Even when hoses or tubes run parallel to each other one end are connected by a transition piece so that The supply and return lines are on one side of the roof, are the tubes or hoses recognizable as such and become felt as not belonging to the roof structure. Ultimately, the systems described are based on the generation of Limited heat and not in cloudy weather conditions more effective so that other heat sources are used have to.  

The invention is therefore based on the object of Benefit ratio of solar systems, with a good effect degree, to improve their application by a combined generation of electrical energy and heat increase energy and a mounting option with minimal technical effort and good optical adaptation to the Ensure roof structure.

The tasks are solved according to the invention by that the individual absorption element consists of a transparent, flexible, against UV radiation and the heat transfer medium stable plastic hose.

The peculiarity of the invention is the fact that in inserted a strip-shaped absorption body into the hose ben, whereby an absorption element is formed, which in one overhead and an underlying channel is divided. The absorption body is dimensioned so that it something is wider than the hose diameter, so the hose envelope deformed elliptically, the absorption surface the hose will cost almost the same amount of material favorably enlarged and there is an optically favorable flattening of the absorption element. The width of the hose is the respective roof structure customized.

This creates a connection between the upper and lower channel made that the hose at its lower end something is longer than the inserted absorption body and after is locked on the outside. This creates a together hanging double hose with a cover.

The conversion of solar energy into heat takes place exactly here in the middle of the tube on the absorbent body, taking on simple way the radiation is kept to a minimum. It is also advantageous that the heat transfer medium is transparent is and the absorption element in the countercurrent principle from flows through the lower to the upper channel, or vice versa. In the simplest case, the system is powered by water or air operated.  

With the system according to the invention, the effectiveness of transparent, colored absorption liquids flowed through absorbers after own experiments exceeded. The inventive construction of the absorption elements can also be opened on the supply and return lines one side of the roof, preferably on the upper part of the roof to install. The supply and return line can also be used consist of a double hose divided into two chambers.

The connection of the absorption elements with the forward return Cable is made of flexible, transparent or colored Plastic hoses made according to claim 5 in the Absorbent elements are glued in and drilled over Rubber connectors inexpensively with the forward return line are connected.

Since the connecting hoses are correspondingly thin, they are passed through the ridge elements, so that the horizontal flow return line inside of the roof.

So that only the flat absorption elements on the Roof, in the recesses of the roof tiles or panels relocated. Since most roofs are also vertical Having structural elements is an inconspicuous, optical well adjusted arrangement achieved. The elements can be fasten by gluing or with clamps, almost any roof can be retrofitted at low cost.

A particular advantage of the invention is that that with all described features of the system, a combined heat and electrical energy production is possible. The absorption body in the hose element coated on the top with known photocells, this way they are protected against environmental influences necessary cabling runs orderly, without additional effort inside the elements and it can heat and electricity can be obtained.  

Retrofitting an existing system with Photocells are possible at any time.

The heat from the sun on the photo cells are discharged through a heat transfer medium.

In this context, the cheapest is with one transparent, gaseous medium worked, in the simplest Case with air. With an open system e.g. by Pre-warmed air from the roof interior sucked in, passed over the absorption body and the Fed to consumers. As a favorable side effect occurs a cooling effect on the photocells, a problematic one This prevents heat build-up on the electrical elements and prevents a drop in electrical power. Should the combined generation of electricity and heat Heat production can be increased, so the absorption element laid on short spacers and the roof surface in the area of the element with a color reflective layer adapted to the roof. In this way, irradiation of the underside of the Absorption element reached.

The heat transfer to the heat transport medium is increased if the lower hose duct is air-permeable with a dark colored absorption granulate is filled.

With a combined heat and electrical generation Energy will be the area of application for solar systems in the future pregnant expanded and the possibility of use almost increased all year round.

Ultimately, in a system according to the invention Advantage to bear that if necessary work on the system can be carried out easily because the roof on the raised The roof tiles can still be walked on.  

An embodiment of the invention is in the drawing shown and is described in more detail below. Show it

Fig. 1: A top perspective view of an assembled solar panel from Absorptionselemen th

Fig. 2: A perspective view of two connected absorption elements

Fig. 3: An, with photocells absorption element a , in its side view b , in a perspective view

Fig. 1 shows a, mounted on the roof solar collector from individual absorption elements, in which a closed consumer is not shown. The absorption elements ( 1 ) run in the recesses in the roof tiles.

The connecting hoses ( 6 ) between the absorption elements and the pre-return line ( 7 ) are passed through the ridge and connected to the pre-return line inside the roof.

This arrangement shows the advantage of a good optical adjustment with a simple and inexpensive installation. The absorption elements are glued on or fastened by clamping brackets ( 16 ).

Fig. 2 shows sections of two connected Absorp tion elements ( 1 ) made of transparent, flexible plastic tubes ( 4 ) in each of which an absorption body ( 2 ) is inserted, which divides the elements into an upper and a lower channel ( 3 ).

At this end, the hose is somewhat longer than the absorption body and is closed off from the outside ( 5 ), so that a connection is established between the channels. The connecting hoses ( 6 ) between the absorption elements ( 1 ) and the forward return line ( 7 ) are glued into the absorption elements from the outside ( 8 ).

The connection to the pre-return line is made by drilled rubber plugs ( 9 ), which are glued into the connecting hoses and pressed or glued into the holes in the pre-return line ( 10 ).

The forward return line is also represented by a double hose divided into two chambers ( 17 ).

Due to the fact that the solar radiation penetrates the tube cover and the absorption takes place in the middle of the tube on the dark colored absorption body, the radiation to the outside is kept low in a simple manner. An unproblematic, transparent medium ( 13 ) is used for the heat transfer, which flows through the absorption body from bottom to top in the countercurrent principle.

In the simplest case, water or air is used works.

Fig. 3 shows an absorption element for the combined Ge win of heat and electrical current.

To generate electricity, the absorption body is coated with known photocells ( 15 ). In order to increase the heat output to the preferably gaseous, transparent medium, the lower tube channel is filled with dark-colored absorption granules ( 14 ).

The hose can be mounted for radiation from below on short spacers ( 18 ) via a reflective roof coating ( 19 ). The heat transfer medium cools the photocells at the same time, which improves their efficiency.

Claims (16)

1. Solar collector from individual absorption elements, for converting solar energy into heat and electrical energy or optionally one of the two types of energy, characterized in that the absorption element ( 1 ) consists of a transparent plastic tube, which by an inserted, strip-shaped absorption body ( 2 ) in two channels ( 3 ) connected to each other at one end of the hose are divided. 2. Solar collector made of absorption elements according to claim 1, characterized in that the tubular casing ( 4 ) consists of a transparent, flexible plastic that is stable against UV radiation and against the corresponding heat transfer medium, and that the inserted absorption body ( 2 ) is somewhat wider than the diameter of the tube is, so that this is flattened and widened in an ellipse and the resulting tension causes the upper chamber to be sealed against the lower hose ( 3 ). 3. Solar collector of absorption elements according to claim 1, characterized in that the absorption body ( 2 ) at one end of the hose is somewhat shorter than the hose in order to establish a connection between the upper and lower hose channels, the hose being fixed or removable at this end is closed on the outside ( 5 ). 4. Solar collector from absorption elements according to claim 1, characterized in that the hose connection ( 5 ) is provided at the lower end of the elements with a Auslaufvor direction for emptying the collector system. 5. solar collector of absorption elements according to claim 1, characterized in that the connections ( 6 ) between the absorption elements and the front-back run line consist of flexible, transparent or colored hoses, with a diameter that allows the connecting hoses in the chambers of the absorption insert elements and glue them firmly and tightly into the absorption element with plastic ( 8 ). 6. Solar collector from absorption elements according to claim 1, characterized in that the absorption element ( 1 ) is manufactured during manufacture as a split into two chambers, transparent double hose, the partition being formed depending on the absorption project and the connecting hoses in the same position in the manufacture to be moved out with. 7. Solar collector from absorption elements according to claim 1, characterized in that the forward-return line ( 7 ) consists of a double hose divided into two chambers. 8. Solar collector made of absorption elements according to claim 1, 6, characterized in that in the connecting hoses pierced rubber plugs ( 9 ) are glued and these are pressed into the bores ( 10 ) of the pre-return line provided for this purpose, or in that the connecting hoses the holes of the pre-return line are glued. 9. Solar collector made of absorption elements according to claim 1, characterized in that the forward-return line is laid in the roof interior ( 11 ) and which connect the hose lines through the ridge elements ( 12 ). 10. Solar collector made of absorption elements according to claim 1 characterized in that the absorption elements glued to the roof tiles or panels or be fastened by clamps. 11. Solar collector made of absorption elements according to claim 1 characterized in that the absorption elements for irradiation of the lower channel on short Spacers are laid and the roof surface in the area of the absorption elements with a color the roof surface adapted reflection material be is layered. 12. Solar collector of absorption elements according to claim 1, characterized in that the absorption element is made of a transparent, flat plastic tube with an elliptical cross section and is divided in the middle according to claim 1, 3 , by an absorption body. 13. Solar collector of absorption elements according to claim 1, characterized in that for the exclusive heat recovery of the absorption body ( 2 ) consists of a dark colored, or color-matched to the roof material. 14. Solar collector from absorption elements according to claim 1, characterized in that the absorption elements for heat emission from a transparent liquid speed ( 13 ) or transparent gas are flowed through, where the collector system with the consumer represents a closed system. 15. Solar collector from absorption elements according to claim 1, characterized in that the collector system is an open system, the absorption elements flowing through from ambient air and the hose channels are filled with a dark colored absorption granulate ( 14 ) for better heat dissipation. 16. Solar collector of absorption elements according to claim 1, characterized in that the absorption body for the production of electrical energy on the top with photocells ( 15 ) are coated, have a dark color on the underside and flows through from the heat energy from a transparent heat transport medium are, preferably according to claim 15, in which case only the lower hose chamber is filled with absorption granules.