DE19633106A1 - Flat solar collector - has metal tub with several bridges formed by parallel arranged channels, and sealed by glass pane - Google Patents

Abstract

The collector includes an absorber fluid for the absorption of a global radiation. The collector consists of a metal tub (1) with several bridges (2) formed by parallel arranged channels (8). The metal tub is sealed by a glass pane (3) with a high transmission for the global radiation of the sun densely. An inlet opening and an outlet opening (5; 1) are provided, where the cross-section of the inlet opening (5) for the absorber fluid (6) stands in a relationship of 1 to 12 or 13 w.r.t. the cross-section of the channels. The metal tub and the glass pane are densely and durably pasted with each other. The absorber fluid is simultaneously a heat carrier fluid.

Description

The invention relates to a solar flat collector, colored by a Thermal fluid is flowed through, in which the global radiation is absorbed becomes.

Solar panels are used to collect the energy of the global radiation Absorb sun and usable thermal energy for water heating convert.

Construction variants are known in which the conversion of the Global radiation in thermal energy in a metallic, flat absorber with a suitable coloring or oxidation of the surface of the absorption body takes place. This coloring or oxidation of the surface takes place for maximum absorption of sunlight and minimum emission of the heated Collector (selective coating).

The absorption body or the absorption sheet is at regular intervals deposited with a pipe system that circulates with one union heat transfer fluid is filled and from the absorption body carried heat into a memory, e.g. B. transported a boiler. The submission of the Heat from the carrier liquid to the storage is via known Heat exchanger.

The disadvantages of these designs are that the heat is multiple must be transferred, d. H. from the coated surface of the absorber sheet into the sheet, inside the sheet to the pipe system, through the pipe wall into the heat transfer fluid.  

The speed of heat transfer is dependent on many factors of the ver depending on the material used. There are high surface temperatures and these are the cause of the heat losses caused by emission and the efficiency of the collector.

Another disadvantage is the uneven distribution of heat dissipation on the collector surface, because in the known pipe systems unevenly distributed Current conditions prevail.

DE-OS 26 08 302 describes a method and an apparatus for collecting solar energy, in which a heat transfer medium is contained in a chamber, which is connected to a circulation system with a heat exchanger, the heat absorption liquid having a high absorption capacity for heat rays in a wavelength range from 0.8 × 10 ^-3 to 400 × 10 ^-3 mm is used. The heat absorption liquid consists of dark colored water.

As a variant, it is also proposed to add an oil to the absorption liquid add, whose surface has a low reflectivity. Each The heat absorption element consists of flexible plastic films. The rear boundary layer of the absorption chamber has one of the suns radiation-facing reflection layer.

The disadvantage of this device is that a to the circulation system Subordinate heat exchanger, whereby heat losses are unavoidable. A plurality of interconnected hoses are arranged in chambers that thus represent a high technological effort.

From DE-OS 27 12 411 it is also known that the fluid medium itself as Ab use sorber by coloring the liquid used. The coloring is achieved by mixtures, batches, emulsions. It is also provided that that appropriate catalysts for the course of defined chemical reactions are added to the fluid medium.

No concrete constructive approaches are recognizable. Furthermore, the The disadvantage is that no measures against overheating are provided.  

In DE-OS 27 58 715 a solar collector is described which consists of a transparent collector and specially colored liquid.

The liquid is stained with inorganic salts, e.g. B. with chrome and Copper salts. The aim of the coloring is to absorb the sunlight under Be maintaining the wavelengths important for photosynthesis in order to use the Collector z. B. to ensure in greenhouses.

The disadvantage is a not inconsiderable design effort and a not optimal efficiency.

In DE 28 29 708, the subject of the invention is an absorber for a solar collector, which of a heat energy transport Liquid flows through and which is characterized in that the Liquid that transports heat energy is a liquid that absorbs solar energy Contains pigment dispersed and / or a dye dissolved.

Can be used as material that transmits at least 50% of the global radiation will:

Polymethyl methacrylate, polycarbonate, polystyrene, PVC, glass fiber reinforced Polyester resin, quartz glass, silicone rubber.

The liquid transporting heat energy can consist of water, a mixture from water and ethylene glycol, hydrocarbon alcohol, ether, ester, silicone oil and mixtures of these liquids.

The disadvantage is the lack of concrete constructive solutions and precautions Avoidance of overheating.

All known and described prior art devices the disadvantage; that there are no measures to avoid overheating are seen that he at standstill of the collector with full irradiation can be sufficient and adversely affect the long-term parameters of the collector impact. In addition, due to the occurrence of high standstill temperatures no use of inexpensive transparent thermal insulation (TWD) Plastic.

The invention has for its object a technologically advantageous Construction for a solar flat panel to create the global radiation is maximally absorbed, effective with little loss and overheating when the Prevents collector and damage in frost.

This object is achieved in that the absorber is the same is the heat transfer fluid and is colored so that the global radiation is immediately converted into heat energy, a residual absorption by a Reflective layer is done on the collector floor pan, being for the collector advantageously back to known components from radiator production is gripped.

Overheating, e.g. B. when the heat exchanger is at a standstill, are avoided by the absorber liquid when a maximum permissible temperature is reached drained to a depot in a regulated manner and when the temperature falls below a low temperature is pumped back into the collector. A control device is provided for this seen, the temperature-dependent valve and pump switches in this circuit.

In terms of construction, the collector consists of a known metal trough with parallel ones Bars and channels for the flow of the heat transfer fluid with a glass or plastic pane is covered tightly. Inlet and outlet The openings are arranged diagonally to each other in the metal tub. For isolation the metal tub is surrounded by thermal insulation.

In a constructive embodiment, one is above the glass or plastic pane Transparent thermal insulation (TWD) is provided with a cover film that covers the Efficiency of the collector increased significantly.

In a special design, the collector consists of a individual identical collector elements, which advantageously take the form of roof tiles have and are assembled to a desired collector size can. These designs can be used particularly advantageously in tiled roofs tie.

The inlet and outlet openings of the individual collector elements are so ge stalten and arranged that each with the inlet opening of a collector element  the outlet opening of another Kolektorelementes plugged together will.

The idea underlying the invention is described in the following Be writing using an exemplary embodiment, which is shown in the drawing is explained in more detail.

It shows:

Fig. 1 sectional view through the solar flat collector;

Fig. 2 representation of the flow conditions in the collector;

Fig. 3 is schematic diagram of the control circuit in case of overheating during standstill;

Fig. 4 sectional view of the collector acc. Fig. 1 with transparent thermal insulation;

Fig. 5 sectional view of a collector element in the execution of a roof tile;

Fig. 6 top view gem. Fig. 5 with inlet and outlet opening;

Fig. 7 schematic representation of the arrangement of several collector elements, for. B. roof tile shape;

Fig. 8 sectional view of a collector element in the execution of a roof tile with pipe connector;

Fig. 9 representation of a pipe connector;
The solar flat collector consists of a flat metal trough 1 with parallel webs 2 and channels 8 formed therewith.

The metal trough 1 is covered with a glass or plastic pane 3 and is connected in a watertight manner by means of a seal 4 and an adhesive connection. The webs 2 present in the metal trough 1 fulfill the task of flux guide bars in the collector and at the same time contribute to the mechanical stability.

The glass or plastic pane 3 is connected to the webs 2 in a point or line shape by riveting, gluing or melting.

The inlet opening 5 and outlet opening 7 of the collector are arranged diagonally to one another in the metal trough 1 and each open between the webs 2 .

The cross section of all channels 8 for the absorption and heat transfer fluid 6 is approximately 13 times larger than the cross section of the inlet and outlet openings 5 and 7 . With this cross-sectional ratio, the necessary residence time of the absorber in the global radiation is achieved in terms of flow technology.

The glass pane 3 is provided with an antireflection coating to improve the radiation transmission in a radiation direction.

To avoid heat loss, the collector 1 and 3 is inserted in a heat insulation 9 adapted to the shape of the metal trough 1 . On the side of the light incident on the collector, this is provided with a safety glass cover 10 .

The metal trough 1 additionally has a reflection layer 11 ; to reflect any residual radiation in the absorber liquid again.

From Fig. 2, the flow conditions of the absorber liquid in the collector can be roughly seen. The cross sections of the channels 8 are selected so that there is a sufficiently long dwell time for the absorber and heat transfer fluid in the radiation between the inlet opening 5 and outlet opening 7 .

In order to avoid overheating when the system is at a standstill, the absorber is pumped into a depot 12 not exposed to the radiation when it reaches a permissible maximum temperature ( FIG. 3) and is returned to the collector when required or when a low temperature is reached. To monitor this safety precaution, an electronic control device 13 is provided, which switches the valve 14 and the pump 15 . For this purpose, the temperature parameters of the collector and the hot water tank are evaluated.

In FIG. 4, in an advantageous embodiment of the collector between the glass or plastic disc 2 and the glass cover 10 is a transparent insulation (TWD) 16 is arranged, thereby increasing the efficiency of the collector.

For better integration of the collector in tile roofs, the inventive collector in tile form ( Fig. 5) has been developed, which thus represents a collector element that can be assembled in multiple arrangement to the desired collector size. The inlet opening 5 is designed as a sleeve and the outlet opening as a pipe socket.

In a further variant ( FIG. 8), the collector element has inlet openings of the same design at all corners, the connections between the elements being connected to one another by means of special raw connectors with a rubber seal ( FIG. 9). Inlet openings that are not required are closed with a stopper.

While the absorber flows through the cavity 17 , the upstream cavity 18 has the task of preventing convection losses.

From Fig. 6, the diagonal arrangement of the inlet opening and outlet opening in a brick element is clearly visible.

In Fig. 7 the areal arrangement of several brick elements is gem. Shown Fig. 5 and 6 to a common collector significantly. The inlet and outlet openings 5 and 7 are each provided with rubber seals, so that the individual NEN collector elements can be joined together tightly. For an advantageous areal laying of the individual brick elements, two different bricks are required, namely firstly the arrangement of the diagonal openings 5 and 7 from the top left and bottom right, and secondly from the bottom left and top right.

The invention has been described and illustrated using selected features been put. Of course, the invention is not based on this illustration limited, but rather all features alone or in any Combination, regardless of their summary in the claims, be used.

Claims (15)

1. Flat solar collector with absorber liquid for absorption of global radiation, characterized in that the collector from a metal trough ( 1 ) with a plurality of channels ( 8 ) arranged in parallel webs ( 2 ) be standing by a glass pane ( 3 ) with a High transmission for the global radiation of the sun is densely covered, an inlet and an outlet opening ( 5 ; 7 ) are arranged, the cross section of the inlet opening ( 5 ) for the absorber liquid ( 6 ) in a ratio of 1 to 12 to 13 to Cross section of the Flußleitkanäle ( 8 ) is and the metal pan ( 1 ) and the glass pane ( 3 ) are permanently sealed together and the absorber liquid speed ( 6 ) is also heat transfer fluid. 2. Flat solar collector according to claim 1, characterized in that the sorber liquid ( 6 ) is the solution of a dye and has an absorption of sunlight in the range of 300-3000 nm. 3. Flat solar collector according to claim 1 and 2, characterized in that the absorption liquid ( 6 ) is a colloidal dispersion and has an absorption of sunlight in the range of 300-3000 nm. 4. Flat solar collector according to claims 1 to 3, characterized in that the absorption liquid ( 6 ) contains additions of dispersions of graphite, clays or heavy metal sulfides. 5. Flat solar collector according to claims 1 to 4, characterized by an outlet ( 19 ) of the absorber liquid ( 6 ) in a depot ( 12 ) when reaching a permissible maximum or minimum temperature by arranging a temperature sensor ( 20 ) in the absorber liquid ( 6 ). 6. Flat solar collector according to claims 1 to 5, characterized in that a valve ( 14 ) and a pump ( 15 ) are arranged between the outlet ( 19 ) and depot ( 12 ), which are switched via a temperature-dependent control device ( 13 ) . 7. Flat solar collector according to claims 1 to 6, characterized in that when the control temperature is exceeded or fallen below via the outlet ( 19 ) and depot ( 12 ), a filling of the collector is controlled and the functionality of the collector is thus achieved. 8. Flat solar collector according to claims 1 to 7, characterized in that the collector over the glass or plastic pane ( 3 ) has a transparent thermal insulation TWD ( 16 ) which consists of a plastic. 9. Flat solar collector according to claims 1 to 8, characterized in that the metal trough ( 1 ) has a residual absorption effecting reflection layer ( 11 ). 10. Flat solar collector according to claims 1 to 9, characterized in that the collector has the shape of a translucent roof tile ( Fig. 5) and is integrated into a tiled roof. 11. Flat solar collector according to claims 1 to 10, characterized in that the inlet (S) and the outlet ( 7 ) in the roof tile ( Fig. 5) are arranged so that they are plugged with identical tiles to any size collector can be. 12. Flat solar collector according to claims 1 to 11, characterized in that the inlet (S) is arranged diagonally to the outlet ( 7 ) in the roof tile and any collector geometries can be realized. 13. Flat solar collector according to claims 1 to 12, characterized in that the tile-shaped collector consists of plastic or glass and the flow-through collector part ( 17 ) has a cavity ( 18 ) upstream. 14. Flat solar collector according to claims 1 to 13, characterized in that the diagonally arranged for the inlet and outlet connections ( 5 and 7 ) of the brick ( Fig. 5) are designed so that the inlet as a sleeve and the outlet are designed as pipe sockets. 15. Flat solar collector according to claims 1 to 14, characterized in that the brick at the corner points has inlet and outlet openings which are connected to pipe connectors ( 21 ) including rubber seals ( 22 ) during installation.