WO2024260842A1 - Flat collector - Google Patents

Abstract

The invention relates to a flat collector (10) comprising a base plate (12), side walls (14, 16, 18, 20) surrounding the base plate (12) and at least one at least partially transparent cover panel (22), which are detachably or non-detachably connected to one another and form at least one reaction chamber (24), wherein at least one intermediate panel (30) is arranged within the reaction chamber (24), dividing the reaction chamber (24) into at least two sub-chambers (26, 28) and being at least partially transparent, wherein the intermediate panel (30) is arranged within the reaction chamber (24) in such a way that air circulation is made possible within the reaction chamber (24), within the sub-chambers (26, 28) and between the sub-chambers (26, 28).

Description

flat collector

Description:

The present invention relates to a flat collector according to the features of the preamble of claim 1.

It is known that clean, desalinated water can be obtained from seawater using solar heat in special flat plate collectors called "solar stills". This also applies to brackish water or water contaminated with non-volatile substances, or water with a very high salt concentration, which is used, for example, as a liquid sorbent in air dehumidifiers or atmospheric water generators. For the sake of simplicity, the description of the present invention refers to salt water.

In a "solar still" collector, the salt water is heated on the base plate and partially evaporated. Desalinated water condenses on the transparent cover plate of the collector. The plate is mounted at an incline so that the desalinated water collects on the underside and can flow out of the collector through an opening. The salt water flows into the collector through one or more openings or pipes and out again through one or more openings. The collector tray is so deep or the salt water level is so low that the salt water does not come into contact with the upper plate or the area of the collector where the desalinated water is collected. Flat plate collectors, namely so-called "Solar Still" collectors according to the state of the art, have the disadvantage of low efficiency, i.e. a low production rate of desalinated water with a given solar radiation.

It is therefore an object of the present invention to provide a generic flat collector which ensures a high efficiency and thus a high production rate of desalinated water.

To solve this problem, a flat collector with the features of claim 1 and a system with the features of claim 9 are used. Advantageous embodiments with expedient further developments of the invention are specified in the subclaims, wherein advantageous embodiments of the flat collector are to be regarded as advantageous embodiments of the system and vice versa.

A first aspect of the present invention relates to a flat collector comprising a base plate, side walls enclosing the base plate and at least one at least partially transparent cover plate, which are connected to one another detachably or non-detachably and form at least one reaction chamber, wherein at least one intermediate plate is arranged within the reaction chamber, which divides the reaction chamber into at least two sub-chambers and is at least partially transparent. According to the invention, the temperature difference between the base plate and the upper, transparent cover plate is increased by slowing down the heat transport, in particular the heat convection, between these two elements. According to the invention, a transparent intermediate plate is installed in the space between the base plate and the upper cover plate in such a way that the air circulation between the base plate and the upper cover plate is not prevented, but is slowed down. The intermediate plate is arranged within the reaction chamber in such a way that a Air circulation is possible within the reaction chamber, within the sub-chambers and between the sub-chambers. Overall, the temperature within the flat collector and in particular the temperature difference between the base plate of the collector and the transparent cover plate is increased, resulting in a corresponding improvement in efficiency. This effect is even more pronounced in water with a high salt concentration. With a higher temperature difference, a larger proportion of the heat transport between the base plate and the cover plate consists of latent heat convection, i.e. the transport of water from the liquid state (on the ground) to the gaseous state (in the collector housing) and then back to the liquid state (condensation on the cover plate).

In advantageous embodiments of the flat collector according to the invention, an area of the intermediate plate is smaller overall than an area of the base plate and/or an area of the cover plate. This ensures that free spaces remain open within the reaction chamber, which enable air circulation. The areas of the base plate, the intermediate plate or the cover plate can also all be the same size. The decisive factor is that the remaining reaction chamber is large enough to enable air exchange between the sub-chambers. For example, the side walls of the flat collector could also be "bent outwards" to enable air circulation. It is also possible for the intermediate plate to have at least one opening. This also ensures sufficient air circulation within the reaction chamber. The intermediate plate can be arranged approximately parallel to the cover plate within the reaction chamber. It is also possible for the intermediate plate to be dimensioned in such a way that one end of the intermediate plate lies above a drainage channel formed in the reaction chamber for a liquid desalinated and/or demineralized by means of the flat collector. Advantageously, any liquid or water drops that may fall from the upper cover plate fall down, are caught by the intermediate plate and guided to the drainage channel. The term "drainage channel" is understood to mean any line device that is suitable for conducting liquids. Furthermore, the side walls and/or the intermediate plate can have at least one adjustment device and/or at least one adjustment grid for variable setting of a distance between the intermediate plate and the cover plate. The convection can thus advantageously be reduced to the desired level. This is achieved by choosing the appropriate distances between the base plate and the intermediate plate or between the intermediate plate and the upper cover plate. The smaller the distance, the greater the flow resistance, the smaller the convection and the higher the temperature difference. If the distance is too small, however, the collector will have a higher temperature and thus a higher energy loss through thermal radiation. The adjustability, however, reliably prevents this. Finally, the intermediate plate and the cover plate can be made at least partially of glass, plastic or a combination of these materials. Other materials and material combinations are also conceivable.

A second aspect of the invention relates to a system for desalination and/or demineralization of liquids comprising at least one flat collector according to the first aspect of the invention. This makes it possible to produce improved, in particular higher yields of desalinated and/or demineralized liquid. Further features and their advantages can be found in the descriptions of the first aspect of the invention, with advantageous embodiments of each aspect of the invention being regarded as advantageous embodiments of the other aspect of the invention.

Further advantages, features and details of the invention emerge from the following description of an embodiment and from the drawings. The features and combinations of features mentioned above in the description as well as those described below in the figure description The features and combinations of features mentioned and/or shown alone in the figures can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the invention.

It shows

Figure 1 is a schematic representation of an inventive

flat plate collector;

Figure 2 is a schematic representation of the inventive

Flat plate collector according to Figure 1 with partially transparent side walls; and

Figure 3 is a schematic side sectional view of the flat collector according to the invention as shown in Figure 1.

Figure 1 shows a schematic representation of a flat collector 10 comprising a base plate 12, side walls 14, 16, 18, 20 surrounding the base plate 12 and at least one at least partially transparent cover plate 22, which are connected to one another in a detachable or non-detachable manner and form at least one reaction chamber 24. An intermediate plate 30, which is arranged within the reaction chamber 24, divides the reaction chamber 24 into two sub-chambers 26, 28. The intermediate plate 30 is also at least partially transparent. The flat collector 10 also comprises an inlet opening 34 for the water to be desalinated, in particular sea water, but the flat collector 10 is generally suitable for the desalination and/or demineralization of liquids. The water to be desalinated is fed via the inlet opening 34 through openings 40 into the reaction chamber 24, in particular the lower part 26 (see also Fig. 2 and 3). At the end of the An outlet opening 36 for the remaining salt water is formed in the flat collector 10. In addition, there is an outlet opening 38 for the desalinated water in this area.

Figure 2 shows a schematic representation of the flat collector 10 according to Figure 1 with partially transparent side walls 12, 14, 16, 20. This makes the internal structure of the flat collector 10 easy to see. The arrangement of the intermediate plate 30 within the reaction chamber 24 can be seen. This creates the subchambers 26, 28 below and above the intermediate plate 30. It is also clear that the intermediate plate 30 is arranged parallel to the cover plate 22. The surface of the intermediate plate 30 is smaller overall than the surface of the base plate 12. This creates spaces and connecting channels between the lower subchamber 26 and the upper subchamber 28 for air circulation.

The way the flat collector 10 works can be described as follows: Firstly, it is advantageous to install the entire collector 10 with a slope, for example on a gable roof, so that the air circulation is achieved through natural convection. The heated and humidified air rises in the sub-chamber 26 between the base plate 12 and the intermediate plate 30. At the top of the collector, the air flows into the sub-chamber 28 between the intermediate plate 30 and the upper cover plate 22. There it cools down and flows downwards between the intermediate plate 30 and the upper cover plate 22. The air is dehumidified by condensation. At the bottom, the air flows back into the sub-chamber 26 between the base plate 12 and the intermediate plate 30 and the cycle starts again. Furthermore, it is clear that the intermediate plate 30 is also dimensioned such that one end of the intermediate plate 30 is located above a drainage channel 32 formed in the reaction chamber 24 for a liquid desalinated and/or demineralized by means of the flat collector 10. The drainage channel 32 ends in the drainage opening 38. In addition, a further drainage channel 42 is formed, which ends in the drainage opening 36. Figure 3 shows a schematic side sectional view of the flat plate collector according to Figure 1. The arrangement of the intermediate plate 30 within the reaction chamber 24 can be seen, namely parallel to the position of the cover plate 22. In addition, the division of the reaction chamber 24 into the subchambers 26, 28 by the intermediate plate 30 is once again clear. The arrangement of the drainage channels 32, 42 and the relative position of the intermediate plate 30 above the drainage channel 32 can also be clearly seen. The intermediate plate 30 is dimensioned in such a way that free spaces for air circulation remain between the side walls 14, 16, 18, 20 and the intermediate plate 30.

The base plate 12 of the flat collector 10 is usually made of metal, black-colored or black-coated metal, a metal alloy, ceramic, glass or plastic or a combination thereof. The material and/or the coating should be corrosion-resistant to the liquid to be desalinated. The cover plate 22 and the intermediate plate 30 are made at least partially of glass, plastic or another suitable translucent material.

Claims

Claims: 1. Flat collector (10) comprising a base plate (12) or base pan, side walls (14, 16, 18, 20) and at least one at least partially transparent cover plate (22), which are detachably or non-detachably connected to one another and form at least one reaction chamber (24), characterized in that at least one intermediate plate (30) is arranged within the reaction chamber (24), which divides the reaction chamber (24) into at least two subchambers (26, 28) and is at least partially transparent, wherein the intermediate plate (30) is arranged within the reaction chamber (24) in such a way that air circulation is possible within the reaction chamber (24), within the subchambers (26, 28) and between the subchambers (26, 28). 2. Flat collector (10) according to claim 1, characterized in that a surface of the intermediate plate (30) is overall smaller than a surface of the base plate (12) and/or is overall smaller than a surface of the cover plate (22). 3. Flat collector (10) according to one of the preceding claims, characterized in that the intermediate plate (30) has at least one opening. 4. Flat collector (10) according to one of the preceding claims, characterized in that the intermediate plate (30) is arranged approximately parallel to the cover plate (22) within the reaction chamber (24). 5. Flat collector (10) according to one of the preceding claims, characterized in that the intermediate plate (30) is dimensioned such that one end of the intermediate plate (30) is above a formed drainage channel (32) for a liquid desalinated and/or demineralized by means of the flat collector (10). 6. Flat collector (10) according to one of the preceding claims, characterized in that the side walls (12, 14, 16, 18) and/or the intermediate plate (30) have at least one adjustment device and/or at least one adjustment grid for the variable adjustment of a distance between the intermediate plate (30) and the cover plate (22). 7. Flat collector according to one of the preceding claims, characterized in that the intermediate plate (30) and the cover plate (22) consist at least partially of glass, plastic or a combination of these materials. 8. System for desalination and/or demineralization of liquids comprising at least one flat collector according to one of claims 1 to 7.