FR2462670A1 - Solar heating panel for building - has external, self-regenerating desiccant drier to eliminate condensation inside panel airspace - Google Patents

Abstract

The solar heat collector (1) has an insulated enclosure (3) with a glass cover (4). An absorber (2) containing the fluid to be heated is separated, from the glass cover by an air gap (5). A container (6) is connected to the air space (5) of the solar panel. The container consists of a thin-walled copper cylinder (13) filled with a dessicant (7). Holes (14,15) in each end of the cylinder provide a connection from the air space through the dessicant (7) to atmosphere. The cylinder is housed in an outer transparent enclosure (16) held between steel end plates (17,18). Moisture adsorbed by the dessicant during the night is rejected to atmosphere during periods of sunshine when the air in the air space (5) expands and causes a flow to atmosphere over the dessicant.

Description

The invention relates to devices using solar energy and relates more precisely to a collector of solar energy of the planar type.

Planar type solar energy collectors are mainly used for heating heat-transfer liquids, in particular water up to temperatures around 60 to 80 ° C, and are widely used in hot water supply circuits for industrial premises. and homes.

The execution of planar type solar collectors is quite simple. They comprise an absorber of sun radiation mounted in a thermally insulated body, one of the walls of which is made of an optically transparent material.

The absorber of solar radiation comes into contact with the coolant and, when heated, transmits the energy of solar radiation Between the wall of optically transparent material and the absorber there is a gap or air gap.

The main requirements imposed on collectors of this kind are a moderate coat, convenience in service, sufficiently high reliability and efficiency.

The efficiency of a planar type solar energy collector depends to a large extent on the extreme reduction of heat loss by convection, transmission and radiation. This is why the greatest attention is paid to the thermal insulation of the body: the opaque part of the body is made of thermal insulation material, for example polyurethane, while the optically transparent wall is generally made of glass with an air gap for thermal insulation. . In order to reduce heat loss by convection, double glazing is used regularly, in other words two air layers are used for the insulation. During operation in a solar energy collector, on the inside of the glass layer is periodically condensed with water vapor which decreases the efficiency of the collector, according to estimates, by 10 to 15%. It is possible to avoid condensation of atmospheric humidity by using a fully sealed collector. However, a waterproof collector is quite expensive since it requires the use of special materials and, in addition, the tightness of the collector leads to an additional complication of its execution since the heating of the collector causes a pressure rise inside. of the collector body which it is important to equalize with atmospheric pressure.

It is more advisable to prevent the formation of mist (avoid condensation of atmospheric humidity) on the optically transparent wall of the body by using moisture-absorbing materials.

There is already known a solar collector of the planar type comprising a solar absorber disposed in a thermally insulated body with a wall of optically transparent material and mounted with an interval relative to said wall as well as a container of a moisture absorbing material which can be regenerated by heating, by means of which the volume between the solar radiation absorber and the wall of the body of optically transparent material communicates with the atmosphere. The container of moisture absorbing material is disposed in the body of the solar radiation absorber. The solar absorber heats the moisture absorbing material to a temperature that guarantees its regeneration. We know that the process of absorption of moisture by the moisture absorbing material is accompanied of a significant release of heat which, under the conditions of effective insulation, leads to a significant increase in the regeneration temperature of the moisture-absorbing material. Furthermore, the regeneration temperature is limited by the operating temperature of the collector, that is to say by the temperature of the coolant. In other words, in such a solar collector of the planar type, total regeneration of the moisture-absorbing material is impossible and the moisture-absorbing material must be changed periodically by partially or completely dismantling the collector. All of this leads to additional operating costs.

The invention therefore proposes to create a solar collector of the planar type with such a location of the container of moisture-absorbing material that it makes it possible to simplify and accelerate the replacement of moisture-absorbing material during 11 use of the collector.

The problem thus posed is solved by the fact that in a solar collector of the planar type comprising a solar radiation absorber located in a heat-insulated body with a wall of optically transparent material and mounted with an interval relative to said wall and a container of moisture-absorbing material which regenerates by heating, by means of which the volume between the absorber of solar radiation and the wall of the body of optically transparent material communicates with the atmospheres according to the invention, the container of absorbent material 1 The humidity is arranged outside the body and is suitable for heating up to a temperature guaranteeing the regeneration of the moisture-absorbing material.

It is advantageous that the solar energy collector according to the invention comprises a heat-insulated envelope of which at least part is made of optically transparent material and in which is disposed a container of moisture-absorbing material, heated by the solar radiation which passes through the optically transparent part of the envelope.

It is advantageous that in the solar energy collector according to the invention at least a part of the container oriented towards the part of the envelope of optically transparent material is executed so as to absorb the solar radiation.

It is also desirable that the solar energy collector, according to the invention, contain a solar radiation reflector arranged inside the body.

The location of the container of moisture-absorbing material outside the body makes it possible to considerably simplify the prophylactic maintenance of the solar energy collector and improves the conditions for regenerating the moisture-absorbing material.

In what follows the invention is illustrated by the detailed description of embodiments and by detailed drawings in which
- Fig. 1 shows a general view of the planar type solar energy collector (view in longitudinal section) according to the invention
- Fig. 2 shows an embodiment of the container of moisture-absorbing material provided with a reflector (view in longitudinal section) according to the invention
- Fig. 3 shows a system of solar collectors of the planar type communicating with the atmosphere by a container of moisture-absorbing material, which is common, according to the invention.

The collector I of solar energy (FIG. I) of the planar type comprises an absorber 2 of solar radiation located in a heat-insulated body 3. One of the walls 4 of the body 3 is made of an optically transparent material, it being understood that the absorber 2 is mounted with an interval 5 relative to said wall 4. The collector I also comprises a container 6 filled with moisture-absorbing material 7 via which the volume 5 communicates with the atmosphere.

The vital element of collector I is the absorber 2 of solar radiation. The absorber 2 is produced by a process known to those skilled in the art. In the simple case, the absorber consists of a metal casing 8, in particular of copper with a blackened surface oriented towards the solar radiation indicated by arrows A in the figure. The blackened layer is made of metal oxide, in particular of cobalt oxide.

Such an agent for absorbing solar radiation intensely absorbs solar radiation whose wavelength ranges from 0.2 to 1.5 microns and in the infrared part of the spectrum - The radiation whose wavelength ranges from 3 to 5 microns. Inside the box 8 there is a flow of coolant 9, in particular 11 water. The. box 8 comprises an inlet pipe and an outlet pipe 10 and 11 respectively, for connection with a hot water supply system (not shown in the figure).

The heat-insulated body 3 of the collector I is made of a heat-insulating material which can be wood, a plastic material, etc. As the optically transparent material of the wall 4, glass is used. In the body 3 is formed an orifice 12 through which the gap 5 communicates with the container 6. The container 6 is a thin-walled metal cylinder 13 in particular made of copper, filled with moisture-absorbing material 7, for example silica. On the end faces of the cylinder 13 are formed orifices 14 and 15. Through the orifice 14 the enclosure of the cylinder 13 communicates with the orifice 12 of the body 3 while through the orifice 15 it communicates with the atmosphere. In other words, the enclosure 3 communicates with the atmosphere via the moisture-absorbing material 7. The cylinder 13 is placed in the envelope 16, which is executed in the form of a glass tube with end faces of which there are metal diaphragms 17, 18 made of steel with low heat conductivity.

In the orifices 14 and 15 are mounted metal fabrics (not shown in the figure) which prevent losses of the moisture absorbing material 70
The container 6 can have any geometric shape, for example cylindrical or parallelepipedic. The envelope 16 generally has the same shape as the container 6, that is to say in the version described it is cylindrical. In this case it is advantageous to produce the entire lateral part of the envelope 16 in optically transparent material.

FIG. 2 represents a container 6 having the shape of a parallelepiped. In this version only the wall 19 of the envelope is made of optically transparent material while the remaining part of the envelope 20 is made of steel. To raise the heating temperature of the moisture-absorbing material 7 inside the envelope 20, a reflector 21 of solar radiation is provided, executed in the version described in the form of a specular coating formed on the surface. inside of the envelope 20, opposite the wall 19. It is also possible to produce the reflector 21 in the form of a separate sheet of aluminum, the surface of which has been polished.

It is advantageous to produce at least part of the container 6 oriented towards the part of the envelope 20 made of optically transparent material, that is to say oriented towards the wall 19 so that it absorbs solar radiation by a process. any known to those skilled in the art, in particular by blackening the surface of the container 6 or by providing ribs on this surface.

In a hot water supply circuit comprising a group of collectors I (FIG. 3) of solar energy of the planar type, it is possible to use a common container 6 filled with a material absorbing water 7. In this case the intervals 5 (Figure I) of the collectors I are joined together in series by a pipe 22 (Figure 3), the pipes 10 are joined to the pipe 23 serving for the supply of the coolant while the pipes II are connected to the pipe 24 for the evacuation of the coolant. The advantages of a hot water supply circuit comprising a group of solar energy collectors with a single common container 6 which are linked to the acceleration and the simplification of the replacement of the moisture absorbing material 7 are obvious .

The operation of the planar type solar energy collector is as follows. During the night the humid air from the atmosphere arrives in the enclosure of the collector I (FIG. I), that is to say in the volume 5 by passing through the container 6 of material absorbing moisture 7.

Furthermore, the moisture absorbing material 7 dries the air by absorbing its moisture. During the day in the presence of solar radiation there is expansion of the air inside the collector I and heating of the moisture-absorbing material 7 which causes the regeneration of the moisture-absorbing material 7, the humidity released being driven towards the atmosphere. In this case, the regeneration of the moisture-absorbing material 7 takes place at the operating temperature of the container 6 which exceeds the operating temperature of the absorber 2 of the solar energy thanks to the execution of the container 6 in the form of an autonomous solar energy collector free of contact with the coolant 9. In addition, in the described solar energy collector, the operating temperature is independent of the conditions for regeneration of the moisture-absorbing material 7, and moreover the spare absorbent material 7 of container 6, do not require significant disassembly of collector I.

Claims (4)

RESENDTCATI0NS 1 - Solar collector of the planar type comprising an absorber of solar radiation sheltered in a heat-insulated body with a wall of optically transparent material and mounted with an interval relative to said wall and a container of moisture-absorbing material which is regenerated by heating, by means of which the volume between the solar radiation absorber and the wall of the body of optically transparent material communicates with the atmosphere, characterized in that the container (6) of moisture-absorbing material (7) is arranged outside the body (3) and is adapted to be heated up to a temperature guaranteeing the regeneration of the moisture-absorbing material. 2 - solar energy collector according to claim I, characterized in that it comprises a heat-insulated envelope (16) at least part of which is made of an optically transparent material and in which is housed a container (6) of absorbent material l water heated by solar radiation passing through the optically transparent part of the envelope. 3 - Solar energy collector according to claim 2, characterized in that at least part of the container (6) oriented towards the part. the envelope (16) of optically transparent material is produced so as to absorb solar radiation. 4 - Solar energy collector according to any one of claims 2 or 3, characterized in that it comprises inside the envelope (16) a reflector of solar radiation (21).