FR2463902A1 - Solar heat collector - has plate in portions each with holes having flanged edges in which pipes fit - Google Patents

Abstract

The solar heat collector comprises an absorber consisting of pipes through which coolant flows and which are in contact with a metal plate. The plate (1) is in a number of portions, each having holes with flanged edges (2) beaded over and pref. covered with a heat-absorbent coating. The pipes (3) are a press-fit in the holes, and distance sleeves (4) can be fitted between the individual plate portions as necessary. Each plate portion can be bent, having one heat-absorbent portion and one containing the holes and flanges.After insertion of the pipes in the flanges they can be expanded by pressing balls through them. There are heat resistant spacers between the coolant pipe of the absorber and a less heat resistant connecting pipe for introducing or removing the coolant. The spacers are pref. made of PTFE and the connecting pipe is pref. PVC.

Description

The present invention relates to a solar energy collector comprising a solar heat absorber consisting of a metal sheet and a pipe, preferably metal,. in heat conduction contact with the metal sheet. A refrigerant is circulated in the piping, when the solar collector and its absorber are subjected to sunlight, so that the refrigerant collects the solar heat which is absorbed by the metal sheet.

We know how to make a solar collector absorber by welding a copper pipe and a copper sheet, and preferably determining a metallurgical joint between the pipe and the sheet. The solar heat which is absorbed by the sheet circulates through the joint towards the piping and as a result the refrigerant which circulates in the piping is heated. However, the junction area is relatively small and the heat conduction is not very effective. It is known to make grooves in the sheet to increase the surface of the junction between the piping and the sheet, but this does not bring a marked improvement in heat transfer, and it is more expensive to conform the sheet to make grooves therein. precision.

 This is why the object of the present invention is to economically produce a solar heat absorber from a sheet and a metal pipe, the absorber having an improved heat conduction between the sheet and the pipe. Another object of the invention is to improve the joints between the sheet and the piping, as regards both the surface of the joints and the quality of the contact of these joints.

 I1 has been found, in the context of the present invention, that the absorber sheet can be advantageously subdivided into a series of plates. These plates are provided with flange holes in the same number as the number of tubes of the absorber. The tubes are forced into the holes to determine satisfactory thermal contact between the tubes and the flanges and to keep the plates assembled to each other, possibly using spacers between the plates. Preferably, the plates are provided with a layer absorbing solar heat. Thus, the absorption of solar heat by the absorber is effective even when the angle of incidence of solar radiation coming to strike the plate is large. The solar heat absorbed by the plates is transferred to the tubes and to the refrigerant in a surprising way easy by means of the hole flanges, provided that the thermal contact between the tube walls and the plate hole flanges is satisfactory.

In a preferred embodiment of the invention, each plate is curved at a certain angle and thus forms two or more continuous parts. A first part of the plate is provided for absorbing solar heat and the second part is provided with said flanged holes. When the tubes have been forced into the flange holes, the result being that the plates are kept assembled to each other, said first parts of the plates form at least one surface for absorbing solar heat in the continuous assembly , and there is no need to provide spacers between the plates. The solar heat absorbed by said first parts of the plates circulates via said second parts of the plates towards the flanges, the tubes, and finally the refrigerant.

A particularly satisfactory contact between the tubes and the flanges of the holes is obtained by forcing metal balls into the tubes, which expands the tubes when they have themselves been forced into the holes in the plates. Satisfactory thermal contact can also be obtained by applying a thermally conductive solder paste or metal between the tubes and the flanges. It is also possible to use both metal balls to expand the tubes and a thermally conductive paste or a weld metal.

The solar collector, of which the solar absorber forms a part, can be designed, for the rest, in a common manner, with a base plate, a frame, a layer of insulating material placed on the base plate and on which the absorber is placed, as well as a cover plate.

 According to one embodiment of the invention, at least some of the metal plates of the absorber are used as means of fixing to the chassis.

 According to another embodiment of the invention, the two external plates of the absorber are provided for determining the terminal joints of the solar collector.

 According to a particular embodiment of the invention, the base plate and the chassis of the solar collector are formed in the form of a single plate which is curved to provide it with flanges against which the flanges of the cover plate are placed. A porous sealing strip is advantageously inserted between the rebrods of the chassis and of the cover plate, as well as between the end joints and the cover plate. It is also advantageous to place a thermally insulating filling material between the absorber and the frame.

The solar absorber can become very hot and reach a temperature of several hundred degrees, and consequently, according to a particular embodiment of the invention, there are spacers made of a heat-resistant plastic, such as teflon, between the tubes of the absorber in which the refrigerant circulates, and the tubes to which the tubes of the absorber are connected and which are intended to send the refrigerant to the absorber and to make it return, such as tubes made of an economical but heat-sensitive polyvinyl chloride.

The present invention also relates to a method of using the solar collector of the invention. A group of solar collectors according to the invention is subjected to sunlight and a refrigerant is pumped in the group as well as in one or more radiators. Air is circulated from outside against the radiators. The outside air temperature is raised from around 7 to 120C. This causes its humidity to decrease markedly. The air is then brought into contact with a material, such as wet grass, to dry it.

In the following, some embodiments of the present invention will be described in more detail, with reference to the accompanying drawings in which
FIG. 1 represents in section, and to a certain extent schematically, in particular as regards the proportions, a horizontal section of a solar absorber according to the invention,
FIG. 2 is a vertical section of an end part of a solar collector provided with a plate absorber according to FIG. 1,
FIG. 3 represents a spacer in a heat-resistant material, placed between a tube of the absorber of FIG. 1 and of FIG. 2 and a tube for feeding or discharging the refrigerant,
- Figure 4 shows how a group of solar collectors according to Figure 2 is used to dry wet grass, using sunlight and outside air,
FIG. 5 shows how the sheet plates of a solar heat absorber are bent at a certain angle according to the invention and how a substantially continuous absorber surface is produced,
FIG. 6 shows how the thermal conduction takes place between a plate of the absorber and a tube of the absorber according to FIG. 5,
FIG. 7 is a plan view of an absorber provided with plates bent at a certain angle,
FIG. 8 represents a plate of the absorber as intended to constitute an end seal of a solar collector and comprising holes intended for the tubes of the absorber,
FIG. 9 is a perspective view of a solar collector, from which the terminal seal has been removed,
- Figure 10 shows how an insulating strip was inserted between the cover plate of a solar collector and one of its end joints,
- And Figure 11 is a cross section of a solar collector comprising a plate absorber according to the invention, a base plate, an insulating material, an insulating filling material and a porous strip of insulation between a cover plate and the absorber.

 Figure 1 shows schematically and in horizontal section a solar heat absorber according to the invention.

The metal plates are provided with holes surrounded by flanges 2. The tubes 3 are forced into the flange holes, and spacers in the form of sleeves 4 arranged around the tubes 3 have been placed between the plates 1 to maintain the assembly shown in the figure. The arrows indicate the direction of the coolant path in the tubes 3. Thanks to the joints in the form of a cylindrical shell between the flanges and the tubes, the total contact surface is surprisingly large. In addition, in the case where balls are forced into the tubes 3 to expand them and improve contact with the flanges, the heat conduction between the flanges 2 and the tubes is exceptionally good.

Figure 2 is a cross section of an end section of a solar collector comprising a plate absorber of the type illustrated in Figure 1. The solar collector consists of a base plate 11, an insulating material 12 placed on the plate base, a frame 13 and a transparent cover plate 14. The tubes 3 are fixed to the frame 13 (in a manner not shown). The absorbent plates 1 support the cover plate 14 and hold the insulating material 12 in place. Provided that the solar collector, when it is used, is turned in a direction such that the plates 1 are oriented towards the south, poor absorption. solar heat will only take place for 10 minutes before noon and 10 minutes after noon, which can be considered negligible due to the excellent qualities of the absorber with regard to the rest.

 The solar heat absorber illustrated in Figures 1 and 2 can become very hot and reach for example the temperature of 3000C; to protect a tube 21 intended for the supply or the evacuation of the refrigerant (FIG. 3) and produced for example from polyvinyl chloride, a spacer material 22 made of a heat-resistant substance, such as teflon, between the tube 21 and the tube 3 in the manner indicated in FIG. 3, using rings 23 and an insulating material 24, a thread 25 of the tube 3 as well as a locking nut 26.

Figure 4 shows how a group of solar collectors with solar heat absorbers of the type illustrated in Figures 1 to 3 are used to dry wet grass. A pump 32 circulates a refrigerant in the absorbers 31 of the group, then in the radiator 33 which is heated. The air temperature is raised from about 7 to 120C, and as a result the air is dried and can be used to dry grass, not shown, through which it flows.

 Figure 5 shows how plates 41 which were mounted on the refrigerant tube 43 according to the invention were bent at an angle, and how separate surfaces 45 for absorbing solar heat were thus obtained. All the solar heat absorption surfaces 45 of the plates form a substantially continuous solar heat absorption surface. However, some of the plates 46 should not be bent and serve as reinforcing means for the cover plate of the solar collector (not shown).

FIG. 6 represents one of the curved plates 41 of FIG. 5, provided with a flange or a collar 42 surrounding a tube 43. The path of the solar heat which is absorbed by the surface 45 of the plate and which arrives at the refrigerant is indicated by the arrows.

FIG. 7 is a plan view of a solar heat absorber comprising plates 41 which are bent at an angle according to the invention (not shown) and include surfaces for absorbing solar heat 45. The refrigerant passes by the tubes 43 connected in parallel.

 FIG. 8 represents a metal plate 51 intended to constitute an end seal with the refrigerant tubes 53 and the flanges 52 which surround them.

 Figure 9 is a perspective view of a solar collector from which the end seal has been removed. The outermost plate 1 of the absorber and the tubes 3 are visible. The base plate 6 has the shape of a box comprising walls 6b and flanges 6c to which the plates 1 have been adapted (of which only the one which is furthest outside is shown).

FIG. 10 represents the end seal 51 of FIG. 8 installed in the solar collector, an insulating strip 8 being inserted between the end seal and the cover plate 7.

 FIG. 11 is a vertical section of a solar collector according to the invention, comprising absorber plates 61, a base plate 66a, a frame flange 66b, an insulating material 69a, an insulating filling material 69b and a insulating cover strip 69c as well as a cover plate 67.

Claims (11)

1. Solar energy collector comprising a solar heat absorber, the latter consisting of a metal sheet and one or more tubes intended for the circulation of a refrigerant, which tubes are in thermal conduction contact with the metal sheet, the solar heat absorbed by the metal sheet being, via the walls of the tubes, transferred to the refrigerant which circulates in the tubes, characterized in that the metal sheet consists of a series of plates provided with flanged holes and preferably covered with a solar heat absorbing layer, and in that the tubes are forced into the flange holes of all the plates so as to obtain good thermal contact between the tubes and the flanges and keep the plates assembled to each other, possibly using spacing means between each pair of plates, the solar heat absorbed by the plates being transferred via area of the flanges of the plates to the tubes and to the refrigerant which circulates in the tubes.  2. solar collector according to claim 1, characterized in that each plate is bent at a certain angle and thereby forms one or more continuous parts, a first part for absorbing solar heat and one or more second parts provided with said flange holes, in that the first parts of the plates thus form the entire surface of absorption of the solar heat of the absorber, and in that the solar heat absorbed in said first parts is transferred, via of said second parts and of the flanges of the plates, to the tubes and to the refrigerant which circulates in these tubes.  3. Solar collector according to claim 1 or 2, characterized in that the tubes have been expanded by means of balls or the like to obtain good thermal contact between the walls of the tubes and the flanges present around the holes in the plates.  4. Solar collector according to one of claims 1 to 3, characterized in that a thermally conductive paste or a weld metal has been applied between the tubes and the flanges. 5. Solar collector according to any one of claims 1 to 4, consisting outside of the absorber, in a base plate, a frame, a layer of insulating material which is applied to the base plate and by which the absorber is supported, as well as by a cover plate, characterized in that at least some of the plates of the absorber act as fixing means for the chassis.  6. Solar collector according to claim 5, carac merise in that the two end plates of the absorber act as end joints for the solar collector. 7. solar collector according to claim 5 or 6, characterized in that the base plate and the frame are made in a single curved piece of sheet material, which is further curved to determine the edges against which the edges of the cover plate. 8. Solar collector according to any one of claims 5 to 7, characterized in that a porous strip is placed between the edges of the frame and the cover plate, as well as between the end joints of the cover plate.  9. Solar collector according to any one of claims 5 to 8, characterized in that it comprises a thermally insulating filling material between the absorber and the chassis.  10. Solar collector according to any one of claims 1 to 9, characterized in that it comprises spacing means made of a heat-resistant plastic, such as Teflon, between the refrigerant tubes of the absorber and the tubes which are connected to the tubes of the absorber and intended to circulate the refrigerant towards and from the absorber, such as tubes made of polyvinyl chloride sensitive to heat.  11. A method of using a group of solar collectors according to any one of claims 1 to 10, characterized in that the group is subjected to sunlight, the refrigerant is pumped into the group and into one or more radiators against which the outside air is circulated, the temperature of which is raised by about 7 to 120 ° C., the humidity of this air being therefore greatly lowered, and the air then being brought into contact with a material, such as wet grass, to dry it.