DE9313856U1 - Two-part solar collector - Google Patents

Description

G 11 875 GB

Stephan Fintelmann, Alexander Thorn, Mansteinstrasse 15, 10783 Berlin 5

Two-part solar collector

The invention relates to a solar collector with a frame formed from a U-shaped profile, in which an absorber is arranged under a cover that is permeable to solar radiation and an insulation on the rear side of the absorber facing away from the solar radiation. At least one hole extending perpendicular to the absorber surface is provided in the insulation of the collector, which hole serves to accommodate at least one connection piece for the distribution and collection line.

Distribution and collection lines are arranged outside the collector.

Such solar collectors (also called solar panels) each contain a solar energy absorber. As a rule, a solar collector system is made up of a number of such solar collectors, each with a housing, on a house roof, for example. Several housings or frames are arranged next to one another and a common pipe system leads the heat transfer fluid to the individual collectors and from them to the consumer.

The pipe system connecting the majority of solar collectors has, on the one hand, a common distribution pipe which leads the heat transfer fluid to the individual collectors and, on the other hand, a collecting pipe which receives and collects the heated heat transfer fluid from the individual collectors and leads it to the consumer (or consumers).

The solar energy collectors have so-called absorbers, each of which is arranged in a weatherproof housing. On the back of the absorber they are connected to pipes through which the heat transfer fluid flows. For example, the pipes are shaped like meanders.

In order to avoid heat energy loss, insulation measures, usually heat insulation panels made of

Mineral wool. The housing is usually made of aluminum sheet profiles or deep-drawn aluminum trays that enclose an insulating plate or the like.

The present invention relates to the problem of the arrangement of the above-mentioned distribution and collection lines, i.e. the supply and discharge lines to the collectors.

¹ ^ The present invention also relates to the problem of shaping the absorber. In addition, the present invention relates to the problem of weather-tight connection of several solar collectors to one another.

Regarding the problem of arranging the distribution and collection lines, i.e. the ¹ ^ supply and discharge lines to collector fields, the state of the art essentially knows two solutions:

On the one hand, it is known to run the distribution lines outside the collector housings and on the other hand, it is also known to arrange the distribution lines inside the collector housings. Both known solutions have advantages and disadvantages.

If distribution and collection lines extend inside the housing, these must be installed by the manufacturer, with the connections of the lines protruding from the housing. Therefore, a relatively large distance is required between the individual collectors. The connection nozzles protruding to the side create the problem that the thermal expansion of the lines and metal nozzles must be compensated for.

which cannot always be done effectively. 30

In the case of distribution and collection lines arranged outside the individual collector housings, these were previously mounted on the back or along the front sides of the individual housings. The disadvantages of such an arrangement of the lines are the required complex thermal insulation for the lines running separately from the housing and the limited ability to mount the collectors when the lines are arranged at the back.

The absorbers required for the collectors were mainly manufactured using two different methods. In one method, absorber strips are provided with a special coating and then individually soldered to the distribution and collection lines by hand. This is extremely complex and costly, and when soldering the already coated absorber strips, the coating at the soldering point is damaged.

In another method of manufacturing absorbers, two aluminum sheets are joined together using a special rolling process so that a catalyst for the heat transfer medium is formed between the sheets by subsequent inflation. With such absorbers, measures must be taken to prevent corrosion caused by the heat transfer medium. In addition, aluminum is a poorer conductor of heat than copper.

The invention is based on the object of providing a collector module for accommodating an absorber, which is connected via a carrier module provided with the distribution and collection lines.

The inventive solution to this problem is characterized in claim 1.

A second object is to provide an absorber that avoids the previous problems of known absorbers. The inventive solution to this object is characterized in claim 2.

Further advantageous embodiments of the invention are the subject of the subclaims.

The present invention creates a system of collector modules and support modules that is simpler and cheaper to manufacture and install. The collector module essentially consists of a frame, an insulating plate, a glass plate and an absorber. The connecting pieces of the absorber protrude into a hole in the insulating plate, with the hole extending perpendicular to the absorber surface into the

Insulating plate. A carrier module essentially consists of an insulating plate which is provided with grooves for receiving distributor and collecting pipes, whereby these distributor and collecting pipes are provided with connecting pieces for connection to the collector module. The connecting pieces of the collector module and the carrier module are connected to one another by flexible hoses (hereinafter referred to as flexible hoses). The separate arrangement of the distributor and collecting lines makes it possible to provide only one lead-through in the roof area.

The collector modules are each equipped with an absorber, which consists of a deep-drawn, corrugated copper sheet that is soldered to a meander-shaped pipe coil (hereinafter referred to as meander coil). The special coating of the absorber, e.g. with black chrome plating, is applied after the meander coil is soldered to the absorber sheet.

This design of the absorber enables better conductivity and a reduced risk of contact corrosion.

In addition, the thermal expansion or contraction between the individual collector modules is reduced by the fact that the distribution and collection lines in the carrier module are only connected to the collector module via flexible hoses.

The simple connection of the connection pieces using flexible hoses on the one hand and the simple connection using screws between the carrier and the collector module on the other hand make the assembly and disassembly of the solar collectors easier and therefore more cost-effective.

Alternatively, the distribution and collection pipes can also be laid without support modules. It is sufficient to arrange the pipes between standard insulation panels and attach them to the roof structure using pipe clips. This option makes self-assembly easier and also cheaper, as only the collector modules and the pipes need to be purchased.

Need to become.
35

In the following, embodiments of the invention are explained in more detail with reference to the drawings. It shows:

Fig. 1 shows a schematic section through an edge area of a

a collector module arranged on a carrier module; 5

Fig. 2 is a partially sectional perspective view of a collector module;

Fig. 3 is a perspective view of a carrier module;

Fig. 4 shows a perspective alternative arrangement of the distribution and collection pipes;

Fig. 5 is a perspective view of an edge region of two interconnected collector and carrier modules;

Fig. 6 shows a detailed view of the collector connection.

Fig. 1 shows a section through an edge area of a collector module (1) that rests on a carrier module (17). The collector module essentially consists of an insulating plate (4), the edges of which are covered by a frame (2), an absorber (5) that rests on the insulating plate (4) and a glass plate (3) that rests on the frame (2) and is glued to it by means of a silicone adhesive (11).

The frame (2), which is essentially rectangular in shape, has two frame side parts (7) and two frame front side parts (8), which are mitered and connected to one another by means of rivets, weld points or the like. The frame parts essentially have a U-shaped profile, with the lower edge of the frame parts being longer than the upper edge. To stiffen the frame (2), the lower edges of the two frame side parts (7) are connected to one another by frame cross members (9), with the frame cross members (9) being arranged essentially parallel to the frame front side parts (8). The frame cross members (9) rest on the lower edges of the frame side parts (7) and are connected to them by means of screws, rivets, weld points or the like.

An absorber sheet (5a) consists of a deep-drawn sheet made of copper with beads (34) and whose side edges (40, 41) are bent downwards. The beads (34) are arranged so that they run essentially parallel to the frame end parts (8). The absorber sheet (5) is connected to a meander coil (6) in such a way that a soldering foil (35) is placed on the underside of the absorber sheet (5a) and the meander coil (6) is placed on top of it, after which the meander coil (6) is connected to the absorber sheet (5a) by heating. The free ends of the meander coil (6) are bent downwards at almost a right angle and form collector connections (14). A connection piece (15) is attached to the collector connection (14). Collector fastenings (10) in the form of an angled piece of sheet metal are attached to the edges of the frame (2) by means of screws, rivets, spot welds ¹ ^ or the like.

The absorber (5) is arranged on the insulating plate (4) in such a way that the collector connection (14) with the connecting piece (15) is in a hole (29) that extends perpendicularly to the absorber surface in the insulation. The lower edge of the connecting piece (15) is at a sufficient distance from the lower edge of the insulating plate (4), which allows the later inclusion of a connecting piece (21) and a flexible hose (16) of a distributor pipe (20).

The carrier module (17) is arranged below the collector module (1). Distributor lines (20) and collection lines (26,27) are arranged in grooves (22) that are milled into an insulating plate (18) of the carrier module (17).

A covering insulation (23) is placed on the distribution (20) and collection lines (26,27), the upper surface of which is flush with the surface of the insulating plate (4). The covering insulation (23) preferably consists of mineral wool.

As can be seen from Fig. 3, the distributor or collecting pipes have screw connections (24) at their ends, through which they can be connected to other distributor or collecting pipes. In order to avoid

In order to enable the supply and discharge of the heat transfer fluid from the same side of the collector field when connecting several collectors according to "Tichelmann", a return line (26) is provided which is connected to the collecting line (27) by means of a semicircular bend (25) at the end of the collector field.

The insulating plate (18) has fastening profiles (19) on its front sides, whereby the fastening profile (19) has holes (32) on an edge bent outwards at a right angle, which serve to accommodate fastening means for installation on the roof truss. An upper edge of the fastening profile (19) bent back at a right angle has holes (31) on the outside, which serve to accommodate fastening means for connecting the collector fastening (10) to the fastening profile (19).

To connect a carrier module to a collector module, proceed as follows:

^The support module is attached to the roof truss. The collector module (1) is then placed on the support module (17), the connecting pieces (15 and 21) are connected with a flexible hose (16) and fastening elements (33) are guided through the aligned holes (30 and 31).

The separate installation of the distribution and collection pipes enables easy assembly and disassembly of the collector modules, as well as a single opening for the connection to lines located under a roof to the consumers. The thermal expansion or contraction of the connection pieces (15 and 21) as well as the distribution and collection lines (20 and 27) is completely compensated by the flexible hose (16). As the connection piece (15) is directed vertically downwards, therefore lateral thermal expansion does not have to be compensated, the collector modules can be arranged at a small distance from each other. Side thermal insulation is therefore not required for each individual collector module, but is limited to the edge of the entire collector field. The glass plate is advantageously

(3) are arranged on the frame in such a way that the outer edges of the glass plate (3) protrude beyond the frame. As can be seen from Fig. 5 and 6, it is no longer necessary to provide wide covers, usually made of metal, between the collectors. It is therefore sufficient to connect glass plates (3) of several collector modules (1) to one another using a rubber seal (12). If several collector modules (1) are arranged in such a way that the glass plates (3) overlap, it is sufficient to ^insulate the glass plates from one another using a self-adhesive foam rubber strip (28).

Alternatively, it is also possible to do without support modules (17). It is then sufficient to arrange the distributor pipes (20) or collector pipes (26,27) between two mineral wool heat protection mats, e.g. in standard width 600 mm and 25 mm thick, and to attach the pipes (20,26,27) to the roof with pipe clips (39). This enables the simplest self-assembly of pipes and collector modules (1).

In a preferred embodiment, the frame (2) consists of zinc sheet profile parts. This leads to lower heat losses than is possible with aluminum profile sheets, since zinc sheet is a poorer heat conductor than aluminum. In addition, the choice of zinc sheet profiles enables cheaper production.

Mk/mat

Claims (10)

G 11 875 Gb Stephan Fintelmann, Alexander Thorn, Mansteinstraße 15, 10783 Berlin Protection claims: 1. Solar collector with a frame formed from a U-shaped profile, in which an absorber is arranged under a cover permeable to solar radiation and an insulation on the rear side of the absorber facing away from the solar radiation, wherein at least one bore extending perpendicular to the absorber surface is provided in the insulation, in which the connecting piece for at least one distribution line is accommodated, and with distribution and collecting lines arranged outside the collector, characterized in that the distribution (20) and collecting lines (26,27) are mounted in a separate carrier module (17) and there in grooves (22), wherein connecting pieces (21) of the distribution (20) and collecting lines (26,27) ¹¹¹ It connecting pieces (15) of the absorber (5) by means of flexible hoses (16) and that the carrier module (17) essentially consists of an insulating plate (18) and fastening profiles (19) and that the carrier module (17) is connected to the collector module (1) by means of a collector fastening (10). 2. Solar collector according to claim 1, characterized in that the Absorber (5) consists of a one-piece deep-drawn absorber sheet (5a) made of copper and provided with beads (34) and a meandering pipe coil (6), wherein the meandering pipe coil (6) is connected to the absorber sheet (5a) by means of a soldering (35). 3. Solar collector according to claim 1 and 2, characterized in that the beads (34) run out before the end of the absorber sheet (5a). 4. Solar collector according to claim 1, characterized in that the Frame (2) consists of U-shaped zinc sheet profiles. 5. Solar collector according to claim 1 and 4, characterized in that the frame (2) is reinforced with frame cross members (9). 6. Solar collector according to claim 1, characterized in that a glass plate (3) rests on the frame (2) and that the edges of the glass plate (3) protrude beyond the frame. 1 · Solar collector according to claim 6, characterized in that the glass plate (3) is glued to the frame (2) by means of a silicone adhesive (11). 8. Solar collector according to claims 1, 6 and 7, characterized in that adjacent edges of glass plates (3) of several collector modules (1) are sealed against each other by means of a rubber seal (12). 9. Solar collector according to claim 8, characterized in that in the drainage direction of the rainwater, overlapping edges of glass plates (3) of several collector modules (1) are sealed by means of a self-adhesive foam rubber strip (28). 10. Solar collector according to claim _{1 1} , characterized in that the distributor (20) and collecting lines (26, 27) are alternatively mounted in two mineral wool heat protection mats (37, 38) and fastened with pipe clips (39). Mk/mat
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