DE2913490A1 - Solar radiation absorber roof - has extruded heat carrier feed pipe parallel to gutter, between upper and lower roof panel - Google Patents

Abstract

The roof consists of aluminium sheets with connected hollows to accommodate a heat carrier medium and collector conduits. A heat carrier feed pipe (3) extending parallel to the gutter (2) consists of an extruded profile. The profile has a clamp nose (9), a connection section (10), and a projecting section (12) with passage apertures (13). The roof consists of an upper roof panel (4) and a base panel (5) below it. The panels overlap, and each is fastened by clamping on the gutter side, and by screwing of the base panel to the roof lath (6), and the ridge side. The heat carrier medium is transferred from one panel to the next via telescopic connecting elements, having a sealing ring.

Description

From sorberdach

The innovation concerns an absorber roof consisting of several aluminum sheets with lines for a heat transfer medium and from parallel to the eaves or the roof ridge running supply and discharge lines.

It is known to produce absorber roofs made of aluminum, the Lines for heat transfer media, for example, using the so-called rollbond process getting produced. When using such roofs there is the disadvantage that Condensation water is formed below the roofs and thus premature rot of the wooden roof truss occurs.

Attempts have been made to prevent the formation of condensation water by that the insulation between the roof structure and roof surface or absorber surface is improved will. However, one waives the advantage of the heat of condensation in the To use the formation of condensation water for heating the heat carrier. aside from that the circulating air heat from the underside of the absorber plate cannot be used.

The task of the present innovation is to measure the efficiency of an absorber roof by applying the heat from the circulating air to the absorber sheet on all sides increase and at the same time reduce the detrimental effect of condensation in the roof structure to prevent. According to the innovation, this is indicated by what is stated in the claims for protection Features solved.

In the following, the innovation will be described in more detail using an exemplary embodiment explained. The figures show: FIG. 1 cross section through a device constructed according to the invention Roof.

Figure 2 is a perspective longitudinal section through a constructed according to the invention Roof.

FIG. 3 enlarged cross section through a connection point of two aluminum sheets.

Figure 4 to Figure 7 cross sections through absorber sheets with various Piping system.

In Fig. 1, the roof beam is 1, the eaves 2, the supply pipe with 3, the absorber plate with 4 and the bottom plate with 5. The floor pan 5 can be designed as both trapezoidal and corrugated sheet metal.

Between the floor panel 5 and the roof beam 1, usually through a film 7 is protected, roof battens 6 are arranged. The absorber sheet 4 is screwed 8 or

screwed to the base plate 5 and the roof battens 6 via clamp 9.

The feed pipe 3 is an extruded profile that has several functions has to fulfill at the same time. First of all, it serves to conduct the heat carrier in the different sections of the roof. It has an outlet nozzle for this purpose 10, which is used in a special way to accommodate the beginning of the line 11 of the roof line 14 is formed. Furthermore, the supply pipe 3 has a disengagement end 12, the for receiving and discharging the condensation water from the floor panel 5 into the eaves 2 serves. Breakthroughs 13 are arranged so that the condensation can run off unhindered can.

In Fig.2 the roof beam is with 15, the eaves with 16, the roof membrane designated by 17 and the absorber plate by 18.

The bottom plate 19 rests on the roof batten 20 and opens at the lower End into the channel 21 of the supply pipe 22. Bends 24 of the absorber sheet 18 engage in a nose 23 of the feed pipe 22, whereby the absorber sheet 18 easy to assemble and at the same time secured against wind and suction forces. That The absorber plate 25 located further up has mounting or ventilation openings 26 and engages with its fold 27 in a sheet metal nose 28, which is on the underneath arranged absorber plate 29 is attached.

The roof pipe system is now supposed to be based on the example of the absorber sheet 29 will be described in more detail.

The lines of the heat transfer medium 30 have an inlet piece 31 and an end piece 32, which is on the opposite side of the heat transfer line 30 open. This prevents the heat transfer medium from taking the shortest route the roof pipe system flows through it. Rather, it ensures that a more even Heat exchange with the entire surface of the absorber plate 29 (according to the Tichelmann system) he follows. Through the window 34, the connecting piece 33 of the heat transfer line can be Easily accessible for assembly and repair purposes. Construction and functionality of the connection piece are described in more detail with reference to the next Fig. 3.

In Figure 3, the batten covered with plastic film with 35, the Bottom plate with 36 and the absorber plate with 37 resp.

38 designated. This rises from the line 39 of the absorber plate 37 Heat transfer medium into the welded connection piece 40 and from there via the receiving tube 41 in the channel 42 of the absorber plate 38. To prevent the escape of the The heat transfer medium is an O-ring between the outlet connection 40 and the receiving tube 41 43 arranged The assembly of the roof takes place in the following Steps: first, the lower absorber plate 37 is overlaid with the bottom plate 36 a support 44 and insulating washer 45 screwed together.

A folding plate 46 is placed under the screw head 47 and fixed by tightening screw 47. The upper roof plate 38 inserted with the receiving nozzle 41 in the connecting piece 40 and pressed the nose 49 are clamped to the folding plate 46. For repair and inspection purposes a viewing opening 48 is provided. Likewise, through the viewing opening 48, commercially available Crimping tools are introduced for subsequent crimping of the pipe connection.

In the case of the roof plates mentioned above, the roof lines were made according to the so-called Rollbond-Verfaloren produced. But it is also possible to use other line systems to use. Reference is made here to the embodiments shown in FIGS referenced. According to FIG. 4, a heat conduction pipe 50 is connected to a sheet metal 51. The heat conduction pipe is expediently made from an extruded profile. It can be connected to the sheet metal 51 by gluing, welding, soldering or screwing and riveting get connected. To improve the heat transfer or the surface enlargement are in the heat pipe 50 lugs 52 with pressed.

The assembly of a heat conduction tube 53 on a sheet metal 54 is shown in FIG Fig. 5 shown. The connecting pieces 55 and 56 are on the opposite Places provided.

The actual heat conduction pipe 50 is bent in a meander shape. In the bending radii 57 are the profile webs beforehand by punching for the purpose of better bendability been removed.

In Fig.6 and Fig.7 are two further alternatives for a heat conduction pipe shown. The extruded heat pipe 58 with oval The passage cross section is glued to the sheet metal 59. In contrast, the heat pipe is 60 according to FIG. 7 initially pressed into an extruded profile 61, which is connected to the sheet metal 63 is connected in the usual way.

A subsequent compression of the lugs 62 in the direction of the arrow, the can only be carried out locally at certain intervals, fixes the pipe 60 with the smallest possible air gap between the two components.

Claims (10)

Protection claims c 1i absorber roof consisting of several aluminum sheets with interconnected cavities for receiving a heat transfer medium and collecting pipes, characterized in that a parallel to the eaves (2, 16) extending supply pipe (3, 22) consists of an extruded profile, the one Clamping nose (9), a connecting piece (10) and a bracket (12) with openings (13). 2. absorber roof according to claim 1, characterized in that it consists of an upper roof plate (4) and an underlying floor plate (5). 3. absorber roof according to one of the preceding claims, characterized characterized in that several roof sheets overlap like roof tiles, the Fastening of each individual roof plate to the eaves side by means of a clamp and on the ridge side through a screw connection to the base plate (5) on the roof batten (6) is made. 4. absorber roof according to one of the preceding claims, characterized characterized in that the transfer of the heat carrier from a roof plate (39) a second roof plate (38) over acting telescopically, with a sealing ring (43) provided connection / receiving pieces (40,41) takes place. 5. absorber roof according to one of the preceding claims, characterized characterized in that the heat conduction tube (50) consists of an extruded profile with a round Cross section. 6. absorber roof according to one of the preceding claims, characterized in that that the interior of the heat conduction tube (50) with pressed-on lugs (52) for the purpose of increasing the surface area and improvement of the heat transfer is provided. 7. absorber roof according to one of the preceding claims, characterized characterized in that the heat conduction tube (58) consists of an extruded profile with an oval Cross section. 8. absorber roof according to one of the preceding claims, characterized in that that the heat conduction tube (60) can be clamped in an extruded profile (61) and Can be fixed via pressed-on ribs (62) by local pressing in the direction of the arrow is. 9. absorber roof according to one of the preceding claims, characterized in that that the connecting pieces (55, 56) of the heat conduction pipes alternately on the opposite, are at the most distant corner of the pipeline network. 10. absorber roof according to one of the preceding claims, characterized characterized in that the heat conduction channels (30) in the "Rollbond" absorber sheets (29) are arranged parallel to the sloping roof and that the input tubes (41) and The outlet pipes (40) are located above and below in the middle of the absorber plate, but via channels (30a, 30b) so with the lower or upper horizontally running distribution channel (30c) are connected so that the inlet and outlet across a corner opposite a uniform Pressure build-up and thus even heat distribution over the entire absorber plate (29) guaranteed.