NO780727L - BUILT-IN SYSTEM FOR SOLAR COLLECTORS - Google Patents

Description

Installation system for solar collectors.

The object of the invention is a built-in system for solar collectors, where on the edge of the cover the solar collector under the insertion of a lay-up band or the like is applied, running around, laterally beyond these projecting cover strips and is pre-stressed with it on the edge of the underside of the collector plate under the insertion of a laying strip or similar attached laterally above the collector plate projecting sub-frame profile or part of this so that a gap is formed between the front side of the subframe profile and the bevelled outer edge of the cover strip.

With regard to the increasing energy demand for people and with regard to the decline of the usual types of energy, the use of solar collectors is of ever-increasing importance. Thereby it depends not only on the shape of the solar collectors, but also on the appropriate binding of the solar collector into building bodies to, on the one hand, protect it. building body, and secondly to enable easy assembly.

For this purpose, it is known to incorporate the solar collector using cover strips according to the principle of puttyless glazing in building bodies. Unfortunate with such a built-in system are impact and overlapping points of the cover strips with regard to tightness against rainwater. Furthermore, it is proposed to connect the frame of two neighboring solar collectors with the help of plastic profiles that are pushed onto corresponding recesses in the frame. Thereby, the connection between the edge of the building body breakthrough and the solar collector takes place by means of a frame with the help of a metal strip which, at its longitudinal edge towards the collector side, is clamped over an elastic profile.

It is also known to insert the frames of the solar collectors inserted in the building body according to the principle of soldered or inset frames from residential windows into the building body.

These possibilities used up to now in practice when installing solar collectors in the building body have the disadvantage that the installation is associated with considerable work over a longer period of time, an absolutely tight connection between the solar collector and the building body is not always ensured and the exchange of the solar collector in -trap damage requires a considerable amount of time, especially when the solar collectors are inserted or bound individually in the building bodies.

The invention is therefore based on that task

to provide an installation system for solar collectors in building bodies, where the solar collectors of the initially mentioned type are inserted or connected with relatively little work in the building body and are exchangeable with relatively few hand movements.

The solution to this problem is that the solar collectors with their sub-frame profiles, at least in the area of their corners, rest on fastening profiles placed on the building body and are firmly connected to these, while spaces are formed between the solar collectors arranged at a distance from each other, each time a metal strip with edged into those of the bevelled outer edges of the cover strips and the overlying front sides of the sub-frame profile formed slits projecting onto the attachment profiles and sub-frame profiles of two neighboring solar collectors erected longitudinal edges forming a gutter.

When the building body breakthrough is within the framework of

in the further embodiment of the invention, the solar collectors are fixed in such a way that in the gaps formed by the beveled outer edges of the cover strips and the opposite front sides of the subframe profiles, the one-sided upturned longitudinal edge of a metal strip which is brought up onto the fastening profile and the subframe profile protrudes each time, and the the other part of the metal strip is on the building body.

In the area of room water formation sometimes also over

the overall circumference, a sealing insert can be arranged for sealing between the edges of the metal strip's upturned longitudinal edges and the opposite surfaces of the cover strips.

Appropriately, the upturned longitudinal edges of the metal strips are bent over at their upper edge to form a drop nose towards the channel or to the building body.

With the device according to the invention of the upturned metal strips, a gutter system appears, the gutters running in the dripping direction suitably having a greater depth than those on

transverse to the dripping direction continuously flows. This ensures that the formed rainwater can be carried away sufficiently.

In the areas in which the channels arranged longitudinally to the drip direction intersect with the channels running transversely to the drip direction, the channels lying transversely to the drip direction are

broken and the gutter end is soldered into corresponding recesses in the upturned longitudinal edges of the gutters running in the dripping direction.

The appropriate thing is that the solar collectors are connected

with the fastening profiles by means of tin screws, which are inserted through corresponding holes in the cover clamp strips and the subframe profile and are screwed together with the fastening profile.

The advantages achieved with the built-in system according to the invention consist in the fact that the solar collectors can be easily mounted, especially also in the case of a multiple device, and by loosening the screws that connect the solar collectors to the fastening profiles they can be easily exchanged. A further advantage consists in the fact that the upturned longitudinal edges of the metal strips simultaneously form a housing for the solar collectors, and thus the special housing usually used for known solar collectors can be disregarded.

The built-in system designed according to the invention is explained in more detail with the help of some design examples.

The drawing shows:

Fig. 1 a sectional cross-section through the corner area of a built-in solar collector in the area of the building body breakthrough, Fig. 2 an elevation of four solar collectors arranged in a row. Fig. 3 a cross-section along the section line I-1 in fig. 2.

Fig. 4 a perspective elevation of the crossing area of

one in the drip direction and one running transversely to the drip direction, with longitudinal edges each time turned up.

On the edge area of the cover 1 of the solar collector is the circumferential, laterally projecting cover strip 2 beyond the cover 1

during the insertion of an overlay band 3- The outer edge area 4 of

the cover clamp strips 2 are bevelled and form with the opposite steps of the U-shaped sub-frame profile 5 a gap 6. The leg of the sub-frame profile 5 directed towards the building body 7 rests on the flange-like edge areas of the collector plate 8 under the introduction of a laying band 9. The cover clamp strips 2 are above screws not shown firmly connected to the upwardly directed leg of the U-shaped subframe profile 5. The solar collector lies with the leg of the subframe profile 5 which carries the collector plate 8 on the U-shaped fastening profile 12 fixed to the building body 7 via screws 10,11.

By means of the tin screws 15 inserted through corresponding holes 13, 14 in the cover clamp strip 2 and the legs of the U-shaped subframe profile 5, the solar collector is screwed together with the upward-facing leg of the fastening profile 12. ■ On the back of the collector plate 8 there is an insulation layer 16 In the gap 6 between the chamfered outer edge 4 of the cover strip 2 and the step of the sub-frame profile 5, the raised longitudinal edge of the metal strip 17 attached to the building body 7 protrudes. The edge of the raised longitudinal edge of the metal strip 17 is directed outwards to a drip nose 18. A sealing profile 19 is sandwiched between the drip nose 18 and the opposite surface of the cover strip 2

In fig. 2, several solar collectors 19 arranged in a row in this way are inserted into openings in the building body 20, with a space 21 always present between two neighboring solar collectors 19.

In the space 21, as section I-1 in fig. 2 shows in fig. 3, arranged a metal strip 22 with upturned longitudinal edges, so that the longitudinal edges equipped with teardrop nose 33 project into it between the edged legs 23 of the cover joint strip 24 and the steps of the subframe profile 25 forming gap 26, The fastening profile 27 on the building body 20, on which the two solar collectors

lies, has in its central area a to'" profile of the metal strip

22 custom form. Between the edges of the longitudinal edge and the each time

opposite the horizontal surface of the cover clamp strip 24, a sealing insert 28- is sandwiched in.

Fig. 4 shows in perspective the crossing area of a in the drip direction with a metal running transversely to the drip direction. strip 29,30 with each time upturned longitudinal edges with drip noses 31, and partial omission of the cover clamp strip 32. The in drip

direction lying metal strip 29 has a greater depth than the metal strip 30 lying across the drip direction. The metal strip 30 running across the drip direction is interrupted and the two ends are soldered into corresponding recesses of the upturned longitudinal edges of the metal strip 29 lying in the drip direction

Claims (5)

1. Installation system for solar collectors, where each time the on the edge of the cover of a solar collector during the introduction of a laying band or the like applied, running around, laterally beyond these projecting cover strips are pre-stressed with the one on the edge of the underside of the collector plate during the introduction of a laying band or the like attached laterally above the collector plate projecting sub-frame profile resp. parts thereof so that between the front side and the subframe profile and the bevelled outer edge of the cover strip, a gap is formed, characterized by the fact that the solar collectors (19) each time with their subframe profile (5,25) lie at least in the area of their corners on the building body (7, 20) placed fastening profiles (12,27) and are firmly connected to these, as each time the space (21) formed between two neighboring solar collectors is arranged a metal strip (22) with upturned longitudinal edges, so that the longitudinal edges are brought up onto the fastening profile and the subframe profile and projects into the slot (6, 26). 2. Built-in system according to claim 1, characterized in that the metal strips (29) running in the dripping direction have a greater depth than the metal strips (30) running transversely to the dripping direction. 3. Installation system according to claims 1 and 2, characterized in that a sealing insert is arranged between the edges of the upturned longitudinal edges of the metal strips (17, 22, 29, 30) and an opposite surface of cover strips (2,24,32) (19,28). 4. Built-in system according to claims 1-3, characterized in that in the area of intersection of metal strips (29,30) arranged lengthwise and transversely to the dripping direction, the metal strip (30) running transversely to the dripping direction is interrupted and the ends are soldered into corresponding recesses of the drawn up longitudinal edges of the metal strip (29) running in the drip direction. 5. Built-in system according to claims 1-4, characterized in that on the sides of the solar collectors (19) located adjacent to the building body breakthrough, metal strips (17) that are edged up on one lengthwise side extend, each time the edged up lengthwise side of the metal strip is first up on the fastening profile (17) and the subframe profile (5) and protrudes into the gap (6), while the other part lies on the building body (7).