DE202007016366U1 - Solar module frame construction - Google Patents

Abstract

A stand construction capable of supporting solar panels on a roof with a sheet material as a topmost layer
- At least a first level, consisting of a plurality of substructure hollow profiles, which is arranged between the first layer of film material and at least a second layer of film material, which is connectable to the first layer of film material, fixed on the roof, and wherein on the first level a plurality of base profiles (2) is arranged forming a grid pattern,
A plurality of uprising profiles (3, 3 '),
characterized in that
- each two angled mutually arranged Aufständerungsprofile (3, 3 ') are fixed with one end to a base profile (2) and with a portion (3'') of the base profile (2) form a Aufständerungsrahmen,
A plurality of the elevation frames are arranged parallel to each other, so that two legs of two elevation frames (3) arranged parallel to one another form a bearing surface for at least one solar module,
- a ridge profile element (4) stabilizing over a plurality of ...

Description

The The following invention relates to a stand construction for elements for energy production from sunlight, in particular for solar modules.

STATE OF THE ART

Out the prior art are numerous systems for energy production known from sunlight on building roofs. So solar modules, also referred to as photovoltaic elements, used to extract electrical energy from sunlight. Here are the photovoltaic modules (PV modules) or solar modules with one as possible huge surface arranged on a support such that the sunlight on the modules as possible optimal. Dependent from the roof pitch, especially in relation to the energetic optimal sun position, it is often necessary, a substructure to create on which the modules are arranged and aligned to the sun can be.

The DE 20 2006 009 884 U1 describes a substructure for a photovoltaic system, in particular a device for arranging photovoltaic modules on a support surface. The disclosed subject matter is intended to provide a safe and cost-effective arrangement of PV modules on mounting surfaces, even on roofs, the installation surface, respectively the water-conducting roof skin, which should not be destroyed or impaired by the arrangement of the PV modules. It is therefore on attachment by means of screws, which would require a roof skin penetration, omitted. The disclosed device is therefore supported on a support surface such that in a region in which a photovoltaic module is arranged, the support surface is covered without support. By appropriate arrangement, the number of points at which the device is supported on the support surface or mounting surface is minimized; When measuring the number of interpolation points, the statics must be taken into account. The device comprises a cross member and a support member, wherein the PV module is disposed on the cross member and the support member, the cross member spaced from the support surface. Thus, a frame construction is provided on which the PV modules are arranged.

Corresponding the complexity the arrangement of known photovoltaic systems and the determination on the Roof can be such a facility in terms of safety unfavorable Weather such as storm or even with regard to any revisions and roof repairs as inadequate prove.

EPIPHANY

outgoing from this prior art, the present invention is the Task based, an improved stator construction for solar panels to arrange on a roof. This task is done by a device having the characterizing features of the independent claim 1 solved. Training of the device are claimed in the subclaims.

A first embodiment The invention relates to a stand construction suitable is to carry solar modules on a flat or sloped roof, which has a film material as the uppermost layer. The stand construction is made up of several levels, the lowest level consists of so-called substructure hollow sections, which between the aforementioned first layer of the film material already on the roof is present, and a second layer of film material over the Substructure hollow sections is placed connected. In order to The substructure hollow sections are advantageously stationary arranged on the roof and are at the same time firmly on all sides closed, which keeps them from getting wet protected are. On the enclosed between the film layers substructure hollow sections are Basic profiles arranged with the underlying level form an advantageous stable yet lightweight grid pattern. On the basic profiles become setting up frames applied, parallel to each other in a row on the roof be arranged so that in each case two legs of two parallel mutually arranged Aufständerungsrahmen advantageous as a support surface for a Solar module serve. On the side of the series of uprising frames, the opposite of the solar modules is one or more Windableitelemente arranged. Now, the mutually parallel Aufständerungsrahmen at its highest Points covered by a ridge profile element and advantageously stabilized, so over a water-bearing, undamaged Roof skin a stable, wind resistant solar module stand construction arises.

A another embodiment refers to that a plurality of rows of the aforementioned stand structures is arranged parallel to each other on a roof.

Further an embodiment relates that the film material, which the two film layers forms, introduced between the substructure hollow sections and waterproof, a bituminous roofing felt or another bituminous Foil, it is also possible to use a plastic film, are particularly suitable for this self-crosslinking or self-adhesive or even chemically crosslinking films or plastic films.

Finally, refers an embodiment that the Windableitelement is a flat Windableitblech, this in yet another embodiment on vibration dampers is stored such that advantageously a wind attack from the Windableitblechen can be derived without the stand construction with the on it attached solar modules takes damage. These and other advantages will become apparent from the following description and the accompanying drawings seen.

BRIEF DESCRIPTION OF THE FIGURES

Of the Reference to the figures in the description is for the support of Description. objects or parts of objects, which are essentially the same or similar are, can be provided with the same reference numerals. The figures are merely a schematic representation of an embodiment of the invention.

1a shows a sectional view of the stand construction arranged from the side on a roof.

1b shows a cross-sectional view of the base profile with Aufständerungsprofil recorded therein,

2 shows a schematic perspective view of a part of the stator construction with thereon Windableitblech and solar module.

3a shows a perspective view of the stator construction with ridge profile and Windableitelement.

3b shows the stand construction 3a , provided with solar modules.

3c shows the Windableitblech.

DESCRIPTION

The inventive stand construction is basically suitable to carry solar modules on a roof. Under one roof becomes basically below a building roof understood, the invention is particularly suitable for use on roof surfaces with a slope of up to 15 °. These require special fastening measures with regard to systems for the arrangement of solar modules, since they are not usually gegziegelt but a waterproof membrane with foil or roofing felt roofing exhibit. This roofing is intended to ensure waterproofness preferably not damaged when such a system is placed on the roof.

With "solar module" are below meant all elements that are capable of absorbing solar energy and convert it into electrical energy, often as photovoltaic elements designated.

The frame construction is suitable to be placed on a roof, which already wearing a foil layer. Of course can, if necessary, such a film layer also on the Roof are applied, if it is intended, the stator construction according to the invention to install on the roof.

For the construction the stator construction according to the invention will be first a variety of substructure hollow sections on the first Layer of water-bearing Foil material that already exists on the roof, arranged. The Arrangement is advantageously carried out so that the substructure hollow sections parallel to each other and at an angle or at an angle of 90 ° C too a ridge line of the roof. A second layer of film material will over the substructure hollow profiles arranged or stored on this, then the two layers of film material are joined together. Thus, the substructure hollow profiles are stationary on the Roof arranged and at the same time watertight on all sides.

at the foils may be a bituminous foil, a bituminous roofing felt or a plastic film, the use is also possible a self-crosslinking, self-adhesive or chemically crosslinking Plastic film, so that the two film layers, between which the substructure hollow profiles store easily and quickly permanently can be connected to each other.

Advantageous is thus under the substructure hollow sections a closed, waterproof roof covering in front, which is a watertightness of the roof even then ensures if the now top, second film layer is penetrated, for example, during the assembly of another element on the substructure hollow profile.

A plurality of basic profiles is now arranged on the welded - or firmly closed - substructure hollow sections such that a grid pattern is formed. 3b shows, however, without representing the film layers, a plurality of parallel arranged substructure hollow profiles, which in the present case are trapezoidal sheet hollow sections 1 is. On these are basic profiles 2 arranged so that a grid pattern arises. The basic profiles 2 can now on the trapezoidal sheet hollow sections 1 be fastened by screwing.

It is alternatively also possible to arrange a further film layer or at least at attachment points film strips on the film layer underneath and also with this to glue, to weld or otherwise connect to basic profiles 2 on the trapezoidal sheet hollow profiles 1 to fix. Advantageous are how out 1b apparent, the basic profiles 2 U-shaped cross-section: gluing or welding the base profiles 2 on the underlying substructure hollow sections should therefore be advantageous so that the U-shaped cross section is maintained.

Now there will be a variety of uprising profiles 3 . 3 ' on the basic profiles 2 arranged such that in each case two Aufständerungsprofile 3 . 3 ' with a section 3 . 3 '' of the basic profile 2 form an elevation frame. As shown in 3a . 3b . 1a and 2 , the upgrade profiles can 3 . 3 ' be arranged with each other so that with the section 3 '' of the basic profile an equilateral triangle ( 2 ) or alternatively a triangle with two long and one short leg. The provided number of Aufständerungsrahmen is arranged parallel to each other, so that in each case two legs of two mutually parallel Aufständerungsrahmen a bearing surface for a solar module 6 form. Thus, as shown in 3b , a series of solar modules 6 with solar module frame 6 ' tightly pushed on the mutually parallel Aufständerungsrahmen be arranged.

As shown in 1a . 2 . 3a and 3b , can be mounted on the side of the mounting frame, opposite to the solar panels 6 equipped side, a Windableitblech 5 to be ordered. Such a Windableitblech 5 advantageously results in that the stand construction is closed by the rear side with regard to the solar modules and protects them.

In order to further stabilize the arrangement of the Aufständerungsrahmen, is a Firstprofilelement 4 on the ridge, which is formed by the respective edge of the roof facing edges of the Aufständerungsrahmen arranged. This ridge profile 4 is particularly versatile as it holds, stabilizes, secures and secures the frames of a series of abutting solar modules; In addition, the ridge profile may be such that its edge facing away from the solar modules to a cable channel 7 ( 3a . 3b ) is bent over. This cable channel 7 serves advantageously to accommodate the cables coming from the solar modules 6 lead to a generator. Furthermore, the ridge profile 4 Serve that the wind deflector 5 attached to it. The wind deflector sheet 5 stands with its edge facing away from the ridge line of the stand construction on the basic profiles 2 on. It can be bolted to this, if necessary.

Advantageously, the Windableitbleche 5 be stored oscillating, so as to buffer gusts of wind, which act on the solar module stator construction. To make this possible, vibration elements or vibration absorbers at the coupling point between Windableitblech 5 and Aufständerungsrahmen or ridge profile are arranged. Such vibration absorbers are in 2 shown: At 2 it is a stand construction with a Aufständerungsrahmen from equilateral Aufständerungsprofilen 3 . 3 ' on a basic profile 2 are mounted to a Aufständerungsrahmen. The wind deflector sheet 5 is arranged on the opposite side of the equipped with the solar modules side, where it can be seen that the Windableitblech 5 by vibration damper 8th dampened directly on the uprising profile 3 ' is arranged or comes to rest.

An alternative option, the Windableitblech 5 to arrange is in 3a and 3b shown: The wind deflector 5 is not on the Aufständerungsprofil here 3 ' it is rather on the ridge profile 4 attached and stands only on the basic profiles 2 on. By using the Windableitbleche 5 Thus, it is possible to mitigate jerky effects of wind forces on the trapezoidal sheet metal hollow substructure. The with the solar modules 6 equipped side is protected, rear wind attack is prevented.

As shown in 1a become the ones through the uprising profiles 3 . 3 ' and the section 3 '' of the basic profile 2 formed Aufständerungsrahmen received in the advantageous U-shaped base profile, which is arranged on the substructure, that its open side facing away from the roof and thus the Aufständerungsrahmen between the two short legs of the U-shape can be introduced. Advantageously, a further stabilization of the Aufständerungsrahmen in the U-shaped base profiles by the introduction of self-tapping screws 9 obtained from the outside first by the short sides of the U-shaped base profile 2 and then into that of the U-shaped base profile 2 recorded elevation profile 3 . 3 ' penetration.

This provides a safe and stable stator structure resistant to wind forces, which ensures that the attachment of the stand construction does not damage the roof and that the lowermost water-bearing foil of the roof remains tight. With the freely selectable inclination of the stator for the solar modules also optimal current efficiency can be achieved. LIST OF REFERENCE NUMBERS 1 Trapezoidal metal hollow profile 2 basic profile 3 Elevation Profile 3 ' Elevation Profile 3 '' Section of the elevation framework 4 First profile element 5 wind deflector 6 solar module 6 ' Solar module frame 7 Cabel Canal 8th vibration

Claims (19)

A pedestal structure adapted to support solar modules on a roof with a foil material as a topmost layer, comprising - at least a first plane consisting of a plurality of substructure hollow sections interposed between the first layer of foil material and at least one second layer of foil material joined to the first layer of film material is connectable, is fixedly arranged on the roof, and wherein on the first level a plurality of basic profiles ( 2 ) is arranged forming a grid pattern, - a plurality of Aufständerungsprofilen ( 3 . 3 ' ), characterized in that - in each case two uprising profiles arranged at an angle to each other ( 3 . 3 ' ) with one end at a basic profile ( 2 ) and with a section ( 3 '' ) of the basic profile ( 2 ) form a Aufständerungsrahmen, - a plurality of Aufständerungsrahmen is arranged parallel to each other, so that two legs of two mutually parallel Aufständerungsrahmen ( 3 ) form a support surface for at least one solar module, - a ridge profile element ( 4 ) is arranged stabilizing over a plurality of mutually parallel Aufständerungsrahmen, - one of the support surface for the solar modules opposite side of two mutually parallel Aufständerungsrahmen is covered with at least one Windableitelement. frame construction according to claim 1, characterized in that a plurality of Rows of elevation frames arranged parallel to each other on the roof is arranged. frame construction according to claim 1 or 2, characterized in that the film material a bituminous Foil, a bituminous Roofing felt, bituminous sheeting or a plastic film, in particular a self-crosslinking, self-adhesive or chemically crosslinking plastic film. Stand construction according to one of claims 1 to 3, characterized in that the substructure hollow sections have a trapezoidal cross-section ( 1 ) exhibit. Stand construction according to one of claims 1 to 4, characterized in that the substructure hollow profiles trapezoidal sheet hollow sections ( 1 ), in particular galvanized enamelled trapezoidal sheet metal hollow sections, or aluminum trapezoidal sheets, with flanges formed integrally on both sides. Stand construction according to claim 5, characterized in that the trapezoidal sheet hollow profiles ( 1 ) has a length in the range of 3.0 m to 10.0 m, preferably a length of 5.0 m, a width in the range of 0.3 m to 0.7 m, preferably a width of 0.5 m, a Thickness in the range of 0.5 mm to 2.0 mm, preferably a thickness thickness of 0.75 mm, a depth of the cavity of 3.0 to 10.0 cm, preferably of 5.0 cm. frame construction according to one of the claims 1 to 6, characterized in that the substructure hollow sections substantially perpendicular or oblique to a ridge line of the roof run. frame construction according to one of the claims 1 to 7, characterized in that the basic profiles in the right Angle to a ridge line of the roof. Stand construction according to one of claims 1 to 8, characterized in that the Windableitelement a flat Windableitblech ( 5 ). Stand construction according to one of claims 1 to 9, characterized in that the ridge profile element ( 4 ) is folded over at a to the Windableitelement pointing longitudinal edge to a cable channel. Stand construction according to one of claims 1 to 10, characterized in that the ridge profile element ( 4 ) at a to the Windableitelement-facing longitudinal edge to a cable channel ( 7 ) is folded over. Stand construction according to one of claims 1 to 11, characterized in that the Windableitelement with a first longitudinal edge on the ridge profile element ( 4 ) and with a second longitudinal edge on a plurality of basic profiles ( 2 ). Stand construction according to claim 12, characterized in that between the first longitudinal edge and the ridge profile element and / or the second longitudinal edge and the base profiles ( 2 ) A plurality of vibration dampers is arranged. Stand construction according to one of claims 1 to 13, characterized in that the basic profile ( 2 ) has a U-shaped cross section and wherein an open side of the U is facing away from the roof. Stand construction according to claim 14, characterized in that the end of the on the basic profile ( 2 ) set up profile ( 3 . 3 ' ) in the U-shaped cross section of the basic profile ( 2 ) is recorded. Stand construction according to claim 15, characterized in that in the U-shaped cross section of the basic profile ( 2 ) end of the upgrade profile ( 3 . 3 ' ) with a screw ( 9 ), preferably a self-tapping screw ( 9 ), is attached. Stand construction according to one of claims 1 to 16, characterized in that the Windableitelement on the Aufständerungsprofil ( 3 ' ) rests. Stand construction according to one of claims 1 to 17, characterized in that the Aufständerungsrahmen the solar module ( 6 ) holds. Stand construction according to one of claims 1 to 18, characterized in that the ridge profile element ( 4 ) clamps an upper solar module transverse side.