DE10136037A1 - Roof integrated solar module system has distance between plating arrangement and modules for ventilating the rear of modules and carrying away water - Google Patents

Abstract

The system has plate-shaped solar modules (2) with or without frames arranged adjacent to each other and attached to the roof by holders (6). A plating arrangement (4) is mounted below the solar modules on the roof or in the holder with a distance (7) between the plating arrangement and the modules for ventilating the rear of the modules and carrying away water.

Description

The present invention relates to a roof integrated Solar module system, especially for pitched roofs, according to Preamble of claim 1.

To use solar energy in building technology, it is known for a long time, on normal roof tiles or Roof tiles to attach solar panels and on the back interconnect with each other. Because of such an exposed location However, the solar modules on the surface of a roof can Faults and damage to the solar system can easily occur. Newer assembly forms for solar modules therefore see one Integration of the individual modules into the surface of the roof, d. H. Solar modules are instead of roof tiles in the Roof area used. This results in the solar modules some protection and a more appealing appearance.

DE 299 15 648 U1, for example, shows a solar brick in Modular construction known, the modules for mounting on the Underside are designed in the shape of roof tiles. Through this The solar modules can be shaped in different ways Adapt roof shapes and integrate them into the roof structure. The bottom is the corresponding specifications for this adapt to certain roof structures, creating a high Manufacturing effort arises.

To integrate the solar modules into the roof area are common also mounting profiles z. B. made of aluminum or plastic used, into which the individual solar modules are inserted can. It is possible to use frameless modules or modules To use edging. An arrangement is also known planar solar modules or laminates using shingle technology.

DE 195 02 215 A1 describes e.g. B. a roof integrated Photovoltaic module system described in the frameless Solar modules in cross rows between cross beams side by side are arranged horizontally. Adjacent modules of a respective Cross rows are connected to each other by clamping profiles, in the the modules are inserted loosely at the edge and with the help of a Filler profile can be clamped. At the bottom edge the modules are held by retaining clips on the cross beams attached so as not to slip. The modules in an upper row stand with their lower edge like a roof tile over the modules a row below.

However, solar systems installed through mounting profiles are common not installed watertight, for example at the edges the solar modules or on the holding devices water under the Penetrate roof surface. Therefore, it is necessary below the solar modules a device for draining the water provided.

From DE 196 12 489 C1 z. B. a photovoltaic system for Pitched roofs known, arranged on support elements has plate-shaped and frameless solar modules that are laid in a scale-like manner. Under the longitudinal edge of the In this solar system, solar modules are lower deck elements provided on which a trough-shaped watercourse is arranged is. Within these watercourses, this is on the edges of the Solar panels collected and penetrated by the water Roof slope led down.

However, it is e.g. B. possible through creep effects and wind pressure, not all at the edges of the individual modules penetrating water is collected in the watercourses. A Reduction of the edge areas within the solar system by the use of large-area solar modules or laminates is limited by the fact that large modules that are only on the edge be held, can bend in the middle area. This jeopardizes the reliable functioning of the modules. Ultimately, the modules may break. Further it cannot be ruled out that water is also present at unforeseen Penetrate where there is no drainage can such. B. if the solar modules are damaged Outside influences. This can lead to moisture penetration of the Roof area come.

It also comes with the integrated arrangement of the solar modules in the roof area to heat the modules. By a Such an increase in temperature will affect the performance of the Solar modules greatly reduced. It is therefore important to: Integrated installation of the solar modules in the roof area on a to ensure adequate ventilation of the entire solar system to to be able to use the modules optimally.

DE 198 02 997 A1 describes a roof structure for attachment and Attachment of solar modules shown. For this is on the roof an insulation element attached, the profile ribs on the surface has, on which by means of a holding device Solar modules are attached. Between the insulation element and the A cavity is provided for solar ventilation, its size is set by means of the height of the profile rib can be.

A structure for solar modules is known from EP 0 905 795 A2, of a variety of vertical support rails for has the modules that are attached to the roof panel and run in the direction from the ridge to the gutter. Between the solar modules are two such holding rails at a distance attached to the roof cladding. On the bottom of the Solar modules are deflection devices in staggered rows arranged to increase the speed of the air flow diminish that from the gutter to the ridge between the Roof lining and the solar module runs. Besides, they are Holding rails in the lower area with one over the entire Provide a lengthwise groove. In this groove, the Edge of the frame of the solar panels penetrating rainwater recorded and derived.

It is the object of the present invention roof integrated solar module system to create that despite integrated installation, adequate ventilation of the Solar modules and reliable water drainage and thus ensures tightness of the roof, simple and is inexpensive to assemble and adequate protection offers for the solar modules as well as the one to be carried by the roof Reduced weight. In addition, the optics of the system be designed appropriately.

This object is achieved by an integrated roof Solar module system according to the features of claim 1 solved. Preferred embodiments emerge from the subclaims out.

Accordingly, a roof-integrated solar module system shows plate-shaped solar modules with or without a frame that arranged side by side and by holding devices on the roof or are attached in the holding device, a sheet on, which is arranged below the solar modules on the roof. There is a between the solar modules and the cladding Distance to the rear ventilation of the solar modules and to Water drainage below the modules over the area of the Paneling.

The sheet according to the invention is used on any Spot water that has entered and trapped all over Surface of the sheet to the gutter or on the roof tiles derives. Water that is on a roof area above the Solar module system collects and over the roof towards the Solar module system expires, can easily over the sheet metal are derived, even if the water masses z. B. in strong Rain increase significantly. At the same time, by the distance a good one between the solar modules and the cladding Back ventilation of the modules guaranteed. This can cause a prevents excessive heat build-up on the solar modules by moving the heat through the air to the roof ridge is transported away, so that the performance of the modules is ensured.

Despite the installation of a roof-integrated solar module system the roof reliable through the sheet metal according to the invention sealed. Even if the Solar modules (sometimes the chemically hardened toughened glass the solar modules jump without exerting excessive force) remains the roof is watertight, because of the sheet metal is caught in an unforeseen place penetrates.

According to a further preferred embodiment of the present invention is the distance between the Solar modules and the sheet metal dimensioned such that the Modules less than 20 mm above the remaining roof area protrude. This is e.g. B. possible that a Sheet metal thin compared to other roof cladding can be interpreted. The solar modules can therefore be used for protection from external influences almost completely (depending on the Dachstein) can be sunk in the roof area.

Rectangular and plate-shaped solar modules are preferred shipped and arranged perpendicular to the ridge. By z. B. provided on the sheet metal holding devices the modules on their in the direction from ridge to eaves bleed edge, d. H. vertical, mounted on the roof. On the sheet can have at least one support for each Solar module or laminate can be arranged such that the Supported solar modules in a central area of their area become. Due to the large area of the solar modules, arises z. B. due to its own weight and in winter also by Snow load is a deflection of the modules or laminates. The supports can cause excessive bending of the Solar modules can be prevented. The supports are preferably to further protect the solar modules on their surface with covered with a plastic or rubber pad.

In a further preferred embodiment of the invention laminates are used, i. H. Solar modules without their own Frame. To hold these laminates are next to the Retaining device for the sheet metal, additional spacers can be used to reduce the impact between the laminates. In connection with the lamination according to the invention inexpensive, simple spacers can be used because a u. U. penetrating water through the sheet easily can be derived. According to the invention Spacers on a rubber surface and are z. B. H or Z-shaped.

The present invention allows conventional, already existing components can be used without modification. This enables quick and inexpensive installation to ensure. In addition, a good water drainage and rear ventilation of the solar modules ensured. Through the water drainage over the entire area the sheet is also the tightness of the roof unforeseen influences ensured.

A preferred embodiment of the invention is in the Drawing shown and is described below. in this connection demonstrate:

Fig. 1 is a schematic sectional view of a solar panel system according to the present invention; and

FIGS. 2a and 2b is a schematic view of the spacer according to the present invention.

In Fig. 1 is a simplified representation of the arrangement of the solar module 2 is shown with a roof-integrated solar module system according to the present invention. On the roof of a building that is to be supplied with solar energy, a sheet 4 is provided at least under the solar modules 2 . The sheet can also consist of plastic or the like. It is advantageous if the sheet metal 4 adapts to the shape of a part of a holding device 6 fastened to the roof, as is shown in an area 8 in FIG. 1. On the lateral edge areas and on the edge facing the ridge, the sheet metal protrudes into the roof covering 9 provided for the roof. At the edge facing the eaves, the sheeting can be designed such that it guides water that is collected and drained over its surface onto the surface of the remaining roof covering, from where it reaches the eaves via the roof covering or directly into the eaves become.

With the holding devices 6 , the solar modules 2 can be fastened over the sheet metal 4 . Conventional brackets can be used for this. It has proven useful to fix the individual solar modules by clamping them in the holding devices. In order not to damage the solar modules, the clamping device can be rubber-mounted. By clamping the solar modules, it is not necessary to screw the individual modules together, which means that they can be installed quickly and the risk of damage is minimized.

The holding devices 4 are distributed over the sheet according to the size of the solar modules 2 . The solar modules can be arranged in the longitudinal or transverse direction above the roof. In the present invention, solar modules with a size of 500-1200 mm width and 1000-2000 mm length and a laminate thickness of 4-8 mm are preferably used, but other dimensions are possible. The solar modules are frameless as laminates. The solar modules are preferably arranged transversely to the roof, ie with their long side parallel to the ridge above the roof and held on their narrow side by the holding devices 6 . This can, for. B. the required number of holding devices can be reduced.

With this arrangement, a deflection as described above can take place, in particular in the case of laminates in the central region. Therefore, in order to support the modules in a central area between the holding devices 4, at least one support can be provided on the sheet for each solar module 2 . The supports can be made of any material, they are preferably provided with a plastic or rubber surface at least on their surface on which the solar modules rest, so that damage to the solar modules can be avoided.

In the present invention, the individual solar modules are also arranged next to one another in the direction from ridge to eaves and not above one another in a shingle-like manner. In the joint area in which two adjacent solar modules touch, spacers 10 are provided according to the invention, in particular in the case of frameless laminate modules. For this purpose, for example, solid rubber elements or metal elements with a rubber coating can be used.

In Fig. 2a an H-shaped spacer 10 is shown, which receives the respective edge of adjacent solar modules 2 and 2 'in its recesses 12 and 12 '. A Z-shaped spacer 10 is shown in FIG. 2b. The spacer 10 has a lower web 14 on which a solar module close to the ridge rests. The lower web 14 is connected via a connecting region 16 to an upper web 18 which projects over an adjacent solar module 2 'which is close to the eaves. Water that u. U. penetrates at the boundaries between the spacer and solar modules, is caught by the sheet metal 2 and derived in the direction of the eaves.

The sheeting according to the invention is arranged on the roof substructure in such a way that the solar modules which are completely mounted on the sheeting only protrude slightly beyond the remaining roof area. The solar modules are preferably less than 10 mm or 20 mm beyond the roof surface, but further, larger distances are also possible. Due to the thickness of the roof covering used, such as brick, and the thin sheet metal used, no special precautions are necessary. The space remaining between the solar modules and the cladding serves for the problem-free drainage of water that has penetrated under the solar modules 2 . The water can be guided almost unhindered over the entire surface of the sheet in the direction of the eaves. At the same time, the space provides sufficient ventilation for the solar modules so that they do not heat up excessively and the performance of the modules is not impaired.

With the present invention, a roof integrated Such a solar module system in a cost-effective and fast manner be mounted on a roof that the tightness of the roof is guaranteed.

Claims (9)

1. Roof-integrated solar module system made of plate-shaped solar modules with or without a frame, which are arranged next to one another and are attached to the roof by holding devices, characterized in that a sheet ( 4 ) is provided below the solar modules ( 2 ) on the roof or in the holding device ( 6 ), wherein between the solar modules ( 2 ) and the sheet ( 4 ) there is a distance ( 7 ) to the rear ventilation of the solar modules ( 2 ) and to the water drainage below the solar modules ( 2 ) over the surface of the sheet ( 4 ). 2. Solar module system according to claim 1, characterized in that the sheeting ( 4 ) extends over the entire roof area covered by solar panels ( 2 ). 3. Solar module system according to claim 1 or 2, characterized in that the distance ( 7 ) is dimensioned such that the solar modules ( 2 ) protrude less than 20 mm or 30 mm beyond the remaining roof area. 4. Solar module system according to claim 1 to 3, characterized in that on the sheet ( 4 ), the holding devices ( 6 ) receive the solar modules ( 2 ) at the edge and at least one support for each of the solar modules ( 2 ) in this way on the sheet ( 4 ) is arranged that they support the solar modules ( 2 ) in a central area. 5. Solar module system according to claim 4, characterized characterized that the supports a plastic and / or have rubber surface. 6. Solar module system according to one of the preceding claims, characterized in that in addition to the holding device ( 6 ) the sheet ( 4 ) for holding frameless solar modules, spacers ( 10 ) are provided between adjacent solar modules ( 2 ). 7. Solar module system according to claim 6, characterized in that the spacers ( 10 ) are H or Z-shaped. 8. Solar module system according to claim 6 or 7, characterized in that the spacers ( 10 ) have a rubber surface. 9. Solar module system according to one of the preceding claims, characterized in that the sheet ( 4 ) consists of plastic.