WO2011045177A1

WO2011045177A1 - Carrying assembly for photovoltaic modules

Info

Publication number: WO2011045177A1
Application number: PCT/EP2010/064301
Authority: WO
Inventors: Tobias Helf; Christian Koitzsch; Thomas Christall
Original assignee: Robert Bosch Gmbh
Priority date: 2009-10-14
Filing date: 2010-09-28
Publication date: 2011-04-21
Also published as: EP2488801A1; DE102009052001A1

Abstract

The invention relates to a carrying assembly for photovoltaic modules, in particular large-area, thin-film solar modules, having a driven ground support and a connection means which is located between the upper end of the support, which is remote from the ground, and the lower face of the module. According to the invention, the connection means is affixed in the center of gravity of the respective module and designed as a sleeve or plug-in part, wherein the contour of the sleeve or plug-in part is complementary to the outer or inner contour of at least one fastening section of the driven ground support in order to affix the module to the support such that it is secured against rotation.

Description

Support arrangement for photovoltaic modules

description

The invention relates to a support arrangement for photovoltaic modules, in particular large-area thin-film solar modules, with a Rammbodenstütze and a connecting means, which is located between the upper, distal end of the support and the module base, according to the preamble of patent claim 1.

From DE 20 2006 011 393 Ul a support arrangement for solar systems is already known, which receives a plurality of solar modules. The previously known

Supporting system comprises a plurality of spaced in a row in a horizontal longitudinal direction floor supports with an elongated longitudinal direction

extending carrier assembly a uf, said Trägeranordn ung contacted mechanically with the floor supports via connecting elements. Furthermore, transversely to the longitudinal direction and against the horizontal inclined inclined Modu lträger exist on which rest the solar modules. Specifically, the side rail assembly has two spaced apart from the longitudinal direction

Longitudinal support on and there are the module carrier each at the two

Longitudinal beams held. The design effort for the respective solar module is significant, which leads to a deterioration of the cost-benefit aspect when building a solar system based on this technology.

Also, the support structure of a solar array for one or more

Solar modules according to DE 203 19 065 Ul goes from longitudinally spaced, anchored to the base first carriers, at least one in

Longitudinally extending side member, which is attached to the first carriers, and a plurality of longitudinally spaced, transversely to

Longitudinal direction and inclined to the horizontal in a transverse direction extending cross members, which are mounted on the side rail, from. All the above-mentioned constructive elements must be mechanically connected, usually screwed be screwed, which entails considerable time for the construction of a large-scale solar system and thus in turn increased costs.

In the utility mouser DE 20 2007 016 396 U l is oriented with the aim of simplifying the manufacturing and erection expenses on a concrete element for a foundation-free installation of solar cells on surfaces, in particular outdoor facilities. The concrete element consists of a molded stone element and arranged troughs for hanging

Transport systems. Furthermore, attachment points for holding the structure are present, on which the solar cells are fixed there nn. The weight of the concrete block should be sufficient to compensate for wind and snow loads, so that an overall system based on such

Supporting elements can not be destroyed by the aforementioned loads.

In the system for fixing roof components including those containing solar cells, according to DE 103 29 184 AI, the components to be joined are each provided at the connection points with the corresponding parts of a pressure-acting adhesive connector. These corresponding parts of the adhesive connector are flexible and attachable by gluing. It is also possible to attach the corresponding parts of the Haftverbi countries positive fit. By such Velcro connection techniques to be given the opportunity, ei ne assembly of the components vorzuneh men without special tools.

The mounting system according to DE 20 2008 015 237 U l is aimed in particular at frameless thin-film modules. This known system has two profile-shaped cross rails, which are arranged spaced apart parallel and si nd for holding a plurality of photovoltaic modules provided. Each of the cross rails has a flat support surface. Furthermore, there are a plurality of holders each rigidly connected to the back of a module using an adhesive. The respective photovoltaic module is mounted by means of the holder on the cross rails, to which each cross rail at least one holder is assigned and each holder has a recess and each cross rail has an integrated projection. In order to prevent a displacement of the holder against the joining direction, a retaining device is provided between at least one transverse rail and a holder associated therewith. The holders should be in places in the

Plane interior of the back of the PV module are arranged, which are chosen so that the module undergoes minimal deflection in the position of use.

Regardless of the holder provided requires the mounting system to DE 20 2008 015 237 Ul a supportive, net-like and thus very

elaborate supporting structure.

From the above, it is therefore an object of the invention, a further developed support structure for photovoltaic modules, in particular large-scale thin-film solar modules, with a Rammbodenstütze and a

Connecting means, which is located between the upper, distal end of the support and the module base to specify, the

Traganordnung one hand, based on the solar system total system only low production costs entails and on the other hand, the

Expenses for the assembly of a variety of solar modules for or when building a solar power plant is minimized.

The object of the invention is achieved by a support arrangement for photovoltaic modules according to the feature combination according to claim 1, wherein the dependent claims represent at least expedient refinements and developments.

The invention described in the claims teaching applies

especially in the attachment of solar modules in open space systems, in which case the challenge is to achieve the most cost-effective attachment of the solar modules, with an orientation to the south with an angle of inclination, which depends on the latitude of the plant to be built, has to be done. In addition, a minimum distance to the underlying soil should be given to avoid unwanted shading of the solar cells by plant growth. Ultimately, the attachment of the solar modules should be so stable that the overall system

sustained attacking wind and / or snow loads permanently. The

inventive support assembly has as connecting means between Rammbodenstütze and the respective photovoltaic module on a sleeve or a male part, wherein the contour of the sleeve or male part of the outer or inner contour of at least one mounting portion of Ra mm ground support kom is plementär to fix the module against rotation on the support in a simple manner by eg plugging on can .

Furthermore, according to the invention, a single Rammbodenstütze is provided for each solar module, forming within a field of solar modules, a solar system, the individual modules are not mechanically interconnected, as is the case in the prior art.

Sleeve or plug-in part and outer or inner contour of the Rammbodenstütze are preferably deviating from the circular cross-section to prevent twisting of the respective solar module about the longitudinal axis of the floor support without additional securing means.

In one embodiment, the respective solar module can have a frame, which on the force side is part of the connection means.

In particular, the frame may have at least one supporting beam.

The sleeve or the male part is then attached to the frame and / or the supporting beam, preferably cohesively.

In a further embodiment, frameless thin-film modules are used as so-called glass-glass laminates for the solar module. In this case, there is the possibility that the sleeve or the plug-in part is directly materially connected to the back of the glass-glass laminate.

The sleeve or the plug-in part is at a selectable angle between the longitudinal axis of the sleeve or plug-in part and the surface plane of the respective one

Solar module fixable to this. This prefabricated sleeves or plug-in parts with a mounting surface as a standardized component

Find use. Depending on the degree of latitude, these prefabricated, standard components have a defined angle at the intended place of use, which corresponds to the desired tilt angle. In the production finalization of the solar modules then the respective sleeves or plug-in parts can be fixed according to the specification of the purchaser. The assembly of the solar modules would thus be based on plugging or plugging in on the on-site ramming floor support.

In the elevated state, the solar modules should have the smallest possible distance to the ground surface, the choice of the distance is only vegetation-dependent.

In addition, the individual solar modules of a solar system

shaded each other complained set up, the respective distance in horizontal, d. H . lateral direction, for the purpose of reducing the total wind load is also to be minimized.

In a preferred embodiment, a meta llischer profile post, in particular sigma post is used as Rammbodenstütze.

The invention will be explained in more detail below with reference to an embodiment and a schematic diagram (Figure).

Known solutions of the prior art aim, as described above, dara uf from, for open space solar systems initially net-like supporting occupancy fields to create with south-facing. The formed net-like arrangements, which are partially adapted to the external dimensions of the solar modules to be installed, are then occupied with individual modules.

Due to the market introduction of silicon thin-film solar modules with very large dimensions of up to 6.0 m ² and greater, but still low efficiency of the usual constructive approach to the attachment and training of ground-mounted systems is not economically justifiable.

The essential basic idea of the invention consists in the departure from net-like support structures for fixing each individual solar module with the aid of a mound fund, in particular a pile bottom support, whereby each individual module then has a connection to the respective ground anchor or the pile bottom support , The proposed solution according to the invention therefore decouples via the individual attachment of the solar modules to the respective ground anchor module geometry and module efficiency of the resulting costs. For this reason, the system is particularly suitable for large solar panels with lower surface efficiency, which could not take advantage of module size in alternative systems in planar support, due to high

Elevation costs.

As can be seen from the figure, each large-area thin-film solar module 1 has a connection means 2 which is fastened to the underside of the solar module 1.

The connecting means 2 is in the example shown in a sleeve 3 over.

The inside opening of the sleeve 3 is matched to the outer diameter of a Rammbodenstütze 4. As Rammbodenstütze 4 a known per se Sigma post can be used, which is driven sufficiently deep into the soil 5.

In the example shown, the longitudinal extent of a solar module 1 about 130 cm.

The smallest distance between the lower edge of the solar module 1 and the surface of the ground 5 is e.g. at> 55 cm.

This distance is matched to the expected growth. In order to minimize occurring wind loads, however, the principle applies to keep the height of the elevation basically low. Also, the distance of the individual modules 1 with each other only under the aspect of shading, which must be avoided to be specified. Again, wind suction and / or pressure forces are reduced if the individual solar modules are as close as possible and thus form a quasi-closed area.

In addition to the cost advantage arises in view of the sleeve according to

Embodiment a lower installation costs for Rammfundamente due to relaxed requirements regarding accuracy

Positioning and angularity.

Furthermore, the assembly effort is reduced by the fact that the sleeve acting as an adapter or the plug-in part is preferably materially connected to the module on the production side. This only a Aufsteck- and Arretiertätigkeit in the field is necessary. With regard to the principle of the individual elevation of the effort in adapting to different terrain topographies is significantly reduced. It is also possible to use it on unstable substrates such as landfills or landfills. Because of that

Total height is minimized, there is only a minor impact on the landscape.

Claims

claims

1. support assembly for photovoltaic modules, especially large area

Thin-film solar modules, with a Ram floor support and a

Connecting means, which is located between the upper, distal end of the support and the module base,

characterized in that

the Verbindungsm ittel fixed in the center of gravity of each module and is designed as a sleeve or plug-in part, the contour of the sleeve or male part of the outer or inner contour of at least one Befestigungsa section of the Rammbodenstütze is complementary to the module against rotation to fix the support.

2. Support arrangement according to claim 1,

characterized in that

a single Rammbodenstütze is provided for each solar module, wherein forming a solar system within a field of solar modules, the individual modules are not mechanically interconnected.

3. Support arrangement according to claim 1 or 2,

characterized in that

Sleeve or male part and outer or inner contour of the Rammbodenstütze deviating from the circular cross-section are formed.

4. Support arrangement according to one of the preceding claims,

characterized in that

the respective module rah is designed without a menue or comprises a frame, which on the force side is part of the connection means.

5. Support arrangement according to one of the preceding claims,

characterized in that

the frame has at least one supporting beam.

6. support arrangement according to claim 4 or 5,

characterized in that

the sleeve or the plug-in part is firmly bonded to the frame and / or the supporting beam or directly to the rear side of the frameless module.

7. Support arrangement according to one of the preceding claims,

characterized in that

the sleeve or the plug-in part is fixed at a selectable angle between the sleeve or plug-in longitudinal axis of the surface plane of the respective solar module at this.

8. Support arrangement according to one of the preceding claims,

characterized in that

in the elevated state, the lowest point of the respective solar module has only a vegetation-dependent, smallest possible distance to the ground surface.

9. Support arrangement according to one of claims 2 to 8,

characterized in that

the individual solar modules of a solar system are set up free of shading spaced, the respective distance for the purpose of reducing the total wind load is minimized.

10. Support arrangement according to one of the preceding claims,

characterized in that

the Rammbodenstütze is designed as a metallic post, in particular sigma post.