WO2014075746A1

WO2014075746A1 - Mounting system for solar modules

Info

Publication number: WO2014075746A1
Application number: PCT/EP2013/000162
Authority: WO
Inventors: Martin Habdank
Original assignee: Habdank Pv-Montagesysteme Gmbh & Co. Kg
Priority date: 2012-11-13
Filing date: 2013-01-19
Publication date: 2014-05-22
Also published as: DE112013004091A5; DE202012104361U1

Abstract

The invention relates to a mounting system for solar modules (2), wherein the solar modules (2) are each individually enclosed in a module frame (16). At least two solar modules (2) are combined to form a self-supporting structural unit in that the module frames (16) thereof are connected by means of at least one module connector (11).

Description

Mounting system for solar modules

The invention relates to a mounting system for solar modules.

Solar modules have, in a known manner, a laminate structure in which solar cells are integrated. The individual solar modules are typically enclosed in module frames, which consist of metallic materials, in particular aluminum profiles.

The solar modules are used in large systems for power generation, these solar modules are arranged on this support structures, which form in particular outdoor facilities. Such a support structure is known from DE 20 2012 103 108 Ul. This supporting structure for solar modules comprises an arrangement of mounted on a substrate post. At each post, a carrier unit is pivotally mounted, wherein the carrier unit has two transverse bars carrying struts, whose ends facing away from the cross member are mounted in a pivot bearing. The cross member is slidably mounted by means of guide means on the post. On the cross member receiving means for the storage of solar modules are provided. By setting and fixing a pivot position of the carrier unit, the inclination of the solar modules is specified. An advantage of this support structure is that the struts with the cross member form a universal, suitable for different applications unit that can be quickly and accurately adjusted by pivoting the pivot bearing in their inclination. This results in a simple and reliable Neigungsverstellmöglichkeit of on this module pen stored solar modules. Since the same components are used in unaltered shape and arrangement for the tilt-adjustable unit with the struts and the cross member always results in a significant rationalization effect on the production of their construction. In this support structure, two longitudinal members are mounted on the cross beams, the longitudinal axes of which extend expediently perpendicular to the longitudinal axes of the mutually parallel cross member. The solar modules are then mounted on these side rails.

Thus, in this support structure, a single-row arrangement of solar modules lying side by side is realized.

The disadvantage here, however, that the number of solar modules that can be installed there is very limited by such a single-row arrangement of solar modules on the support structure.

Therefore, it is desirable to develop such support structures so that there can be installed several superimposed rows of solar modules. To realize this, must be mounted on the side rails transverse to these extending module carrier, on each of which the superimposed adjacent solar modules of a column are stored. Since at least one separate module carrier must be provided for the solar modules of a column, which also has to extend over the entire length of this column, the provision of the module carriers on the longitudinal carriers means an undesirably high cost of materials and costs. In addition, the assembly of the supporting structure is extremely complex.

The invention has for its object to provide a mounting system by means of which large-scale arrangements of solar modules can be realized with little design effort. To solve this problem, the features of claim 1 are provided. Advantageous embodiments and expedient developments of the invention are described in the subclaims.

The mounting system according to the invention is used for mounting solar modules, wherein the solar modules are each individually enclosed in a module frame. At least two solar modules are thereby combined to form a self-supporting structural unit in that the module frames of the solar modules are connected by means of at least one module connector.

The essential advantage of the invention is that the module connectors connect individual solar modules to form a stable, load-bearing structural unit, which can then be installed as a complete module on supporting structures. It is essential here that the module connectors form stable interfaces between the solar modules, so that these seams no longer have to be supported by carriers of the supporting structure. But this can be saved in the construction of the support structure such carrier, which leads to a considerable material and cost savings in the production of the support structure. Furthermore, the mounting of the support structure is considerably simplified, since this has a small number of parts by the saving of carriers. The module connectors ensure a rational, cost-effective connection between individual solar modules. In particular, the use of materials for the realization of these compounds is very low, since the module connector can be chosen considerably smaller than the lengths or widths of the solar modules. The module connectors connecting the two solar modules thus extend only over the adjoining edge regions of the solar modules and thus require a significantly lower use of material as a support of a supporting structure on which the solar modules rest over their entire length or width. Furthermore, the module connectors are advantageously connected to the module frame of the solar modules by adhesive bonds or screw connections.

Thus, the connections between the module frame of the solar modules and the solar modules can be made quickly and easily.

In general, the module frames of the solar modules can be structurally adapted to the module connectors.

Particularly advantageous to install the module connector no structural adjustments to the module frame must be provided, whereby the design effort for the mounting system according to the invention is further reduced.

According to a structurally particularly advantageous embodiment of the invention, the module connector is formed by a profile piece.

In the simplest embodiment, the profile piece forming a module connector has a receptacle into which the edge regions of the module frames of two adjacent solar modules can be inserted.

With the so-formed Moduiverbinder exactly two solar modules can be connected together.

According to a functionally extended embodiment of the invention, the profile piece forming a module connector has on two opposite sides in each case a receptacle into which the edge regions of the module frames of two adjacent solar modules can be inserted.

In this case, the receptacles of the profile piece are advantageously identical.

With the module connector designed in this way, four solar modules can be connected to one another. Of course, this module connector can also be be used that in its recordings only the module frame of a solar module is introduced, so that only two solar modules are connected to the module connector.

Particularly advantageously, the or each receptacle of a module connector is U-shaped. In the images thus formed, the module frame of solar modules can be easily inserted, thereby the solar modules are already prefixed, so that then simply and accurately the respective module frame in the module connector can be fixed by an adhesive or screw.

The module connectors, in particular the profile pieces as components of the module connectors, generally run along a straight line, since the solar modules and their module frames generally have a rectangular shape.

With the module connectors, solar modules, which in particular have the aforementioned rectangular shape, can be combined in different configurations to constructional units. In particular, the solar modules can be combined with the module connectors in rows, columns or matrix form to form assemblies.

The functionality of such units can be further increased by connecting two module connectors through a channel in which electrical lines are guided by solar modules.

Generally, at least one structural unit of solar modules connected via module connectors is arranged on a supporting structure.

In particular, the support structure on an arrangement of mounted on a support post, wherein at each post a support unit is provided with a cross member and are provided on the cross members transverse to these extending longitudinal members, wherein the at least one unit of is mounted directly on the side rails connected via module connector solar modules.

By virtue of the solar modules connected to the module connectors, module carriers which have to be mounted on the side members in the case of known systems for supporting individual solar modules can be saved.

The invention will be explained below with reference to the drawings. Show it:

Figure 1: exemplary embodiment of the mounting system according to the invention for solar modules as part of a support structure. FIG. 2: top view of the solar modules of the arrangement according to FIG. 1

Figure 3: Enlarged view of a portion of a solar module with an associated module frame.

FIG. 4 shows a variant of the arrangement according to FIG. 3.

FIG. 5: individual representation of a module connector for the assembly system according to FIGS. 1 and 2.

Figure 6: View of the module connector according to Figure 5 as a connection between two solar modules.

FIG. 7: Variant of the mounting system according to FIG. 2.

FIGS. 1 and 2 schematically show a section of an embodiment of the support structure 1 according to the invention for solar modules 2. The support structure 1 with the solar modules 2 forms an outdoor installation. The support structure 1 comprises a series of posts 3 arranged along a straight line, which are provided with longitudinal axes running in the vertical direction in one 00162

Underground 4 are anchored. Advantageously, the individual posts 3 are arranged equidistantly. The individual posts 3 are identical.

The support structure 1 of Figures 1 and 2 comprises two posts 3, wherein on the support structure 1 a total of six solar modules 2 are arranged in two superimposed rows. Of course, the supporting structure 1 can also have a larger number of posts 3 and a correspondingly larger number of solar modules 2.

As can be seen from FIGS. 1 and 2, the solar modules 2 arranged on the support structure 1 are arranged in a plane inclined with respect to the horizontal, the angle of inclination being approximately 30 °. In a field installation typically several such supporting structures 1 are provided and each aligned to the south.

As can be seen from Figures 1 and 2, a support unit 5 is pivotally mounted on each post 3 and thus adjustable in angle. The respectively identically formed carrier units 5 each comprise a cross member 6 and two struts 7a, 7b fixed thereto. On the cross member 6 side members 8a, 8b are applied, whose longitudinal axes are perpendicular to the longitudinal axes of the cross member 6. In the present case, two parallel longitudinal members 8a, 8b are provided on the cross member 6. The carrier unit 5 forms, as shown in Figures 1 and 2, a triangular construction, wherein the struts 7a, 7b are each secured with a longitudinal end to a longitudinal end of the cross member 6 and converge at an obtuse angle. In the present case, the struts 7a, 7b are firmly connected to the cross member 6 by suitable fastening means, that is to say the struts 7a, 7b form a rigid, dimensionally stable construction with the cross member 6. In principle, the struts 7a, 7 can also be connected in an articulated manner to the cross members 6. In the present case, the first strut 7a is shorter than the second strut 7b, whereby the carrier unit 5 is already adapted to a nominal tilt angle range of the cross member 6. 2013/000162

8th

The cross member 6 facing away from the free ends of the struts 7 a, 7 b are fixedly connected to each other and pivotally mounted by means of a pivot bearing on the post 3. The pivot bearing is formed in the present case by an anchored in the post 3 bolt 9 or the like. Thus, the support unit 5 is pivotally mounted with respect to a formed by the longitudinal axis of the bolt 9, fixed axis of rotation on the post 3.

Another connection between the carrier unit 5 and the post 3 is obtained by guide means on the cross member 6 and on the post 3. These guide means comprise a hole not shown in the cross member 6 and a pin 10 or the like on the post 3, which projects into the hole of the cross member 6.

The specification of the inclination of the carrier unit 5 takes place in that the position of the hole in the cross member 6 is specified application specific.

Alternatively, an inclination adjustability may be formed in the cross member 6 through a discrete series of holes into which the pin 10 is selectively inserted. Furthermore, instead of a discrete arrangement of holes in the cross member 6, a slot may be provided, in which the pin 10 is guided.

In the support structure 1 according to the invention of Figures 1 and 2 module connector 1 1 are provided, which connect the individual solar modules 2 to form a self-supporting unit. As a result, as shown in FIGS. 1 and 2, all the solar modules 2 can be supported directly and solely on the two side rails 8a, 8b as a structural unit, that is to say there are no module supports which would be provided on the side rails 8a, 8b.

As can be seen from FIG. 2, four module connectors 11 are provided for connecting the solar modules 2. The two outer module connectors 11 each connect an external solar module 2 of the upper row and an external solar module 2 of the lower row. The two central module connectors On the other hand, 1 1 connect two solar modules 2 of the upper row and two solar modules 2 of the lower row.

FIG. 3 shows a solar module 2 of the arrangement according to FIGS. 1 and 2. The solar module 2 is formed in a known manner as a laminate which has solar cells 14 mounted between foils 12, 13, a glass plate 15 being provided on the upper side of the arrangement.

The rectangular solar module 2 formed in this way is enclosed in a module frame 16 which rotates over the entire circumference of the solar module 2. The module frame 16 is formed as an aluminum profile. This aluminum profile forms on its upper side a recess 17 into which the solar module 2 is inserted. The aluminum profile further has a flat side wall 18, to which a hollow body 19 connects, which is bounded by segments of the aluminum profile.

The module frame 16 according to FIG. 3 forms a standard frame, that is to say a frame which has no specific adaptations for the module connectors 11.

FIG. 4 shows a modification of the arrangement of FIG. 3. This differs from the embodiment according to FIG. 3 solely in that a recess 20 is provided in the side wall 18 of the aluminum profile forming the module frame 16 as a specific adaptation to the module connectors 11.

Figure 5 shows an individual view of the module connector 1 1. The module connector 1 1 consists of a profile piece with a profile body 21, which has a rectangular cross-section. At the bottom of the profile body 21 includes a bottom part 22, which protrudes on opposite longitudinal sides on the profile body 21. Next connects to the top of the profile body 21, a ceiling part 23, which also protrudes on opposite longitudinal sides of the module connector 1 1 via the profile body 21. The thus formed Module connector 1 1 has a mirror-symmetrical cross section, which is constant over its entire length. The length of the module connector 1 1 is significantly smaller than the length or width of the module frame 16 of a solar module 2. By over the side walls of the profile body 21 perpendicular projecting segments of the bottom portion 22 and top portion 23 U-shaped receptacles are formed. These are adapted to the heights of the module frame 16. This allows segments of module frame 16 to be inserted into such a U-shaped receptacle and then fixed.

This is shown in FIG. There is a module frame 16 is inserted with a solar module 2 in each case a U-shaped receptacle of the mounting connector 1 1. The fixing of the module frame 16 in a U-shaped receptacle by means of a screw 24, which passes through the bottom part 22 of the module connector 1 1 and the aluminum profile of the module frame 16. 1. The module frame 16 of two adjacent solar modules 2 are generally inserted into a U-shaped receptacle of the module connector 11 and fixed there, in the case of the arrangement of FIG. 2 in each case a solar module 2 of the upper and lower rows. The two module frames 16, which are mounted in a U-shaped receptacle, lie there at a small distance of a few millimeters from one another. Since in each U-shaped receptacle of the module connector 1 1 two solar modules 2 can be mounted with edge regions of their module frame 16, four solar modules 2 can be connected to a module connector 1 1, as in the two central module connectors 1 1 of the arrangement of FIG the case is. In the outer module connectors 1 1 of the arrangement of Figure 2, a U-shaped receptacle remains free, since only two solar modules 2 are connected to these.

Figure 7 shows an extension of the arrangement according to Figure 2. Analogous to the arrangement of Figure 2, Figure 7 shows a mounting system consisting of six solar modules 2, of which three are arranged in an upper and three in a lower row. These solar modules 2 are again connected by means of four module the 1 1 connected to a unit. 2, in the arrangement of FIG. 7, the individual module connectors 11 are connected via channels 25, the individual channels 25 complementing one another to form a continuous channel strand. In the thus formed channel strand 25 electrical lines for the individual solar modules 2 can be performed.

HABDANK PV-Montagesysteme GmbH & Co. KG

73037 Göppingen, DE List of Reference Signs

(1) supporting structure

(2) solar module

(3) posts

(4) underground

(5) carrier unit

(6) Crossmember

(7a) strut

(7b) strut

(8a, 8b) side members

(9) Bolt

(10) cones

(1 1) Module connector

(12) foil

(13) foil

(14) solar cell

(15) glass plate

(16) Module frame

(17) recess

(18) Sidewall

(19) hollow body

(20) recess

(21) profile body

(22) bottom part

(23) ceiling part

(24) screw

(25) channel

PV mounting systems

Claims

HABDANK PV-Montagesysteme GmbH & Co. KG 73037 Göppingen, DE Patent claims

Mounting system for solar modules (2), wherein the solar modules (2) are individually enclosed in a module frame (16), characterized in that at least two solar modules (2) are combined into a self-supporting structural unit in that their module frame (16) is secured by means of at least a module connector (1 1) are connected.

Mounting system according to claim 1, characterized in that each mounting system is surrounded by a rectangular module frame (16).

Mounting system according to one of claims 1 or 2, characterized in that a module connector (1 1) only connects two solar modules (2).

Mounting system according to claim 3, characterized in that a module connector (1 1) connecting two solar modules (2) is arranged on the long or transverse sides of the module frames (16) of the solar modules (2).

Mounting system according to one of claims 1 or 2, characterized in that a module connector (1 1) connects four solar modules (2).

Mounting system according to claim 5, characterized in that four solar modules (2) connected by means of a module connector (1 1) form two superimposed pairs of solar modules (2) arranged next to one another.

7. Mounting system according to one of claims 1 to 6, characterized in that the length of a module connector (1 1) is significantly smaller than the length of a longitudinal or transverse side of the module frame (16) of a solar module (2).

8. Mounting system according to one of claims 1 to 7, characterized in that each module connector (1 1) is formed by a profile piece.

9. Mounting system according to claim 8, characterized in that the profile piece forming a module connector (1 1) has a receptacle into which the edge regions of the module frame (16) of two adjacent ones

Solar modules (2) can be inserted, or that the profile piece forming a module connector has a receptacle on two opposite sides into which the edge regions of the module frames (16) of two adjacent solar modules (2) can be inserted, the receptacles of the profile piece being identical are.

10. Mounting system according to claim 9, characterized in that the or each receptacle is U-shaped.

1 1. Mounting system according to one of claims 1 to 10, characterized in that the module connectors (1 1) are connected to the module frame (16) of the solar modules (2) by adhesive connections or screw connections.

12. Mounting system according to one of claims 1 to 1 1, characterized in that the module frame (16) of the solar modules (2) are structurally adapted to the module connector (1 1).

13. Mounting system according to one of claims 1 to 12, characterized in that two module connectors (1 1) are connected through a channel (25). the ones in which electrical cables from solar modules (2) are routed.

Mounting system according to one of claims 1 to 13, characterized in that a structural unit is provided in the form of a row, column or matrix-shaped arrangement of solar modules (2), each module frame (16) of adjacent solar modules (2) being connected by means of module connectors ( 1 1 ) are connected.

Mounting system according to one of claims 1 to 14, characterized in that at least one structural unit of solar modules (2) connected via module connectors (1 1) is arranged on a support structure (1), the support structure (1) being an arrangement of on a base ( 4) mounted post (3), a support unit (5) with a cross member (6) being provided on each post (3) and longitudinal beams (8a, 8b) running transversely to the cross members (6) being provided, whereby the at least one structural unit of solar modules (2) connected via module connectors (1 1) is mounted directly on the longitudinal supports (8a, 8b).