EP2475939A1

EP2475939A1 - Module arrangement consisting of solar modules

Info

Publication number: EP2475939A1
Application number: EP10754306A
Authority: EP
Inventors: Wadim Salzer
Original assignee: Schueco International KG
Current assignee: Schueco International KG
Priority date: 2009-09-10
Filing date: 2010-09-07
Publication date: 2012-07-18
Also published as: WO2011029824A1; ES2479644T3; US20120174913A1; AU2010294274A1; AU2010294272A1; CA2771684A1; US20120222727A1; EP2475940A1; CA2771682A1; EP2475940B1; DE202010012272U1; WO2011029822A1

Abstract

The invention relates to a module arrangement having the following: at least one or a plurality of double module arrangements each consisting of two solar modules which are oriented at an angle to each other; wherein the edges (3) of each double module arrangement facing away from each other are not interconnected via a support strut.

Description

Module arrangement of solar modules

The invention relates to an arrangement of solar modules on surfaces, in particular roofs, according to the preamble of the claim.

Generic module arrangements are known from DE 100 47 400 C2 and from DE 20 2008 007 549 U1. These documents each disclose Soiarmodulan- orders, which are arranged by means of mounting devices in a so-called folding arrangement on a roof, such that they form a zigzag arrangement in a side view. This type of zigzag arrangement makes it possible to completely or almost completely cover a roof surface with solar modules, which optimizes energy production, in particular when the folding or zigzag arrangement is oriented in an east-west direction.

Unfortunately, in the case of the two abovementioned constructions and, more generally, in the state of the art-the DE 10 2007 000 697 A1, DE 295 03 315 U1 and DE 199 34 059 A1 being called the technological background, the high use of material in terms of their properties on the mounting devices or substructure. In particular, the known mounting devices on relatively many components and components.

Against this background, it is based on the generic prior art, the object of the invention to simplify the generic arrangement with respect to their substructure and with respect to the mounting device.

The invention solves this problem by the subject matter of claim 1.

Advantageous embodiments of the invention can be found in the dependent claims.

According to claim 1, the expensive supporting profile required according to the state of the art, in particular the lower support profiles or cross members, or even base support elements, can be dispensed with. called aspiration. This results in cost savings and simplified assembly.

The invention provides as a development, which is also regarded as a separate invention, the following object: A module assembly, in particular according to claim 1 or according to Merkmai a) of claim 1, wherein adjacent double module arrangements via at least one or more coupling devices with each other are connected, which rest on a substrate and are not fixed there with fastening means, wherein at each anti-sliding means at least two edges of two adjacent double module arrangements are arranged or fixed, preferably four of the edges.

The term of soiarmoduie includes solar elements of various kinds, which form a kind of preassembled module and which serve to generate energy in the form of electricity and heat. The inventive type of mounting (arrangement) is thus suitable for both photovoltaic module ais also for thermic collectors and can preferably be arranged on flat roofs or pitched roofs, but also on any open spaces. Further advantages are the aerodynamic arrangement of the solar modules, which eliminates weighting or anchorages.

In addition, however, it is additionally provided according to a particularly advantageous variant of the invention that adjacent to each other Doppelmodulanordnungen - in Zusammenspie! then form a kind of zig-zag arrangement - connected to each other via coupling devices.

According to the mentioned particularly preferred variant of the invention, these coupling devices again form anti-slip devices, ie, they counteract sliding on a substrate. They are preferably based on a substrate without a fastening means and are preferably designed such that they have a relatively high static friction to the ground. As a rule, weight-bearing weights are not required. In this case, at least two edges of two adjacent double module arrangements are arranged or fixed on each anti-slip device, preferably four of the edges, so that mutually adjacent, adjacent double module arrangements are connected to one another in the region of the adjacent lower edges via the coupling devices or elements designed as anti-slip devices. In this way, a simple mounting of the solar modules allows and still realized a stable and secure division.

Although non-slip devices for setting up solar modules on a flat surface are known per se, so from DE 10 2007 000 697 A1. However, it has not been recognized in this document that it is also possible in a simple manner to use such anti-glide devices directly for coupling adjacent dual-solar module arrangements. As a result, an aerodynamically closed and essentially "closed" surface can be created which eliminates the weight and the like for complicating the solar module arrangements, nor does it pose the problem of setting up double stereo arrays, which are generally relatively large and heavy in the document only solar module arrangements are disclosed, each with a pointing to a direction of the solar module.

It is also expedient and structurally particularly simple if the anti-slip devices are coupled via at least one further connector to one or more double module arrangements.

It is also particularly advantageous if the anti-slip devices also take over the function of a load transfer of Doppelmoduianordnungen in the underground.

Particularly preferably, the anti-slip devices are designed such that the distance between the lower edges of adjacent double module assemblies is 50 to 500 mm, preferably 300 mm, which in turn simplifies maintenance.

Preferably, the anti-slip devices are further configured such that the gap between mutually adjacent dual module arrangements is accessible. According to a further preferred variant, under the solar module, in particular under glass-glass thin-film laminate modules, at least one profile is arranged, which has one or more chambers, which is designed to receive the connector / are.

In the following, again some advantages of the invention are listed.

What is created is a mounting arrangement that makes do in a preferred design without additional ballast and or attachment to the ground.

The mounting arrangement is particularly suitable for unframed solar panels (laminates, preferably thin-film laminates of double safety glass).

A separate substructure, which is attached to the building, is not necessary, because the module supports and supports itself also on wind deflectors can be omitted.

It is an arrangement with a very high Fiächenanteil of Soiareiementen created, which is characterized by a controlled, unobstructed water drainage, good accessibility in the revision passages and a simple and safe cable routing in the revision gears.

Particularly advantageous as a development of the subject matter of claim 1, but also to consider as a separate invention is the anti-slip device used to maintain the row spacing, which serves as a pressure element and also for receiving horizontal shear forces, e.g. by wind, and to connect at least two, lower solar element edges.

The anti-skid device is preferably designed as a support plate for load transfer.

The connecting angles are preferably made of stainless steel and are clamped in profile grooves and in profile grooves preferably a profile of solar modules in training as laminates with a profile which is referred to as a so-called backrail (frameless elements). It may be provided for receiving the pressure forces preferably between the profits or between the connectors, a tension element such as a pull rope. is provided.

The invention will be explained in more detail with reference to an embodiment with reference to the drawing. It shows:

Fig. 1 is a perspective view of one of an inventive

Mounting arrangement formed arrangement of solar modules on a flat roof;

FIG. 2 is a side view of a series of solar modules; FIG.

3 and 4 are each a side view of a multi-row solar module assembly and a plan view of this solar module assembly.

Figure 5 is a sectional view of a profile;

Figure 6 is a sectional view of a connector;

Figure 7 is a sectional view of another connector;

FIGS. 8A, B show a side view and a perspective view of an antislip device;

Figure 9 is a perspective view of another anti-skid device; 10a, b show a front view and a side view of a double-row solar module arrangement;

Fig. 1 1 a, b is a side view of a connector and a plan view of this

Interconnects;

Fig. 12a, b is a side view of another connector and a plan view of this connector; and

Fig. 13 is a view of a pull rope.

FIG. 1 shows a module arrangement according to the invention which has at least two-as in FIG. 2-or a multiplicity of solar modules 1.

To simplify the discussion, FIGS. 2 and 3 are provided with a Cartesian coordinate system. In this case, the coordinates X and Y respectively describe the coordinates of the surface or installation surface assumed here for the solar modules and the supplementary coordinate Z the coordinate perpendicular thereto. at a flat roof or other flat surface, the X and Y coordinates correspond to this area, whereas the Z coordinate is the vertical coordinate. From this orientation, the following terms such as "top" or "bottom" explain, but are not limiting, especially since the invention is also suitable for obliquely oriented surfaces such as a pitched roof.

It should be noted that although the term of the solar module is used throughout, it is to be understood as representative of modules of various types, such as solar cell modules or thermo modules.

The solar modules 1 of FIG. 1 preferably have a relatively flat, rectangular basic shape. In each case two of the solar modules 1 are coupled to one another by means of connectors 6, 7, which are shown by way of example in FIGS. 6 and 7, such that two of the solar modules lie in pairs in the region of one of their outer edges 3 and thereby enclose an angle α, which is preferably - but not mandatory - is greater than 90 °.

Preferably, a plurality of such double module arrangements in a row (direction X) are arranged one behind the other. In addition, it is possible to arrange a plurality of these rows of double modules next to each other (direction Y) on a substrate such as a roof in order to cover a roof surface or the like as desired, in particular also over the entire area, with solar modules.

From this type of arrangement results in the name zigzag arrangement or folding arrangement.

Compared to the prior art, the substructure has been considerably simplified.

The double module arrangements are connected to each other in the mounting arrangement according to the invention in each case at the mutually facing, vertically vertical upper edges 2, but not in the region of the lower edges 3 facing away from each other. Instead, in the mounted position, a connection is realized by the ground itself. An additional connection to the ground in the region of the lower edges facing away from each other is, however, not present within a double-module arrangement or is saved.

Compared to the prior art, as it is known from DE 20 2008 007 549 U1, so a double module assembly is created with a significantly simplified structure, because of the existing there intermediate carrier or profiles that connect the lower facing away from each edge of each double profile arrangement , can be dispensed with. Preferably, no additional support strut is present in the area between the connectors 6, 7 and the lower edges 3.

Adjacent, adjacent double module arrangements are also connected to each other in the region of the adjoining (here lower) edges 3 via coupling devices or elements. These coupling elements preferably realize such a spaced connection of the lower edges 3 of adjacent Doppelmoduianordnungen that good accessibility to the dual module arrangements is ensured for assembly purposes or maintenance.

Preferably, the distance between the lower edges 3 of the adjacent double module assemblies is 50 to 500 mm, preferably 300 mm. The distance between the lower edges 3 is preferably predetermined by one or more coupling devices.

It is advantageous and has a stabilizing effect on the construction when the anti-skid device is roughened on one side or is provided with a friction-increasing coating.

Below, preferred embodiments of these coupling elements are considered in more detail. In a particularly preferred embodiment, the coupling elements or devices form one-piece or multi-piece anti-gliding devices 4 (see in particular FIGS. 8 to 9).

The anti-skid devices 4 are preferably not only designed to realize an anti-skid device for the dual module arrangements but also take over the function of load transfer into the ground.

At least two edges 3 of two adjacent double module arrangements are preferably arranged or fixed on each anti-sliding device 4, preferably four of the edges 3, so that four of these solar modules can be mounted or mounted corresponding to each anti-sliding device.

FIG. 2 shows a series of double module arrangements in a side view, the solar modules 1 being set up at an angle to one another as described with reference to FIG. The upper edges 2 are kept at a small distance. Below the solar elements 1 {here a glass-glass thin-film laminate), profiles 5 are preferably aluminum profiles, which preferably have chambers which serve to receive the connectors or other fastening means.

At the upper edges 2, a connector 6 is inserted into the recesses of two adjacent Soiarmodule 1.

The connector 6 is - see Fig. 6 - preferably formed as a one-piece elbow and has two legs 11, 12, which enclose the angle α.

In the preferred case, this angle α is 160 °. As a result, the solar elements 1 an oblique inclination or orientation of 10 degrees to a flat - for example, horizontally oriented - surface.

The lower edges 3 of adjacent double module assemblies are also directed towards each other in a larger colector field. For assembly, a connector 7 is also inserted into the profile 5 at the lower ends. In this way, the connector 7 is fixed to the profile 5 and thus to the solar module. It is conceivable that profile 5 and screw the connector 7 together. On the side remote from the edge 3 or the profile 5, on the other hand, the connector 7 is connected to one of the anti-slip devices 4.

This anti-slip device of FIG. 8 is a particularly preferred embodiment. In addition, embodiments of the invention are also conceivable in which the lower edges 3 of the Soiarelemente 1 are directly connected.

The anti-skid devices 4, preferably used, absorb compressive forces applied by the individual rows of modules through the 10-degree arrangement. Overall, the pressure forces cancel.

The anti-slide 4 are preferably provided with projecting pins 8, preferably threaded pins on which the connectors 7 are easily placed with corresponding holes for easy installation. It is then only necessary to screw the connector 7 with a nut on the anti-skid on the screws 8.

In addition, the anti-skid devices 4 preferably form a so-called revision gear between adjacent double-module arrangements, which considerably simplifies maintenance-as already mentioned-of the module arrangement.

Figure 2 illustrates that no further Profiimontagetragsystem, no further cross member within the Doppelmoduianordnungen, no support struts or the like as described in the prior art are required.

The zig-zag arrangement is particularly preferably only by the anti-slide device 4 between adjacent Doppelmoduianordnungen, a connector 7 between the Geitsicherungseinrichtung 4 and the Doppelmoduianordnung, a profile 5, on which the solar module is arranged, a connector 6 between the upper edges or profiles 5 adjacent Solar modules of a dual-mode arrangement formed. This can in turn be followed by connectors 7, anti-slip devices 4, etc. In particular, at the ends of larger Moduifelder can be arranged to accommodate the compressive forces between the profiles 5 and between the connectors 7, a tension element. This tension element (not shown here) may be a pull rope or a pull rod. As a result, the entire odu! Fefd can be freely set up without attachment in the ground or without weights. The aerodynamic arrangement also prevents wind forces from reaching under surfaces, so that lifting is not possible.

Figures 3 and 4 symbolically show once again a Moduifeld, which can be arbitrarily expanded and enlarged. Figure 3 shows the important for this application sequence of attachment, consisting of anti-slide, connector, profile with solar module, connector, profile with solar module, connector, anti-skid device, etc.

Below the solar elements there are no connecting or supporting components. Drainage is easily possible, as well as access to the modules.

Figure 5 shows in a sectional enlarged view of the profile 5, the surfaces 9, on which the solar modules 1 (not shown here) can rest and possibly can be glued.

The profile 5 also has an open hollow chamber 10 in which the connector or other mounting elements can be arranged.

This pro! 5 is a particularly advantageous option as a holding element for the solar modules. Alternatively, it is conceivable to fix the connectors directly to a module frame - if present - or to another part of the module or to couple with it, so on special mounting holes or the like.

FIG. 6 shows, in section, a connector 6 which connects the two solar modules of a double module arrangement in the region of the mutually facing upper edges 2 with one another. The connector 6 has at least the two legs 1 1 and 12, which are aligned at an angle to each other. Preferably, the angle α enclosed by legs 11, 2 lies between 00 ° and 175 °, preferably at 160 °.

In addition, the connector 6 on the legs 1 1, 12 preferably has through holes, e.g. Tapped holes, which are provided for easy clamping of the connector 6 by means of screws in the profile 5.

Figure 7 shows a double-curved connector 7, which is designed to define the lower edges 3 of the Soiareiemente 1. The connector 7 has a support leg 7a, a vertical leg 7b oriented vertically here, and a further oblique leg 7c, which is aligned here at an angle β of 90 ° + (180 ° -a) / 2 = 180 ° -a / 2, for attachment to the Soiarmodulen. The connector 7 also preferably also has bores which are designed for connection to the profile 5 or to the anti-slide device 4.

FIGS. 8A and 8B show an anti-slip device 4, which essentially serves as a connecting element between the lower edges 3 of the mutually facing edges 3 of adjacent double-module arrangements.

The distance of the connection is selected to be relatively large at 300 mm, and thus provides the advantage that a revision passage is formed between the double module arrangements. This revision gear is not absolutely necessary, but also serves advantageously for laying the power cable.

Figure 8 A shows a first anti-slip device in a side view, wherein the anti-skid device consists of a lower plate 15, on which at least one push rod 16 is arranged. On the push rod 16, which could also be referred to as a spacer bar, are pins 17, preferably threaded pins, for connecting the anti-slip device with the connector 7 for the lower edges 3 of the solar elements. 1

FIG. 9 likewise shows an anti-slip device 4 ', which is designed for cost reasons without pressure rods. To give the sheet 15 'additional stability, in particular To give this pressure stability, the plate 15 'is folded on the sides. Additional beads or sheet metal stiffeners are a further advantageous addition, in addition to the pins 17, the Gieitsicherungseinrichtung 4 'in the lateral edgings slots 18, which serve for the attachment of cable clamps and the like.

Basically, the non-locking device 4 on its underside 19, ie on its side facing the roof, have a special configuration, preferably a roughening or a friction-increasing coating.

This may be formed as an adhesive surface or a rubberized surface or with stripes such as e.g. Be provided EPD strip or be designed in any other way so that slipping of the elements is prevented on the ground.

The background to this is the fact that wind forces acting on the module field, have only a relatively small lifting effect but a relatively large sliding effect, ie lower forces in the vertical direction and greater forces in the horizontal direction. The anti-skid devices are therefore also suitable without additional weighting and without attachment to the roof or subsoil surface to absorb corresponding wind loads. The footprint is also so large (preferably more than 200 mm ^* 200 mm, in particular more than 400 mm ^* 300 mm, so that the weight forces are well distributed.) The castor securing devices 4 are then preferably only on a substrate and are This type of module arrangement is particularly cost-effective, easy to assemble and yet very safe.

This can also be understood particularly well from FIG. 10, which shows a front view in FIG. 10a and a side view of a double-row solar module arrangement in FIG. 10b. The arrangement is such that wind lift-off is prevented easily and securely.

1a, b show a side view of another embodiment of a connector 6 and a plan view of this connector 6 with the two legs 1 1, 12 and the angle a, which here at 160 ° Wins. The legs 11, 12 serve in turn for insertion into the respective chambers of the profiles 5. In order to limit the insertion path of the connector 6 in these chambers 10, at least one projection 20 is formed on the connector 6. It when the projection 20 is centrally between the two opposite ends of the tavern is particularly advantageous! 11, 12 is formed. Thus, a precise distance between the solar modules is ensured in a simple manner, which corresponds to the width of the at least one projection 20 or the distance between, for example, two projections. Fig. 11 also shows the already mentioned threaded holes (reference numeral 21) for additionally tightening the connector 6 in the profile 5 by screws.

Fig. 2a, b shows a side view of another connector 7 and a plan view of this connector 7. Also, this connector is provided with a projection (reference numeral 22), which limits the insertion path of the corresponding leg 7c in the chamber 10 of the profile 5, so that a defined seat of the solar module or a defined seat of the connector 7 on the solar module is ensured in a simple manner in this lower part of the solar module in the assembled state. Also Fig. 1 1 shows threaded holes (reference numeral 23) and a slot 24, once for additional fixing of the connector 7 in the profile by screws and once for attachment to pins on the anti-slip devices. 4

Finally, FIG. 13 shows a view of the already mentioned tension element here in the form of a tension cable 25 with fastening elements at the ends facing away from one another for receiving the tensile forces between the profiles 5 or between the connectors 7.

Bezuqsziffern:

1 soi element

2 upper edge

3 lower edge

against slippage

5 profile

Interconnects

Connector with legs 7a, b, c

pen

area

10 groove

1 1 thigh

12 thighs

13 angles

14 hole

15 sheet metal

16 push rod

17 pen

18 slot

19 bottom

0 lead

1 threaded holes

2 lead

3 threaded hole

4 long hole

5 pull ropes

6 fasteners

Claims

claims

A module assembly comprising:

a. at least one or more double module arrangements each consisting of two angularly aligned solar modules; characterized in that b, the mutually remote edges (3) of each Doppelmoduianord- tion are not connected to each other via a support strut.

2. odulanordnung according to claim 1 or according to the preamble, characterized in that

adjacent double module arrangements are connected to one another via at least one or more coupling devices which have anti-gliding devices (4) which rest on a substrate and are not fastened there by fastening means beyond an optionally existing adhesive layer,

at least two edges (3) of two adjacent double-module arrangements are arranged or fixed on each anti-slip device (4), preferably four of the edges (3), so that mutually adjacent, adjacent double-module arrangements in the region of the adjacent lower edges (3) over the Coupling devices or elements formed as anti-skid devices are interconnected.

3. Module arrangement according to claim 1 or 2, characterized in that two modules Soiarmodule (1) of the at least one double module arrangement are coupled together only in the region of their mutually facing upper edges (2).

4. Module arrangement according to claim 1, 2 or 3, characterized in that the two modules Soiarmodule (1) of each double module arrangement via one or more connectors (6) are coupled together.

5. Module arrangement according to one of the preceding claims, characterized in that the safety device (4) is roughened on one side and / or provided with a friction-increasing coating.

6. Module arrangement according to one of the preceding claims, characterized in that the anti-slip means (4) via at least one further connector (7) are coupled to one or more further double module arrangements.

7. Module arrangement according to one of the preceding claims, characterized in that the anti-sliding means (4) are designed such that the distance between the lower edges of adjacent Doppeimodul- arrangements 50 to 500 mm, preferably 300 mm, so that the gap between adjacent to each other Doppeimodulanordnungen is accessible.

8. Moduianordnung according to any one of the preceding claims, characterized in that the anti-skid devices (4) take over the function of a load transfer of Doppeimodulanordnungen in the underground.

9. Module arrangement according to one of the preceding claims, characterized in that the anti-sliding means (4) have a footprint on a substrate, which is more than 200 mm ^* 200 mm, in particular more than 400 mm ^* 300 mm.

10. Moduianordnung according to any one of the preceding claims, characterized in that below the solar modules, in particular under glass-glass thin-film laminate modules, one or more profiles (5) is arranged, which has one or more chambers, which for receiving the connector ( 6, 7) is designed / are.

1 1. Module assembly according to one of the preceding claims, characterized in that the connector (6) for connecting the two modules of a double module arrangement is formed at an angle and two legs (11, 12) which enclose an angle α, which is between 95 ° and 175 °.

12. Module arrangement according to one of the preceding claims, characterized in that the Gleitstcherungseinrichtungen (4) with projecting pins (8, 17) are provided on soft legs of the connector (7) are placed with corresponding holes.

13. Module arrangement according to one of the preceding claims, characterized in that the profile (5) surfaces (9), on which rest the solar modules (1).

14. Module arrangement according to one of the preceding claims, characterized in that the profile (5) has at least one open Hohikammer (10) into which the one or more connectors (6, 7) can be inserted / are.

15. Module arrangement according to one of the preceding claims, characterized in that the connector (7) for fixing the lower edges (3) of the solar elements (1) has a support leg (7a) for resting on the slip-locking device (4) and at least one For this purpose angled leg (7c) for fixing to the solar modules.

16. Module arrangement according to one of the preceding claims, characterized in that the Gieitsicherungseinrichtung preferably on a substrate in the mounted position preferably lower plate (15), which preferably has one or more reinforcing beads and / or - edges.

17. Module arrangement according to one of the preceding claims, characterized in that the bend (15) is designed such that on it at least one pressure rod (16) is arranged and that on the push rod (16) the pins (17) for connecting the Gieitsicherungseinrichtung with the connector (7) for the lower edges (3) of the solar elements (1) are arranged.