DE29809280U1 - Holder of solar modules - Google Patents

Description

Description

The invention relates to a mounting of solar modules on underground scaffolding or facades.

Solar modules are usually attached to free-standing substructures or to house facades or roofs. They are generally difficult to integrate into the existing architecture and usually significantly disrupt the overall appearance of a building. In addition, frames and fastening devices are required to hold them, which must be manufactured individually according to the existing structural conditions and are therefore labor-intensive and costly.

On the other hand, facade claddings are known that consist of facade panels applied to a substructure. The substructure can, for example, consist of a lath frame on which holding elements for the facade panels are attached. DE-PS 36 41 747 shows such a solution.

DE-OS 32 39 161 discloses a facade cladding in which horizontal profile bars are attached to vertical profile bars using clamps that are screwed to these profile bars, into which the facade panels are then hung.

It has also already been suggested to use only vertical profile bars, to which appropriate brackets for the facade panels are already molded. It has also already been suggested to use a grid mat as the substructure, which consists of vertical support profiles and horizontal profile bars. The facade panels can be hung directly into the horizontal profile bars in the front level of the grid mat.

The invention is based on the object of specifying a holder for solar modules which, compared to previously known holders, allows simple and inexpensive installation on site and which, in particular when attached to facade cladding with facade panels, offers an architecturally pleasing solution.

According to the invention, the object is achieved in that the solar modules are provided with a frame on their upper and lower sides, which are connected to one another on the back of the solar modules and in plate holders of a free-standing or wall-mounted

• *

«I

attached substructure suitable for supporting facade panels or can be hooked directly into such a substructure.

The brackets can be designed in such a way that the lower frame has a groove on its underside running in the longitudinal direction of the frame and the upper frame has a web running in the longitudinal direction of the frame and projecting upwards beyond the front part of the upper frame.

They can also be designed in such a way that the lower border has an upward-facing web on its rear side and the upper border has an undercut web on its rear side that points downwards and runs in the longitudinal direction of the borders.

Another variant is a design of the surrounds in which they have webs on their back that can be snapped into panel holders in the longitudinal direction of the surrounds.

In a particularly advantageous manner, the plate holder can be designed in such a way that it has a holding arm that holds the lower side of a solar module and that is at a greater distance from the substructure than the holding arm for the upper side of a solar module in an underlying row of solar modules. The solar modules then have an angle that is inclined towards the sun, which allows a more favorable angle of incidence for the sun's rays to be achieved.

The frames can be made of a plastic or aluminum extruded profile or of bent sheet metal. They can also be made of glass, e.g. recycled glass. The connection between the two frames on the back of the solar module can be designed as a continuous flat connection or can be made using one or more spring clips.

In particular, if there is a continuous, flat connection between the frames, an intermediate layer, for example made of foamed plastic, can be arranged between this and the back of the solar module to provide support against it.

The solar modules can have the dimensions of standard facade panels. They can be attached to house walls using this bracket as before, for example, by

First, a substructure of the type described above, which is otherwise used to hold facade panels, is installed, into which the solar modules are then simply hung. The electrical connections can be made, for example, in the vertical bars _of the substructure. Such a substructure requires only a few fastening points and is usually less costly and labor-intensive than individually manufactured fastening devices.

In any case, the solar modules are easy to install without the need for additional fastening devices.

The solution also has the advantage that it can be integrated into facade cladding with facade panels. The solar modules form a level with the facade panels and thus fit into the overall appearance of a facade, creating architecturally pleasing solutions. For existing brick facades, this creates the possibility of renovating or modernizing the facade with solar modules and facade panels, or simply adding solar modules. In existing facade cladding with facade panels, these can simply be replaced with solar modules without the need for any tools or additional fastening devices.

With special brackets that extend through the horizontal joints between the facade panels, the solar modules can also be arranged in front of a facade made of facade panels.

The invention will be explained in more detail below using exemplary embodiments. In the accompanying drawings,

Fig. 1 shows a solar module provided with a holder according to the invention in a

perspective representation,

Fig. 2 a solar module according to Fig. 1, on a facade panel clad

House facade, in a side sectional view,

Fig. 3 a variant of the solar module holder shown in Fig. 1,

a a

Fig. 4 a variant of a solar module holder made of sheet metal in a perspective

Depiction,

Fig. 5 a solar module according to Fig. 4, on a facade panel clad

House facade, in a side sectional view,

Fig. 6 a variant of a solar module holder according to Fig. 4, directly in a

Substructure used,

Fig. 7 is a rear view of the arrangement according to Fig. 6,

Fig. 8 a variant of a solar module holder according to Fig. 1, directly in a

Substructure used,

Fig. 9 is a rear view of the arrangement according to Fig. 8,

Fig. 10 another variant of a solar module holder in perspective view,

Fig. 11 the bracket according to Fig. 10, on a house facade clad with facade panels

applied, in lateral sectional view,

Fig. 12 a second variant of the arrangement according to Fig. 11,

Fig. 13 the plate holder for the solar module used in the variant according to Fig. 11,

Fig. 14 the front and rear view of an enclosed solar module according to Fig. 10,

Fig. 15 another variant of a solar module mount, on a facade panel

clad house façade, in lateral section, 30

Fig. 16 a second variant of the arrangement according to Fig. 15,

Fig. 17 the plate holder used in the variants according to Fig. 15 and Fig. 16 for the

Solar module and

Fig. 18 a view of a part of a facade covered with both facade panels and

covered with solar modules.

Fig. 1 shows a solar module 1, which is held on its lower side in a frame 2 and on its upper side in a frame 3. The frames have webs 4, 5 at the front that extend over the solar module 1. Both frames 2, 3 are braced against each other with two spring clips 6 on the back of the solar module 1. In this case, the spring clips 6 engage in small clamping bodies 7 that are inserted into rails 8 of the frames 2, 3. 10

The surrounds 2, 3 are designed in such a way that a groove 9 is formed on the underside of the module/surround unit and a fastening web 10 is formed on its upper side.

The frames 2, 3 can be manufactured as plastic or aluminum extruded profiles.

Fig. 2 shows the attachment of a module/frame unit to a facade. Vertical support rails 12 are attached to a house wall 11, onto which horizontal profile rails 13 are screwed. Plate holders 14 are hung in the profile rails 13, which hold ceramic facade panels 15.

The facade panels 15 are held on their underside by engaging in a groove 16 and on their upper side by enclosing a longitudinal web 17.

In the same way, framed solar modules 1 can now be hung in the panel holders 14. The solar modules 1 thus form a front facade level with the facade panels 15. Facade panels 15 and solar modules 1 can be replaced at any time. Special facade designs can be realized by arranging the solar modules in rows or columns or other geometric formations.

The electrical connections 18 of the solar modules are connected behind the facade with corresponding connection elements.

Fig. 3 shows the profile of a variant of the frames 2, 3 for solar modules 1, which are dovetail-shaped so that the frames 2, 3 do not require any front webs.

Fig. 4 shows a variant of the enclosure of a solar module 1, which consists of a single sheet metal enclosure 19. The shape of the sheet metal enclosure 19 is selected so that a groove 9 is created on the underside and a fastening web 10 is created on the top. In order to achieve a firm connection between the sheet metal enclosure 19 and the solar module 1, an intermediate layer 20 made of foamed plastic was inserted between the two. 10

Fig. 5 shows the integration of such a module/frame unit into a facade cladding with facade panels 15, analogous to the facade cladding shown in Fig. 2.

Fig. 6 also shows an arrangement in a facade cladding. The difference from the previously shown examples is that here both the facade panels 15 and the sheet metal edgings 19 are shaped in such a way that they can be placed directly on horizontal profile bars 21 of a substructure not shown in detail here. The specially designed panel holders, which encompass the fastening webs 10 of the sheet metal edgings 19 or the longitudinal webs 17 of the facade panels 15, are also not shown here. 20

In an analogous manner, the frames 2, 3 of a solar module holder corresponding to Fig. 1 can be designed for the fastening variant, as can be seen from Fig. 8.

Fig. 7 and 9 show the backs of the brackets according to Fig. 6 and 8.

Fig. 10 shows a further variant of the surrounds 2, 3, which makes the module/surround unit particularly suitable for placing in front of a facade. The specially designed panel holders 22 can be seen in Figs. 11 to 13. The panel holders 22 cross the horizontal joint between two rows of facade panels 15. The surrounds 2, 3 are snapped onto the panel holders 22 using a snap-in connection.

Fig. 12 shows a possibility of attaching the solar modules 1 to the facade in such a way that their underside is spaced from the facade and thus a more favourable angle to incident

Sun rays are created by making the upper of the two holding arms 23 of the plate holder 22 longer than the lower one.

Fig. 13 shows the plate holder 22 as a part cut from an extruded profile in detail.

Fig. 14 shows the arrangement according to Fig. 10 again as a front and rear view. The views make it clear that the corners of the frames 2, 3 can be cut away at an angle so that the spring clips 6 are located behind the solar module 1 and are therefore not visible from the front.

The variants shown in Fig. 15 to 17 also relate to solar modules 1 that are mounted in front of a facade consisting of facade panels 15. The facade panels 15 are here mounted on a substructure, in which the facade panels 15 in turn rest directly on horizontal profile bars 21.

The plate holders 24 provided for holding the solar modules 1 are made of sheet metal and in turn grip the horizontal joint between two rows of plates and around webs 25 formed on the frames 2, 3.
20

A different type of frame is shown in Fig. 18. The frame 26 consists, similar to the frame 19 according to Fig. 4, which consists of sheet metal, of a single, connected part, but here made of glass, to the front side of which the solar module 1 is glued.

Fig. 19 shows a facade constructed from facade panels 15 and solar modules 1 in a front view, from which it can be seen that the solution shown here offers a wide range of architectural design options.

Claims (12)

Patent Attorney Dipl.-Ing. Werner E. König Habsburgerallee 23-25, 52064 Aachen Jerzy Lech, 52078 Aachen Utility model application Mounting of solar modules Protection claims 1. Mounting of solar modules (1) on substructures or facades, characterized in that the solar modules (1) are each provided with a frame (2, 3, 19, 26) on their upper and lower sides, which are connected to one another on the back of the solar modules (1) and can be suspended in panel holders (14, 22, 24) of a free-standing or wall-mounted substructure (13, 21) suitable for holding facade panels (15) or directly in such a substructure (13, 21). 2. Mounting of solar modules (1) according to claim 1, characterized in that the lower frame (2) has on its underside a groove (9) running in the longitudinal direction of the frame (2) and the upper frame (3) has a web (10) running in the longitudinal direction of the frame (3) and projecting upwards beyond the front part of the upper frame (3). 3. Mounting of solar modules (1) according to claim 1, characterized in that the lower frame (2) has an upwardly pointing web (25) on its rear side and the upper frame (2) has an undercut web (25) on its rear side that points downwards and runs in the longitudinal direction of the frames (2, 3). 4. Holder for solar modules (1) according to claim 1, characterized in that the frames (2, 3) have webs on their rear side in the longitudinal direction of the frames (2, 3) that can be snapped into plate holders (22). M:\HOME\BUERO\GBMANM\G98\G98350EN.DOC 5. Holding device for solar modules (1) according to one of the preceding claims, characterized in that the plate holder (14, 22, 24) has a holding arm (23) holding the lower side of a solar module (1), which is at a greater distance from the substructure (13, 21) than the holding arm (23) for the upper side of a solar module (1) of an underlying row of solar modules (1). 6. Mounting of solar modules (1) according to one of the preceding claims, characterized in that the frames (2, 3) on the rear side of the solar module (1) are connected to at least one spring clip (6). 7. Mounting of solar modules (1) according to one of claims 1 to 5, characterized in that the frames (2, 3, 19, 26) are connected to the rear of the solar module (1) with a flat, continuous connection. 8. Mounting of solar modules (1) according to one of the preceding claims, characterized in that an intermediate layer (20) is inserted between the rear side of the solar module (1) and the connection between the frames (2, 3, 19, 26). 9. Mounting of solar modules (1) according to one of the preceding claims, characterized in that the frames (2, 3) consist of an extruded aluminum profile. 10. Mounting of solar modules (1) according to one of claims 1 to 8, characterized in that the frames (2, 3) consist of an extruded plastic profile. 11. Mounting of solar modules (1) according to one of claims 1 to 8, characterized in that the frames (19) consist of bent sheet metal. 12. Mounting of solar modules (1) according to one of claims 1 to 8, characterized in that the frames (26) consist of glass.