DE102011057028A1 - Support for mounting solar module on roof of building, has mounting block with opening opened downward to base plate and closed upward for receiving screw guided from below, where seal is arranged between mounting block and base plate - Google Patents

Abstract

The support (1) has a base plate (10) and a mounting block (30) connected with the base plate, on which a solar module (2) is fixed. The base plate is a profile metal sheet, and the mounting block has an opening opened downward to the base plate and closed upward for receiving a screw guided from below through the base plate. The base plate is a corrugated metal sheet or a trapezoidal sheet. The opening of the mounting block, which is closed upward is a threaded hole. A seal is arranged over the entire surface between the mounting block and the base plate. An independent claim is included for a method for mounting a solar module on a roof.

Description

The invention relates to an elevation for a solar module having a base plate and at least one associated mounting block to which the solar module can be mounted. The invention further relates to a method for mounting a solar module on a roof with an existing in particular profiled sheets roof skin.

Elevations are used to install solar modules on a roof or other surface. The elevation of the above type can be used flexibly on different surfaces or roof types due to their base plate. In particular, when installed on a flat roof surface or a roof surface with unfavorable orientation of the slope or on a flat surface can be provided that the solar module is mounted obliquely to the plane of the base plate.

For covering halls and similar buildings often profiled sheets, such as corrugated or trapezoidal sheets are used, which have parallel to each other in cross-section wavy or trapezoidal embossed webs. The sheets are usually in the range of lying between the webs recesses on a roof substructure and are bolted to this substructure.

From the document 20 2010 005 531 U1 is known for fixing solar modules on a roof, which is formed from trapezoidal sheets, spaced horizontally extending profiles transverse to the webs of the trapezoidal sheet on this and set with the help of retaining clips. The retaining clips are screwed from the outside of the roof by screws which penetrate at least in the trapezoidal sheets, possibly in a roof substructure. On the horizontal profiles carrier profiles or other fastening devices for the solar modules are set. At the screw holes of the retaining clips for the horizontal profiles, however, leaks in the roof skin may result. In addition, complicated installation steps on the roof are required.

Furthermore, from the document FR 2 935 410 known profiles that mimic to the roof the cross section of a web of a trapezoidal sheet to screw from the outside to the roof. On these profiles, a (framed) solar module can be attached directly with retaining clips. For this purpose, the profiles have a mounting groove on their side facing away from the roof skin. Also in this case it can come in the area of the screw to leaks in the roof. The screwing is done either by self-tapping screws with the roof or by the roof with slats of the substructure of the roof. In the former case, the screw is not necessarily sufficient tensile strength. A screwing with the substructure, however, can only be done at selected positions on the roof, since slats are provided in the substructure only about every 60 cm. In order to achieve a secure attachment of the mounting profile on the trapezoidal sheet, the mounting profile is therefore usually carried out consistently under the applied solar modules. Only then it is possible to use the slats of the substructure for a screw regardless of the position of the solar modules relative to the position of the slats. Due to this continuous design of the profile, this results in comparatively high costs. This applies in particular when thin-film solar modules are used which, compared to crystalline or polycrystalline solar modules, have a greater power requirement in relation to performance.

It is therefore an object of the present invention to provide a Aufständerung of the type described above, which allows for low installation costs secure installation of solar modules. It is a further object to provide an inexpensive process for mounting solar modules solar module on a roof, especially in a roof skin of profiled sheets.

This object is achieved by an elevation and a method having the respective features of the independent claims.

An elevation according to the invention of the type mentioned above is characterized in that the base plate is a profiled sheet and the at least one mounting block has a downwardly open to the base plate and closed at the top opening for receiving a bottom guided by the base screw through which Mounting block is connected to the base plate. The threaded connection thus executed provides a resilient attachment of the mounting block to the base plate. The arrangement of the screw protects these and underlying the elevation elements from penetrating moisture and thus from corrosion.

In an advantageous embodiment of the elevation, the base plate is a corrugated metal sheet or a trapezoidal sheet. In this way, a secure determination of the elevation is achieved on a roof, the roof of which also consists of profiled material.

A method according to the invention for mounting a solar module on a roof with a roof skin consisting in particular of trapezoidal sheets is characterized in that an elevation is glued to the roof skin and the solar module is mounted on the elevation. In this way, a simple, fast and inexpensive installation of solar modules on site is possible. The elevation is particularly suitable for retrofitting of solar modules, since no screwing must be done with the roof skin. Fittings can be mounted on already mounted roofs, for example, due to a heat applied from the inside only with great effort.

In an advantageous embodiment of the method, the base plate and the roof skin are profiled with the same cross-section. The resulting in at least one direction positive connection between elevation and roof skin leads to a particularly resilient attachment of the elevation to the roof skin.

Further advantageous embodiments and further developments of the elevation and the method are the subject of the respective dependent claims.

The invention will be explained in more detail by means of exemplary embodiments with the aid of five figures. Show it:

1 a perspective schematic representation of a Aufständerung for mounting a solar module on a roof,

2 an exploded perspective view of a portion of the elevation of 1 .

3 a sectional view of a portion of the elevation of 1 .

4 a perspective schematic representation of a Aufständerung in another embodiment and

5 a sectional view of a portion of the elevation of 4 ,

1 shows an elevation in the middle area 1 with a base plate 10 and four mounting blocks attached to it 30 , The base plate 10 consists of a section of a trapezoidal sheet. Like in the 1 is illustrated, the elevation becomes 1 in the example shown for mounting a solar module 2 on a roof skin 3 used, of which a section is reproduced in the figure. Indicated by the arrow I in a first assembly step on site, the manufacturer completely preassembled elevation 1 first with its base plate 10 on the roof skin 3 set and, if necessary, fixed on this. Details will be related to 3 described. In a second assembly step, as indicated by the arrow II, the solar module 2 at the assembly blocks 30 fastened, for example by means not shown here retaining clips.

2 shows part of the elevation of the 1 in a perspective exploded view.

The base plate formed by a trapezoidal sheet 10 has a plurality of parallel spaced trapezoidal webs 11 on, in the figure only a single is reproduced. In the upper flat surface of the trapezoidal web 11 are spaced from each other two holes 12 for screws 13 brought in.

The assembly block 30 will be in the field of drilling 12 on the trapezoidal bridge 11 the trapezoidal sheet set. For this purpose, the mounting block 30 on its base plate side facing in its shape complementary to the cross section of the trapezoidal web 11 executed. He has a crossbar 31 on, in its width to the width of the trapezoidal web 11 is adjusted. From each side of the crossbar 31 runs one cheek each 34 obliquely downwards, whereby a trapezoid is formed whose shape is that of the trapezoidal web 11 equivalent. At the lower end are the cheeks 34 to a foot 35 bent. On the outer side of the cheeks 34 of the mounting block 30 are ribs 36 arranged on which a cable clip 40 can be clipped to connecting cable mounted solar modules or sensor cable to the mounting block 30 to be able to determine.

In the middle area is the crossbar 31 as a solid profile 32 executed, in which from below, that of the base plate 10 facing side, tapped holes 33 are introduced. The threaded holes 33 are designed as blind holes. The distance between the threaded holes 33 corresponds to that of the holes 12 in the base plate 10 ,

For fastening the mounting block 30 on the base plate 10 becomes the mounting block 30 together with an intermediate seal 20 on the trapezoidal bridge 11 placed. The seal 20 is in its shape also the profile of the trapezoidal web 2 customized. It has a footbridge 21 on, in the openings 23 congruent to the holes 12 are arranged, wherein the openings 23 optional of annular thickenings (beads) 22 can be surrounded. At the footbridge 21 are formed cheeks, like the mounting block 30 go into foot-shaped sections. The seal is preferably made in one piece from a flexible material, for example a rubber, in particular an EPDM rubber (ethylene-propylene-diene rubber). The seal 20 is in its dimensions to the mounting block 30 adjusted so that it covers the entire surface of the seal 20 rests. From the bottom of the trapezoidal bridge 11 be through the holes 12 the base plate 1 and the openings 23 the seal 20 the screws 13 into the threaded holes 33 of the mounting block 30 screwed to this at the base plate 1 set. The heads of the screws 13 lie large area around the edge of the hole 12 on and make a strong connection between the base plate 10 and the mounting block 30 ago. In particular, a tearing of the attachment to the base plate 10 effectively prevented.

Because of the threaded holes 33 in full profile 32 are executed, is an ingress of water from above into the holes 12 or excluded in the threads of the screw. A lateral penetration of moisture into the holes 12 gets through the seal 20 prevents, especially if these are the bead-shaped thickening 22 having. These are compressed by the screw connection and thus seal in the area around the hole 12 good around. The seal 20 Prevents moisture from entering the area under the base plate 10 which protects the underlying material from corrosion. If this is not required, may include the use of the seal 20 be waived.

On the from the base plate 1 groundbreaking, upper side of the mounting block 30 has this two vertical webs 37 on, at its upper end in two beam sections 38 lead. As related to 3 will be explained in more detail form the carrier sections 38 a flat surface for supporting a solar module to be mounted. The between the support sections 38 formed undercut groove can be used to hold a sliding block for mounting purposes.

3 shows a section of the elevation 1 according to the 1 and 2 with mounted solar module 3 and put on a roof skin 2 in cross section.

The solar module 3 lies with an edge on the support sections 38 on and is using a retaining clip 50 that the edge of the solar module 3 overlaps, on the assembly block 30 established. To connect the retaining clip 50 with the mounting block 30 is a sliding block in the between the support sections 38 formed undercut groove, in which a not visible in the figure screw is screwed.

Because of the mounting block 30 due to the screw connection with the base plate 10 is securely connected to this, is a stable attachment of a large solar module with a small number of mounting blocks 30 possible. The length of a mounting block 30 may be in the range of 80 to 300 millimeters (mm), for example, preferably in the range of 100 to 155 mm. Compared to mounting systems, in which a running over the entire length of the module profile is used, there is a significant material savings.

The assembly block 30 is preferably made of a strand profile material, which is cut into correspondingly long sections. Only the holes 33 are then to be introduced in a further processing step. As material for the assembly block 30 Aluminum, plastic or a steel alloy can be used. In an alternative embodiment is conceivable, instead of the full profile 32 with the introduced threaded holes 33 at this point a continuous profile with a down to the base plate 10 to provide an open groove. The width of the groove is chosen so that the bottom through the base plate 10 guided screws 13 self-tapping a thread in this groove. In such a case, a closing of the laterally open groove is optionally attached for reasons of tightness. This can be done by an inserted Kunststoffpfropfen and / or by the introduction of a sealant, such as a silicone. An advantage over the previously described embodiment is that the separate manufacturing step for inserting the threaded hole 13 eliminated. In addition, there is a certain tolerance in the positioning of the holes 3 in the trapezoidal sheet 1 given through the groove. Optionally, the inner side surface of the groove may be grooved to facilitate the engagement of the self-tapping screws.

The roof skin shown in the example 3 is lying on slats 4 a roof substructure and is with these by screws 5 connected. The elevation 1 is now according to the application with the roof skin 3 bonded. This will be suitable filling adhesive 6 , eg mounting foam, on the roof skin and / or the underside of the base plate 10 applied and the elevation 1 on the roof skin 3 placed. As in the embodiment, the base plate 10 prefers the same cross section as the roof skin 2 , This results in a direction transverse to the webs 11 the base plate 10 Form fit between the elevation 1 and the roof skin 3 , In addition, by the profiling of base plate 10 and roofing 3 a large-scale adhesive connection possible. Both lead to a safe and resilient mounting of the elevation 1 on the roof skin 3 without piercing them would have to, which could result in leakage problems. The elevation 1 is for these reasons, among other things well suited for retrofitting solar modules.

4 shows the use of two elevations 1 each with a mounted solar module 2 in a further embodiment. The elevations 1 are here designed so that the solar modules 3 are aligned obliquely against the ground. For example, a pairwise east-west orientation of solar modules can be achieved. The base plates 10 are in turn made of profiled sheet metal, here as in the previous embodiment, a trapezoidal sheet metal. The elevations can be used on any surface, for example on a (flat) roof with a roof skin made of corrugated or trapezoidal sheet or tar paper or plastic film. Similarly, a use in a gravel bed or similar. possible.

For tilting the solar modules 2 show the elevations 1 on a base plate 10 fixed mounting blocks 30 on, which are in pairs differently high. In 5 is a suitable assembly block 30 shown in a sectional drawing. In the bottom, the base plate 10 Assigned area are the mounting blocks 30 configured in this embodiment as well as in the embodiment of 2 , Unlike the example of 2 are in this case the vertical webs 37 however, different high and the vehicle sections 38 are slanted on the vertical bars 37 arranged. For stiffening runs transversely between the two vertical webs 37 a reinforcing rib 39 , Depending on the height of the vertical webs 37 can have several such reinforcing ribs 39 be provided. On the opposite side of the elevation 1 also become such mounting blocks 30 used, but at the same angle between vertical webs 37 and beam sections 38 vertical webs 37 having a greater height.

LIST OF REFERENCE NUMBERS

1

elevation

2

solar module

3

roof

4

Lath of the roof substructure

5

screw

6

Glue

10

profiled base plate (trapezoidal sheet metal)

11

web

12

drilling

13

screw

20

poetry

21

web

22

bead

23

opening

30

mounting block

31

crosspiece

32

full profile

33

threaded hole

34

cheek

35

foot

36

rib

37

vertical web

38

support sections

39

reinforcing web

40

cable clip

50

bracket

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• FR 2935410 [0005]

Claims (17)

Elevation ( 1 ) for a solar module ( 2 ), comprising a base plate ( 10 ) and at least one associated mounting block ( 30 ) on which the solar module ( 2 ), characterized in that the base plate ( 1 ) is a profiled sheet and the at least one mounting block ( 30 ) one down to the base plate ( 10 ) open and closed at the top opening for receiving from below through the base plate ( 10 ) guided screw ( 13 ) through which the mounting block ( 30 ) with the base plate ( 10 ) connected is. Elevation ( 1 ) according to claim 1, wherein the base plate ( 10 ) is a corrugated metal or a trapezoidal sheet. Elevation ( 1 ) according to claim 1 or 2, wherein the at least one upwardly closed opening of the mounting block ( 30 ) a threaded hole ( 33 ). Elevation ( 1 ) according to claim 1 or 2, wherein the at least one upwardly closed opening of the mounting block ( 30 ) is a groove. Elevation ( 1 ) according to one of claims 1 to 4, wherein at least one mounting block ( 30 ) has in a lower portion a shape which is complementary to a cross-section of webs ( 2 ) of the base plate ( 1 ). Elevation ( 1 ) according to one of claims 1 to 5, wherein the mounting block ( 30 ) laterally projecting ribs ( 36 ), to which a cable clip ( 40 ) can be clipped to hold cables. Elevation ( 1 ) according to one of claims 1 to 6, wherein the mounting block ( 30 ) for fixing the solar module ( 2 ) in an upper portion two parallel and spaced support sections ( 38 ), between which an undercut groove is formed. Elevation ( 1 ) according to one of claims 1 to 7, comprising at least one on the mounting block ( 30 ), a mounted solar module ( 2 ) on an edge cross-retaining clip ( 50 ). Elevation ( 1 ) according to one of claims 1 to 8, wherein a seal ( 20 ) over the entire surface between the at least one mounting block ( 30 ) and the base plate ( 10 ) is arranged. Elevation ( 1 ) according to one of claims 1 to 9, wherein the at least one mounting block ( 30 ) is made of an extruded profile. Elevation ( 1 ) according to one of claims 1 to 10, wherein the at least one mounting block ( 30 ) is designed so that a mounted solar module ( 2 ) is aligned in a plane which is oblique to the base plate ( 10 ) runs. Elevation ( 1 ) according to claim 11, wherein a plurality of mounting blocks ( 30 ) of different height are provided to the orientation of the mounted solar module ( 2 ). Elevation ( 1 ) according to one of claims 1 to 10, in which the base plate ( 10 ) is profiled as a roof skin ( 3 ) on which use of the elevation ( 1 ) is provided. Method for assembling a solar module ( 2 ) on a roof with a roof skin consisting in particular of trapezoidal sheets ( 3 ), characterized in that an elevation ( 1 ) with the roof skin ( 3 ) is glued and the solar module ( 2 ) at the elevation ( 1 ) is mounted. Method according to Claim 14, in which the elevation ( 1 ) a base plate ( 10 ) has a profiled sheet. Method according to Claim 15, in which the base plate ( 10 ) and the roof skin ( 3 ) are profiled with the same cross-section. Method according to one of Claims 14 to 16, in which the elevation ( 1 ) is formed according to one of claims 1 to 13.

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