DE102013011260A1 - Spacer for solar module carrier - Google Patents

Abstract

Disclosed is a spacer (1) for solar module carrier (2), which is characterized by a connecting piece (3) and a spacer profile (4), wherein the connecting piece (3) with the spacer profile (4) about a transversely to the longitudinal direction of the spacer profile (4 ) arranged pivot axis (5) is rotatably connected and for the solar module carrier (2) has a parallel to the pivot axis (5) arranged abutment surface (7) with at least one passage opening (8) for a fastening means. In addition, an arrangement (14) of the spacer (1) and a solar module carrier (2) is presented, which is characterized in that the solar module carrier (2) has a base (15) with a base (16), a receptacle (17) for the fold (10) and / or an edge of the abutment surface (7), a counter surface (18) for the abutment surface (7) and a fixing recess (19).

Description

Solar module carriers are already described many times such as in WO 002 002 073 703 A1 , in DE 20 2010 015 848 U1 , in DE 10 2010 024 514 A1 . DE 20 2006 019 837 U1 or DE 10 2009 022 746 A1 , In this case, a triangle forming supporting structures for receiving a solar module are described in cross-section substantially, wherein the angle of the solar modules can be varied by adjustment of the carrier. This is not surprising since an optimized angle of attack has an influence on the energy yield. However, it should also be taken into consideration that, when erecting solar modules on flat roofs, the supports and solar modules are arranged next to one another in rows. The spacing of these rows determines, together with the selected angle of attack, the degree of shading of the series of succession arranged behind the first, sun-facing row and also influences the energy yield. This aspect is already in DE 20 2012 001 526 U1 taken up by supernatants of the flat roof resting carrier profile are described there, which define a distance of the following series, but not further disclosed how the spaced rows are connected together. The drawings are only laterally in the profiles arranged to remove holes that suggest that the U-shaped profiles are placed inside each other and screwed together using the holes.

Solar systems arranged on flat roofs are particularly exposed to wind loads since the solar modules, which are inclined to the roof surface, offer large areas of attack. In order to make the connections between the individual rows of the solar module carrier stable, many systems provide for rectangular through rails at right angles to the rows, which are arranged both between and under the solar modules. The disadvantage here is that the rails are very long and correspondingly poorly transportable and unwieldy. In addition, they distribute their weight evenly on the support surface instead of concentrating it below the solar modules, where it can best counteract the attacking wind forces. The DE 20 2010 006 377 U1 shows below the solar modules U-profiles with undercut grooves into which can be inserted to bridge the distance between the rows matching strips. A disadvantage is that bumps, as well as continuous profiles, can not be compensated. Roof bumps often occur in practice, be it by opposite slopes for the drainage of rainwater or supply lines of all kinds.

Against the background of the state of the art, it is the object of the present invention to provide a possibility of connecting rows of solar module carriers in such a way that roof unevenness can be easily compensated for by means of the connection and weight-saving components can be used on the other hand. which are easy to transport and easy and safe to assemble, while at the same time enabling the stiffening of a multi-row arrangement which increases the overall stability of the arrangement and thus the resistance to wind loads.

The object is achieved by a spacer according to claim 1 and by an arrangement according to claim 14, wherein advantageous embodiments result from the dependent claims.

The spacer according to the invention has a connection piece and a spacing profile, wherein the connection piece is rotatably connected to the spacing profile about a pivot axis arranged transversely to the longitudinal orientation of the spacing profile and has a stop surface arranged parallel to the pivot axis with at least one passage opening for a fastening means, preferably a screw , which is intended to be attached to one of the solar module carrier to be connected. It is advantageous that the connection piece can assume different positions due to the pivotal connection with the spacer profile before it is fixed to the solar module carrier. Thus, it is possible to compensate for differences in the inclination between the rows to be joined, which may result from slightly rising or falling roof surfaces.

Advantageously, the connecting piece is arranged at the end of the spacer profile, so that the stop surface protrudes beyond the end of the spacer profile in at least one pivoting position, thus avoiding that the end of the spacer profile protrudes beyond the connection between stop surface and solar module carrier, which is a receptacle for the projecting Would require part similar to those in DE 20 2010 006 377 U1 disclosed retractable strips. In contrast, the design effort and material consumption is lowered by the preferred solution. In addition, no practice-relevant restrictions of the pivoting range must be accepted.

The spacing profile is preferably designed as a hollow box profile, in order to achieve increased stability with justifiable use of materials. However, this is not mandatory. Of course Other suitable profile cross-sections can be used, such as U-profiles.

In a preferred embodiment, the passage opening in the abutment surface is designed as a slot aligned parallel to the pivot axis. Thus, smaller lateral displacements of rows arranged one behind the other can be compensated for, without a complete row having to be carefully aligned with the adjacent row.

It has proven to be advantageous for the stability of the connection between spacer and solar module carrier if the end of the spacer profile has a fold which can engage in a receptacle of the solar module carrier, which is preferably arranged on a base of the solar module. Preferably, the fold can engage behind the receptacle, without the spacing profile being completely fixed with respect to its angular position relative to the solar module carrier. The abutment surface is preferably arranged on the distance profile such that a pivoting position is possible in which the fold and an edge of the abutment surface touch each other. The angular position of the spacer profile relative to the solar module carrier is then fixed by means of a fastening means which penetrates the passage opening of the stop surface. The fold does not have to come from the distance profile in one piece, since this can be more complex to manufacture than joining a bent component with the spacing profile on the end, for example by riveting.

The spacer has a spacer profile and a fitting which are pivotally connected together. Advantageously, the pivot axis is formed by a bolt, so that the longitudinal axis of the bolt is congruent with the pivot axis. Preferably, the spacer profile is laterally penetrated by the bolt, wherein the connecting piece is arranged on the lateral projections of the bolt. Another advantageous embodiment connects the connecting piece and the spacer profile by means of a sleeve which is arranged between the legs of the U-shaped connecting piece and serves as a guide for the bolt. In this case, instead of a bolt, bolt portions can also engage in the sleeve from each end of the sleeve. The sleeve can advantageously already be integrated in the spacer profile.

The penetrated by the bolt or bolt portion recess can always be advantageously designed to be longer than wide, when the spacer profile on a solar module carrier in a conventional manner, for example by means of screw, rigidly fixed and only at one end of the spacer profile, the connection piece of the spacer according to the invention is arranged. Any differences in level between the rows of solar module carriers to be connected to one another can then be compensated for in a simple manner by displacement of the pivot axis within the recess designed advantageously as a slot before, for example, the bolt forming the pivot axis is fixed in its end position. If the spacing profile at both ends in each case has a connection piece of the spacer according to the invention, level differences can already be compensated in that the pivot angle of the two connection pieces is adapted accordingly.

For the stability of the connection, it has proven to be advantageous if the connector is designed as a swivel bracket, which partially surrounds the spacing profile or vice versa is partially encompassed by the spacing profile. For example, the connector may be configured in a U-shape in cross section, the two legs laterally engage the spacer profile and are arranged with their free ends on the pivot axis, which is preferably formed by a bolt, while the preferably orthogonal to the legs arranged web of u -förmig cross-section of the stop surface is formed. In this case, the components of the connecting piece, which form the legs of the U-shaped cross-section, taper in the direction of the pivot axis for reasons of material savings.

In practice, the rows of solar module carriers are spaced as evenly as possible in order to make the best possible use of the available floor space and, on the other hand, to keep the degree of shading as low as possible. Nevertheless, it may happen that individual rows require a further or smaller distance, for example to position the rows around structures, such as around chimneys. It is advantageous if the spacer profiles of the spacer according to the invention are designed to be adjustable in length, for example, by being composed of two telescopically telescoping profiles that can be fixed by screws, locking means or the like in the desired length.

The spacer according to the invention is particularly well suited for an arrangement of at least one solar module carrier and the spacer, wherein the solar module carrier has a base with a base, a receptacle for the abutment surface of the connector of the spacer and a Fixierungsausnehmung. The fixing recess of the base may alternatively or cumulatively to the passage opening of the stop surface as lying oblong hole be designed. The spacer and the solar module carrier are preferably connected to each other in such a way that the spacer profile engages by means of a fold in a recording of the base and the stop surface, which rests flat on the front of the stand, is bolted to the front of the stand.

It is advantageous for a simple assembly, if the fixing recess of the base, which receives the fastener for the connection of base and stop surface, is further spaced from the footprint of the stand as the receptacle for the fold, since so first the fold in the recording can be spent so that subsequently a final fixation can be done using the Fixierungsausnehmung. In the reverse arrangement of recording and Fixierungsausnehmung the base, the fold of the recording could either not rest and would have to be held elsewhere until the final fixing or the fitting would have to be structurally complex. Nevertheless, such an arrangement is possible and can offer advantages for certain load directions.

In an advantageous embodiment of the arrangement comprising a spacer according to the invention and a solar module carrier, the solar module carrier has a base with a base, a recess for the fold, a counter surface for the stop surface and a Fixierungsausnehmung, which serves the stop surface by means of a bolt against the counter surface to press, wherein the fold is engaged with the receptacle. In embodiments of the spacer according to the invention, which have no bending of the spacer profile, and an edge of the stop surface may be in engagement with the receptacle. It is also possible, if there is a fold of the spacer profile, a receptacle which offers space for the fold as well as for an edge of the stop surface.

The bolt can be bolted particularly advantageous if the angle between the base and the counter surface of the base is more than 90 °. This results in that the bolt is not arranged parallel to the base, as is the case when the angle is 90 °, but obliquely upwards from the pressed onto the counter surface stop surface looks out, so is easier to access and simplifies installation. In a particularly advantageous embodiment of the arrangement of a spacer according to the invention and a solar module carrier, the fixing recess is formed as a round hole with thread, so that it acts as a nut for the screw and a component can be saved.

The invention will be explained in more detail by way of example with reference to the drawings.

LIST OF REFERENCE NUMBERS

1

spacer

2

Solar module carrier

3

connector

4

spacers

5

swivel axis

6

bolt

6a

shell

7

stop surface

8th

Passage opening of the stop surface ( 7 )

9

End of the distance profile ( 4 )

10

fold

11

first recess of the spacer profile ( 4 )

11 '

second recess of the spacer profile ( 4 )

12

first profile leg of the spacer profile ( 4 )

12 '

second profile leg of the spacer profile ( 4 )

13

first pivoting arm of the connecting piece ( 3 )

13 '

second swivel arm of the connector ( 3 )

14

Arrangement of spacers ( 1 ) and solar module carrier ( 2 )

15

stand

16

footprint

17

admission

18

counter surface

19

fixing recess

20

first hole

20 '

second hole

21

rivet

α

Angle between stop ( 7 ) and counter surface ( 18 )

K

locknut

1 shows the components of the spacer (see 3 , Para. 1 ) in a perspective view obliquely from above, wherein the distance profile ( 4 ) at its end ( 9 ) is not folded. The trained as a hollow box profile distance profile ( 4 ) is bevelled and to its end ( 9 ) open. The opposite sides of the distance profile ( 4 ), which is the first (here based on a less stable U-profile ( 12 ) and second profile leg ( 12 ' ), each have a first ( 11 ) and a second recess ( 11 ' ), both of which are each formed as a slot, wherein the longitudinal orientation of the slots orthogonal to the bolt ( 6 ) and the sleeve ( 6a ) after joining the individual components of the spacer (see 3 , Para. 1 ) formed pivot axis (see 2 , Para. 5 ) runs. Also shown is the to the thread (not shown) of the bolt ( 6 ) matching lock nut (K). 1 additionally shows that with the distance profile ( 4 ) connecting piece ( 3 ) with the first ( 13 ) and the second pivot arm ( 13 ' ) as well as the stop surface ( 7 ), in which the passage opening ( 8th ), which is embodied here as a lying slot. The swivel arms ( 13 . 13 ' ) have here in each case a bore ( 22 . 22 ' ), of which the pivot axis (see 2 , Para. 5 ) forming bolts ( 6 ) are penetrated, whereby instead of the holes ( 22 . 22 ' ) and the bolt ( 6 ) also bolt portions (not shown) for engagement in the recesses ( 11 . 11 ' ) of the distance profile ( 4 ) the swivel arms ( 13 . 13 ' ) can be formed.

2 shows a perspective view of the spacer ( 1 ) with distance profile ( 4 ) and fitting ( 3 ) diagonally from below. You can see here a at the bottom of the distance profile ( 4 ) at the end (see 1 , Para. 9 ) with rivets ( 21 ) attached component that the fold ( 10 ) having. The spacer ( 1 ) is shown here in a pivoting position, in which the stop surface ( 7 ) and the fold ( 10 ) touch. The pivot axis ( 5 ) is congruent with the longitudinal axis of the bolt ( 6 ).

3 shows a perspective view of the spacer ( 1 ). To recognize here are the connection piece ( 3 ), the distance profile ( 4 ), the pivot axis ( 5 ), the bolt ( 6 ), the sleeve ( 6a ), the stop surface ( 7 ), which designed as a recumbent slot opening ( 8th ), which are orthogonal to the pivot axis ( 5 ) aligned slot executed second recess ( 11 ' ) of the distance profile ( 4 ) as well as the first ( 13 ) and second pivot arm ( 13 ' ) of the connector ( 3 ).

4 shows a perspective view of an arrangement ( 14 ) from the spacer ( 1 ) with connection piece ( 3 ) and distance profile ( 4 ) and one of the solar module carriers ( 2 ). Here it can be seen that the solar module carrier ( 2 ) a stand ( 15 ) with a footprint ( 16 ), a recording ( 17 ) for the fold ( 10 - covered by the second pivot arm ( 13 ' ) of the connector ( 3 )) and the stop surface ( 7 ). The stop surface ( 7 ) here has a lying, parallel to the pivot axis ( 5 ) aligned slot executed passage opening ( 8th ), behind which a part of the counter surface ( 18 ) of the stand ( 15 ) with the round as a threaded hole (not shown) executed Fixierungsausnehmung ( 19 ), wherein the fixing recess ( 19 ) further from the stand area ( 16 ) is spaced apart than the receptacle ( 17 ). The advantage here is that the angle (α) between floor space ( 16 ) and counter surface ( 18 ) is greater than 90 ° and the distance profile ( 4 ) to its end (see 1 , Para. 9 ) is chamfered, so that the screw bolt (not shown), by means of which the stop surface ( 7 ) against the counter surface ( 18 ) is easily accessible.

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

• WO 002002073703 A1 [0001]
• DE 202010015848 U1 [0001]
• DE 102010024514 A1 [0001]
• DE 202006019837 U1 [0001]
• DE 102009022746 A1 [0001]
• DE 202012001526 U1 [0001]
• DE 202010006377 U1 [0002, 0006]

Claims (20)

Spacers ( 1 ) for solar module carrier ( 2 ), characterized by a connecting piece ( 3 ) and a distance profile ( 4 ), the fitting ( 3 ) with the distance profile ( 4 ) about a transversely to the longitudinal orientation of the spacer profile ( 4 ) arranged pivot axis ( 5 ) is rotatably connected and for the solar module carrier ( 2 ) one parallel to the pivot axis ( 5 ) arranged stop surface ( 7 ) with at least one passage opening ( 8th ) for a fastener. Spacers ( 1 ) according to one of the preceding claims, characterized in that the stop surface ( 7 ) completely or partially over one end ( 9 ) of the distance profile ( 4 protrudes). Spacers ( 1 ) according to one of the preceding claims, characterized in that the spacing profile ( 4 ) is designed as a hollow box profile. Spacers ( 1 ) according to one of the preceding claims, characterized in that the passage opening ( 8th ) as parallel to the pivot axis ( 5 ) aligned slot is executed. Spacers ( 1 ) according to one of the preceding claims, characterized in that the end ( 9 ) of the distance profile ( 4 ) a fold ( 10 ) for engaging in a receptacle of one of the solar module carrier ( 2 ), wherein the fold ( 10 ) as an integral formation of the spacer profile ( 4 ) or as a separate part with the spacing profile ( 4 ) connected is. Spacers ( 1 ) according to one of the preceding claims, characterized in that the spacing profile ( 4 ) with the connector ( 3 ) by means of a bolt ( 6 ) and / or by means of a sleeve ( 6a ), wherein the longitudinal axis of the bolt ( 6 ) and / or the sleeve ( 6a ) with the pivot axis ( 5 ) is congruent. Spacers ( 1 ) according to one of the preceding claims, characterized in that the spacing profile ( 4 ) at least one recess ( 11 ), wherein the bolt ( 6 ) and / or the sleeve ( 6a ) the recess ( 11 ) penetrates completely or partially. Spacers ( 1 ) according to claim 7, characterized in that the distance profile ( 4 ) opposite profile legs ( 12 . 12 ' ), each having a recess ( 11 . 11 ' ) exhibit. Spacers ( 1 ) according to one of claims 7 or 8, characterized in that the recess ( 11 ) is longer than it is wide and in its longitudinal orientation orthogonal to the pivot axis ( 5 ) is arranged. Spacers ( 1 ) according to one of the preceding claims, characterized in that the connecting piece ( 3 ) as a swivel bracket with two opposing pivot arms ( 13 . 13 ' ) is trained. Spacers ( 1 ) according to claim 10, characterized in that the pivot arms ( 13 . 13 ' ) the distance profile ( 4 ) partially surround. Spacers ( 1 ) according to one of claims 5 to 11, characterized by a pivoting position of the connecting piece ( 3 ), in which stop surface ( 7 ) and bevel ( 10 ) touch. Spacers ( 1 ) according to one of the preceding claims, characterized in that the spacing profile ( 4 ) is adjustable in length. Arrangement ( 14 ) from a spacer ( 1 ) according to one of the preceding claims and a solar module carrier ( 2 ), characterized in that the solar module carrier ( 2 ) a stand ( 15 ) with a footprint ( 16 ), a recording ( 17 ) for the fold ( 10 ) and / or an edge of the stop surface ( 7 ), a counter surface ( 18 ) for the stop surface ( 7 ) and a fixing recess ( 19 ) having. Arrangement ( 14 ) according to claim 14, characterized in that the fixing recess ( 19 ) further from the stand area ( 16 ) is spaced apart than the receptacle ( 17 ). Arrangement ( 14 ) according to claim 14 or 15, characterized in that the fold ( 10 ) with the recording ( 17 ) is engaged. Arrangement ( 14 ) according to one of claims 14 to 16, characterized in that the stop surface ( 7 ) with the recording ( 17 ) is engaged. Arrangement ( 14 ) according to one of claims 14 to 17, characterized in that the abutment surface ( 7 ) by means of a screw bolt against the counter surface ( 18 ) is pressed. Arrangement ( 14 ) according to one of claims 14 to 18, characterized in that the angle (α) between footprint ( 16 ) and counter surface ( 18 ) is more than 90 °. Arrangement ( 14 ) according to claim 19, characterized in that the fixing recess ( 19 ) of the stand ( 15 ) is formed as a round hole and has a thread.

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