DE102013004914A1 - Assembly method for connecting adjacent solar module frames - Google Patents

Abstract

An assembly method for connecting adjacent solar module frames (1, 2) is presented, which is characterized by the following steps. In the first step, a bolt (3), which is arranged parallel to the side edge (1a) of the first solar module frame (1) and preferably has a widened head (3a), is placed in a concave recess (4a) of a pin on the side edge (2a) of the second solar module frame (2) arranged bearing (4) made. In the second step, a pin (5), which is arranged parallel to the side edge (1a) of the first solar module frame (1) and has a free, preferably conically tapering end (5a) and an opposite end (5b), which preferably has teeth (5c) a position is spent in which the free end (5a) is directed towards a recess (6a) which is part of a receptacle (6) which is arranged on the side edge (2a) of the second solar module frame (2) and is designed as an open or closed torus. In the third step, the second solar module frame (2) is displaced against the first solar module frame (1) along an axis (7) running parallel to the side edges (1a, 2a), the receptacle (6) engaging around a longitudinal section of the pin (5).

Description

Installing solar modules on flat roofs is a task that requires a systematic approach that is tailored to the respective uprising components. The solar modules are usually arranged on flat roofs side by side to rows, which in turn are placed one behind the other. This raises the problem that adjacent solar module frame must be connected together so that on the one hand, in particular against wind loads sufficiently rigid connection within the series arises and on the other hand any unevenness of the footprint can be compensated during the assembly process. In addition, the assembly process must be fast, with no special tool and can be performed by a person to keep costs low.

It is therefore an object to provide an assembly method for connecting adjacent solar module frame that allows unevenness of the footprint for the solar module frame in a simple and fast way to compensate during the assembly process, at the same time creates a stable against wind loads connection, if possible of a Person alone is feasible and offers as little as possible errors during installation.

The Utility Model DE 20 2012 005 162 U1 already discloses a system of adjacent solar modules, which are laterally interconnected, but does not address how the composite created or at least two adjacent solar module frame under real-world conditions, ie not completely flat shelves, stable against wind loads and at the same time compensate for unevenness of the footprint.

According to the invention, such a mounting method comprises at least three steps, namely as a first step, placing a bolt arranged parallel on the side edge of a first solar module frame into a concave recess of a bearing arranged on the side edge of the solar module frame to be connected. It is advantageous if the bolt and the bearing are each arranged in the same relative position along the side edge of the respective solar module frame.

Since solar modules are sensitive on the one hand and unwieldy on the other hand, this first step is important in order to ensure the handling by only one person. The two laterally to be connected solar module frame are first, preferably including the pre-assembled photovoltaic modules, with the corresponding side edges, as usual, placed on the footprint next to each other. It does not matter which angle of attack the photovoltaic modules already have due to the respective stud work. Then, the first of the two solar module frames to be connected is raised on the opposite side to be connected and held in balance. The lifting of the frame part, which carries the bolt, must then take place only a few inches above the plane of the footprint to mount the bolt to the bearing with its concave recess on the side edge of the second solar module frame.

In which direction the opening of the concave recess of the bearing is directed, is initially irrelevant, as far as the opening is not inclined to the footprint and the bottom of the recess is thus no longer suitable for a Auflagerung. Nevertheless, a downwardly directed opening for a placement of the bolt in the concave recess is not excluded if the opening width is slightly narrower than the bolt diameter and is limited by resilient edges, which are adapted to hold the bolt in the recess. In any case, the person involved in the assembly experiences relief after being placed in the concave recess and can subsequently turn to the second and third assembly steps.

The second step is to bring a pin parallel to the side edge of the first solar module frame, which has a free end, into a position in which the free end of the pin faces a recess forming part of the side edge of the second solar module frame arranged, designed as an open or closed torus recording is. Again, it is advantageous if pins and bearings are each arranged in the same relative position along the respective edge of the solar module frame to be connected.

It when the free end of the opposite end of the pin has a toothing, the recesses are complementary to a projection of the side edge of the second solar module frame and can accommodate this temporarily is particularly advantageous. Thus, the person involved in the assembly is enabled not only to correctly position the first solar module frame with the free end of the pin over the recess of the receptacle, but also to temporarily fix the position by supporting the projection in the toothing. If the toothing has a plurality of recesses complementary to the projection, which run along the circumference of the end of the pin opposite the free end, parallel to its longitudinal extent, the position can be at different angles to the projection connecting solar module frame are supported to each other.

In the third assembly step, the second solar module frame is displaced against the first solar module frame along an axis extending parallel to the side edges, wherein the receptacle engages around a longitudinal portion of the pin. If necessary, the displacement must be such that the projection of the side edge of the second solar module frame slides out of the toothing in order to ensure free pivotability of the first solar module frame about the longitudinal axis of the pin and / or the bolt.

It is advantageous for the entire assembly process, if in each case the male and female part of the assembly formed by the bolt and the bearing bearing joint and the pin joint and the recording-forming safety joint by more than half the side length of the side edges of the to be connected solar module frame are spaced from each other.

In rare cases it is possible to set up solar module frames on a flat surface. Mostly, however, the ideal state of a consistently flat footprint is not achieved, since flat roofs are frequently to be equipped, which have unevenness, be it through cable guides, supply lines or rain gutters, to name just a few examples. A rigid side connection of adjacent solar module frame, which offers no variability, would in these cases lead to the fact that in a composite of several juxtaposed in row solar module supporting frame whose weight load including the usually necessary additional ballasting would not be evenly distributed over all provided feet. This would result in torsions and stresses within the structure that are undesirable due to the associated material fatigue or even damage. Fourth, an additional advantageous step of the assembly method therefore consists in adjusting the pivoting angle of the adjacent, connected solar module frames relative to each other along an axis extending parallel to their side edges in accordance with existing unevenness of the support surface and compensating for this.

In some cases, aligning the angular position of the second solar module frame with respect to the first solar module frame along a parallel to the side edges of the connected solar module frame is not sufficient to achieve an even load distribution on the footprint. It is then helpful to supplement the assembly process with a further step and, fifthly, to adjust the angular position along a torsion axis that is orthogonal to the side edges of the connected solar module frames. The pivoting possible about the torsion axis depends on how much play is present in the safety joint and / or the bearing joint. In a concave recess of the bearing, the opening facing upwards, ie to the plane of the solar modules and whose width is greater than the bolt diameter, the displaceability of the bolt is orthogonal to its longitudinal extent limited only by the depth of the concave recess of the bearing. The safety hinge can also have play, depending on how much smaller the pin diameter is relative to the toroidal recess of the receptacle. Advantageously, the free end of the pin tapers conically, while the contact zone of the recess of the receptacle, which here is meant only the potential contact surface between pin and receptacle, has no conicity. The conicity of the free pin end additionally facilitates the displacement of the second solar module frame against the first in the third step of the assembly process.

In order to fix the positions of the connected solar module frame to each other in addition, it is advantageous if the bolt has a widened head and a thread that has already been screwed into a protruding from the first solar module frame mating thread prior to assembly. By further screwing the bolt into the mating thread, a direct or indirect frictional engagement between the head of the bolt and the bearing can be generated in a sixth step, which finally defines the position of the bearing joint and thus also the degree of pivoting of the connected solar module frame about the pivot axis and the torsion axis ,

The assembly method according to the invention is explained in more detail below with reference to the drawings:

LIST OF REFERENCE NUMBERS

1

first solar module frame

1a

Side edge of the first solar module frame ( 1 )

2

second solar module frame

2a

Side edge of the second solar module frame ( 2 )

3

bolt

3a

Head of the bolt ( 3 )

4

camp

4a

concave recess of the bearing ( 4 )

5

spigot

5a

free end of the pin ( 5 )

5b

the free end ( 5a ) opposite end of the pin ( 5 )

5c

Toothing of the opposite end ( 5b )

6

admission

6a

Recess of the receptacle ( 6 )

7

parallel to the margins ( 1a . 2a ) extending axis

7a

swivel axis

8th

torsion

9

thread

10

head Start

1 shows the first step [i)] of the assembly process. The left picture in 1 shows the corners of the solar module frame to be connected ( 1 . 2 ) with the margins ( 1a . 2a ), whereby at the margin ( 1a ) of the first solar module frame ( 1 ) parallel to this bolt ( 3 ) with widened head ( 3a ) is arranged and in the same relative position along the side edge ( 2a ) of the second solar module frame ( 2 ) the warehouse ( 4 ) with the concave recess ( 4a ).

After performing the first assembly step, which is indicated by the double-dashed arrow, the bolt is located ( 3 ) in the concave recess ( 4a ) of the warehouse ( 4 ), as in the picture on the right 1 can be seen.

2 shows steps two [ii)] and two-a [ii-a)] and step three [iii]]. The left picture in 2 leaves the solar module frame ( 1 . 2 ), whereby at the side edge ( 1a ) of the first solar module frame ( 1 ) the pin ( 5 ) parallel to the side edge ( 1a ) and a free end ( 5a ) and an opposite end ( 5b ) having. In the advantageous embodiment of the method shown here, the free end opposite ( 5b ) a toothing ( 5c ) to the one on the side edge ( 2a ) of the second solar module frame ( 2 ) has complementary depressions.

The middle picture in 2 shows the positioning of the free end ( 5a ) of the pin ( 5 ) after performing step two [ii)] on the recess ( 6a ) of the recording ( 6 ), wherein after execution of the advantageous step two-a [ii-a)] the projection ( 10 ) in one of the recesses of the toothing ( 5c ) and is supported there. The correct orientation of the pin ( 5 ) is indicated by the two simple, pointing in the image arrows, here as additional positioning aids markings on the side edges ( 1a . 2a ), which have been brought into opposite position in step [ii]].

The right picture in 2 shows the state after the third assembly step [iii]]. It can be seen that the second solar module frame ( 2 ) along a parallel to the side edges ( 1a . 2a ) axis has been moved in the direction of the out of the image pointing simple arrow, so that now the recording ( 6 ) a longitudinal portion of the pin ( 5 ) and the lead ( 10 ) thereby from the toothing ( 5c ) has slipped out.

3 shows steps four [iv)], five [v)] and six [vi]] of the assembly process. The left picture of the upper row in 3 shows an overall view of the positioning of the solar module carrier ( 1 . 2 ) after step three [iii]]. The pivotability about one parallel to the side edges ( 1a . 2a ) of the solar module carrier ( 1 . 2 ) extending axis is indicated here by a simple curved arrow.

The middle picture of the upper row in 3 shows a detail from the left image of the top row in 3 on which the pivot axis ( 7a ) is shown as a dashed line, which is parallel to the side edges ( 1a . 2a ) of the solar module carrier ( 1 . 2 ) axes ( 7 ) and the center of the cross section of the bolt ( 3 ) goes through. The pivotability to compensate for unevenness of the footprint is illustrated here by a simple arrow pointing in both directions of pivoting.

The right image of the upper row in 3 shows a state after pivoting about the pivot axis ( 7a ). It can be seen here on the basis of the widened head ( 3a ) of the bolt ( 3 ), that the bolt ( 3 ) has not been screwed in yet. Thus, it is still possible according to step five [v)] a fine adjustment by means of a pivoting about the torsion axis ( 8th ), which is shown here as a dashed line. The concave recess ( 4a ) offers enough play for the pivoting, which is illustrated here by a simple, pointing in both Verschwenkungsrichtungen arrow.

The left picture of the lower row in 3 shows the state after step five [v)]. The two interconnected solar module carriers ( 1 . 2 ) are positioned as desired to each other, so that any bumps are balanced. In order to maintain this position not only due to the inherent weight of the overall construction including the solar modules and frequently required additional ballastings, it is advantageous, according to step six [vi]], to provide an indirect or immediate frictional engagement between the widened head (FIG. 3a ) and the warehouse ( 4 ) by placing the bolt ( 3 ) in the hidden thread ( 9 ) screwed in from the side edge ( 1a ) of the first solar module carrier ( 1 ) and points to the here a simple arrow.

The right image of the lower row in 3 Finally, FIG. 1 shows the position of the laterally interconnected solar modules (additionally secured against wind loads by step 6. 1 . 2 ) to each other in a partial section, the Margins ( 1a . 2a ) the widened head ( 3a ) of the bolt ( 3 ) and the warehouse ( 4 ).

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

• DE 202012005162 U1 [0003]

Claims (5)

Mounting method for connecting adjacent solar module frames ( 1 . 2 ) characterized by the following steps: i) placing a parallel on the side edge ( 1a ) of the first solar module frame ( 1 ), preferably a widened head ( 3a ) bolt ( 3 ) in a concave recess ( 4a ) one on the side edge ( 2a ) of the second solar module frame ( 2 ) arranged warehouse ( 4 ). ii) Spend one parallel on the side edge ( 1a ) of the first solar module frame ( 1 ) arranged pin ( 5 ) with a free, preferably conically tapered end ( 5a ) and an opposite, preferably a toothing ( 5c ) end ( 5b ) into a position in which the free end ( 5a ) on a recess ( 6a ), which is part of one of the margins ( 2a ) of the second solar module frame ( 2 ) arranged as an open or closed torus receptacle ( 6 ). iii) shifting the second solar module frame ( 2 ) against the first solar module frame ( 1 ) along a parallel to the side edges ( 1a . 2a ) axis ( 7 ), the recording ( 6 ) a longitudinal portion of the pin ( 5 ) surrounds. Mounting method according to claim 1, characterized by the following additional step: iv) aligning the angular position of the second solar module frame ( 2 ) opposite the first solar module frame ( 1 ) along a parallel to the side edges ( 1a . 2a ) extending, preferably the center of the cross section of the bolt ( 3 ) intersecting pivot axis ( 7a ). Mounting method according to one of the preceding claims, characterized by the following additional step: v) alignment of the angular position of the second solar module frame ( 2 ) opposite the first solar module frame ( 1 ) along an orthogonal to the side edges ( 1a . 2a ) extending torsion axis ( 8th ). Mounting method according to one of the preceding claims, characterized by the following additional step: vi) generation of an indirect or direct frictional connection between the head ( 3a ) of the bolt ( 3 ) and the warehouse ( 4 ) by screwing in the bolt ( 3 ) in from the side edge ( 2a ) of the second solar module frame ( 2 ) projecting thread ( 9 ). Mounting method according to one of the preceding claims, characterized by the following additional step between step ii) and step iii): ii-a) placing one on the side edge ( 2a ) of the second solar module frame ( 2 ) arranged projection ( 10 ) on the teeth ( 5c ), preferably at an oblique angle to the first solar module frame ( 1 ).

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