DE202008015304U1 - Mounting arrangement for solar panels - Google Patents

Abstract

Mounting arrangement (10) for solar panels (1), in particular for free-field mounting, with
a plurality of paired posts (12, 14) each intended to rest on a foundation,
a plurality of rafters (20), wherein a rafter (20) in each case connects the posts (12, 14) of a pair of posts,
a plurality of purlins (30) each supported on at least one rafter (20), and
a plurality of solar panels (1) disposed on the purlins (30),
characterized in that
the rafters (20) have a bearing surface (22) for the purlins (30), which is curved at least in sections transversely to the extension direction of the rafters (12, 14).

Description

Technical area

The The invention relates to a mounting arrangement for solar panels, in particular for the Free-field mounting, according to the preamble of claim 1.

State of the art

solar panels Electricity generation is increasingly becoming widespread in large-scale free-field installations used. The solar panels are on frame structures mounted, which for optimal alignment of the solar panels to the sun.

So For example, a brochure from Solarworld AG on the product "Sunfix" discloses a generic free-field mounting system. This is characterized by the fact that the construction is formed by tables is between which so-called Einhänger be introduced. Indeed has shown that known, generic systems are not optimal or only with the use of additional Inserts to variable terrain topographies let adjust.

Presentation of the invention

It is therefore an object of the present invention, a mounting arrangement for solar panels to provide the initially mentioned type, the simple installation and construction a good fit to changing terrain topographies allows.

These The object is achieved by a Mounting arrangement for Solar panels solved according to claim 1. Particularly preferred embodiments of the invention are in the dependent claims specified.

Of the Invention is based on the finding that in virtually every Free-field application changeable terrain topographies occur, especially since the planing large areas as extremely complex and costly designed. The invention therefore aims to the Components of the mounting arrangement from the outset for variable terrain topographies to design without this additional inserts are required or excessive local stresses arise. Against this background, the invention provides that in a generic mounting arrangement the rafters a bearing surface for the Have purlins, which are transverse to the direction of extension of the rafters curved at least in sections is.

On this way you can the purlins at different angles safely and without load peaks be placed on the rafters and fixed, without special, Angled inserts between purlins and rafters. This results a good and low-voltage adaptability of the mounting arrangement on changing terrain topographies with simple installation and construction.

The Design of the bearing surfaces is not particularly limited within the scope of the invention. in the With regard to a uniform and Stable adjustability of the angle of inclination of each purlin has However, it proved to be advantageous that the bearing surface according to a Development of the invention is at least partially curved arcuate.

As well is the exact design of the rafters in the context of the present Invention not particularly limited so that, for example, hollow sections, U-profiles and various other Profiles can be used. According to one Further development of the invention, it is provided that the rafters are formed in cross section as a Z-profile, wherein the support surface by a flange of the Z-profile is formed. This results with good static properties a good accessibility and thus also a easy installation of the profile. Furthermore, the Z-profile as needed also a longitudinal as well as being turned around a transverse axis, whereby a variety of built-in and design options yield and the adaptability the system is further increased to the respective requirements. It can optionally also formed both flanges of the Z-profile as a curved support surface be.

According to one Development of the invention is further provided that in the bearing surface at least a slot is provided, extending in one of the extension direction extends the rafter deviating direction, in particular across to the extension direction of the rafters. By means of this long hole, the respective purlins in any position or under each Any angle is securely connected to the rafters, for example in which a screw passed through the purlins and the slot and in the usual way is fixed with a mother.

Furthermore, it is particularly preferred that the slot is arranged asymmetrically with respect to a running in the direction of extension of the rafters center line of the support surface. In this way it can be ensured that no excessive torsional moments are introduced into the respective purlins by the slot being made shorter, for example, towards the free end of the respective flange than towards the respective web of the Z-profile. As a result, although the Winkelvertellungsbe limited in one direction, but this can be easily remedied by turning the profile if necessary.

According to one Further development of the invention, it is further provided that adjacent Purlins are connected to each other at shock points. hereby not only results in an overall increased stability of the overall system, but also a continuous course of the solar panels. there For example, it is particularly preferred that at least one impact be preferred all bumps, between adjacent posts are arranged. In this concept will be thus the shock areas the purlins and the bearing areas of the purlins on the rafters separated. This results in a significantly simplified assembly, while at the same time a higher one and more consistent adaptability the mounting arrangement to changeable terrain topographies allows becomes.

The piercing points between adjacent purlins can designed in the invention in different ways be. According to one Development of the invention, however, is provided that the flexural rigidity lower in the area of the impact is considered as the flexural rigidity of the purlins, respectively Purlin longitudinal direction. this makes possible a certain deformation concentration at the impact points, in particular with strong terrain curvatures is advantageous. Further leaves itself a butt joint perform much easier with low bending stiffness.

Especially advantageous is the said execution of the shock with low bending stiffness further in a development of the invention, in which the purlins connected by shocks after Kind of a Gerber vehicle are arranged, the shocks substantially are arranged at the moment zero points, assuming a evenly distributed vertical load. The design allows that at the points of impact despite simple connecting means with low bending stiffness neither the carrying capacity endangered is still excessive deformations, slope Joints or the like occur.

on the other hand It should be noted that within the scope of the invention joints between neighboring purlins not undesirable are. Rather, according to a Continuing the connection provided that at the points of impact between the faces of adjacent purlins in the assembled state in each case a joint gap is provided. In this way, forcing forces within the mounting arrangement, for example, as a result of temperature expansions could arise avoided or at least reduced to an acceptable level. This answers the safety of the carrier and durability of the overall system.

there it is particularly preferred that provided at the shock points sliding elements are to make a relative shift between adjacent purlins in purlin-lengthwise direction to facilitate. This ensures that the joint gaps their Can fully develop stress relief effect without, for example Connecting screws or the like damaged or only with a small amount Strength can be attracted. Although the design of the sliding elements in the context of the present Invention diverse is variable, it is preferred in the sliding elements Teflon elements, as these have high sliding properties with high durability and resistance.

Brief description of the drawings

1 shows schematically a front view of a mounting arrangement for solar panels according to a preferred embodiment of the present invention;

2 schematically shows a side view of in 1 shown mounting arrangement;

3 schematically shows a sectional view of a rafter, which in the in 1 to 2 shown mounting arrangements is used;

4 schematically shows a detailed view of a butt joint between adjacent purlins, which in the in 1 to 2 shown mounting arrangements is used.

Detailed description more preferred embodiments

preferred embodiments The invention will be described below in detail with reference to the accompanying drawings.

A mounting arrangement 10 as a preferred embodiment of the present invention is in the 1 and 2 schematically shown in a front view and a side view. The mounting arrangement 10 serves for storing and aligning solar panels 1 , especially for outdoor installation in large-area free-form solar panels.

As in 1 and 2 can be seen, includes the mounting arrangement 10 initially a plurality of paired, vertical posts 12 . 14 , each resting on a foundation not shown in detail. The foundation may be a concrete foundation, for example But also act around so-called rotary foundations, which are helical and are screwed into the ground. The posts can do this 12 . 14 be made adjustable in length to the inclination of the solar panels 1 to adapt to the local conditions or the angle of incidence of the sun.

On each pair of posts 12 . 14 rests in the present embodiment, a rafter 20 that with the posts 12 . 14 for example, connected via screws.

On the rafters 20 are - similar to a roof construction - several purlins 30 Arranged on the rafters 20 support and are also connected to these with screws. On the purlins 30 are finally the solar panels 1 attached.

The design of the rafters 20 according to the present embodiment is in 3 shown closer. It can be seen that the rafters 20 formed in the present embodiment in cross-section as a Z-profile, wherein the upper flange 26 of the Z-profile a bearing surface 22 for the purlins 30 represents. Here is the upper flange 26 curved in the present embodiment, that the bearing surface 22 transverse to the extension direction of the rafters 20 (from left to right in 3 ) is curved, which in the present embodiment is a circular arc curvature. However, it should be noted that the rafters 20 and in particular the upper flange 26 can also be configured in other ways, as long as the bearing surface 22 for the purlins 30 transverse to the extension direction of the rafters 20 at least partially curved.

In the support surface 22 of chafing 20 is a slot in the present embodiment 24 provided, in the present embodiment, transversely to the extension direction of the rafters 20 (from left to right in 3 ). Here is the slot 24 in the present embodiment, asymmetrically with respect to an extension direction of the rafters 20 extending center line M of the bearing surface 22 arranged. In this case, the slot extends 24 longer to the jetty 28 of the Z-profile 20 out than from the jetty 28 path. In this way, the static properties of the Z-profile 20 be optimally exploited, taking in the direction of the bridge 28 towards a larger angle of inclination β on the support surface 22 overlying purlins (in 3 not shown) as in the opposite direction (inclination angle α).

The overall arrangement of the purlins 30 is in 1 best to recognize. The purlins 30 run across the rafters 20 through and follow the terrain topography. This will be adjacent purlins 30 at points of impact 32 interconnected, which will be explained in more detail below. These shock points 32 are not in the present embodiment - as usual in the art - in the field of rafters 20 arranged, but each between adjacent rafters 20 or between adjacent posts 12 . 14 , More specifically, the strike points 32 in which the bending stiffness in the purlin longitudinal direction is less than the bending stiffness of the purlins 30 itself, arranged in the present embodiment in the manner of a Gerber carrier. That is, the shock points 32 are essentially at the moments zero points, which result in assuming a uniformly distributed vertical load. As a result, the stress in the area of the impact points 32 minimized, and the shock points 32 can be performed with low bending stiffness, so at the points of impact 32 Curvatures can be concentrated to adapt the mounting arrangement to the terrain topography.

As in 1 also best seen, are in the present embodiment only in every second field in each case two strike points 32 arranged. In this way, on the one hand in each second field prefabricated tables, each with, for example, four posts 12 . 14 , two rafters 20 and several purlins 30 prefabricated and set up. In the other, intermediate fields then individual purlins 30 inserted and at the points of impact 32 be connected to the tables.

The connection of the individual purlins 30 each other is in 4 shown closer. After that are the purlins 30 at the points of impact 32 in each case by means of at least one connecting element 34 (For example, a flat steel element) connected. In order to allow temperature expansion without constraint, it is at the shock points 32 one joint gap each 36 between the faces of adjacent purlins 30 intended. Furthermore, for this purpose are at the points of impact 32 Sliding elements 38 (eg, teflon elements) to provide relative displacement between adjacent purlins 30 in purlin longitudinal direction easier.

Claims (12)

Mounting arrangement ( 10 ) for solar panels ( 1 ), in particular for free-field mounting, with a plurality of paired posts ( 12 . 14 ), which are each intended to rest on a foundation, a plurality of rafters ( 20 ), whereby a rafter ( 20 ) each the posts ( 12 . 14 ) of a pair of posts, a plurality of purlins ( 30 ), each on at least one rafter ( 20 ) and a plurality of solar panels ( 1 ) on the purlins ( 30 ), characterized in that the rafters ( 20 ) a support surface ( 22 ) for the purlins ( 30 ), which are transverse to the extension direction of the rafters ( 12 . 14 ) is curved at least in sections. Mounting arrangement for solar panels according to claim 1, characterized in that the bearing surface ( 22 ) is at least partially curved in a circular arc. Mounting arrangement for solar panels according to claim 1 or 2, characterized in that the rafters ( 20 ) are formed in cross-section as a Z-profile, wherein the support surface ( 22 ) is formed by a flange of the Z-profile. Mounting arrangement for solar panels according to one of the preceding claims, characterized in that in the support surface ( 22 ) at least one slot ( 26 ) provided in one of the extension direction of the rafters ( 20 ) deviating direction extends, in particular transversely to the extension direction of the rafters ( 20 ). Mounting arrangement for solar panels according to claim 4, characterized in that the slot ( 26 ) asymmetric with respect to an extension direction of the rafters ( 20 ) extending center line of the bearing surface ( 22 ) is arranged. Mounting arrangement for solar panels according to one of the preceding claims, characterized in that adjacent purlins ( 30 ) with each other at strike points ( 32 ) by means of at least one connecting element ( 34 ) are connected. Mounting arrangement for solar panels according to claim 6, characterized in that at least one shock ( 32 ), preferably all impacts ( 32 ) between adjacent posts ( 20 ) are arranged. Mounting arrangement for solar panels according to claim 6 or 7, characterized in that the flexural rigidity in the region of the joint ( 32 ) is less than the bending stiffness of the purlins ( 30 ), in each case considered in purlin longitudinal direction. Mounting arrangement for solar panels according to one of claims 6 to 8, characterized in that the shocks ( 32 ) connected purlins ( 30 ) are arranged in the manner of a Gerber carrier, wherein the joints ( 32 ) are arranged substantially at the moment zero points, which result in assuming a uniformly distributed vertical load. Mounting arrangement for solar panels according to one of claims 6 to 9, characterized in that at the points of impact ( 32 ) between the faces of adjacent purlins ( 30 ) in the assembled state in each case a joint gap ( 36 ) is provided. Mounting arrangement for solar panels according to claim 10, characterized in that at the points of impact ( 32 ) Sliding elements ( 38 ) are provided for relative displacement between adjacent purlins ( 30 ) in purlin longitudinal direction. Mounting arrangement for solar panels according to claim 11, characterized in that the sliding elements ( 38 ) have a Teflon element.