DE20119629U1 - Stands, in particular roof stands for photovoltaic and thermal modules - Google Patents

Description

Stands, especially roof stands for photovoltaic and thermal modules

The invention relates to a stand, in particular a roof stand for photovoltaic and thermal modules, which contains module frames and frame brackets.

It is generally known that individual modules of solar generators are either mounted and wired directly at the installation site using individual screw connections or that they are pre-assembled on support units at the installation site and then attached at the destination.

DE-OS 42 34 068 describes a fastening system for solar modules, which consists of a hollow central part with two opposing U-shaped flanges that do not touch each other. The solar modules are inserted into this gap. The aluminum profile is mechanically stable enough to take on the supporting function. It can also be used for power supply and earthing.

DE-OS 197 48 815 proposes to firmly connect several modules to a module carrier using screw, rivet or adhesive connections. These pre-assembled module units are suitable for roof-mounted and roof-in installation as well as free-standing installation with standard mounting substructures. The structure of the module carrier is not described in detail.

DE-OS 199 22 795 describes a flat roof/floor frame, in particular for solar modules. The frame has a module holding device and a fastening device fixed to it for fixing the frame to the flat roof or floor. The module holding device has at least one circular groove in which at least one holding element for the solar module can be fixed.

The object of the invention is a universal self-supporting stand, in particular roof stand for photovoltaic and thermal modules, which can be adapted to the most diverse modules and transported pre-assembled to the place of use and is designed for a long service life and protected against environmental influences.

This object is achieved according to the invention by a universal, self-supporting stand which is particularly suitable as a roof stand for photovoltaic and thermal modules and is constructed in such a way that it contains a complete frame made of high-strength horizontal and vertical hollow body profiles with grooves and corner connectors, designed to accommodate the dimensions and electrical/mechanical loads of the modules to be accommodated. It can accommodate open-type, framed and/or unframed photovoltaic modules or thermal solar modules with the appropriate static design and contains universal frame brackets for connecting to the roof.

In an embodiment of the invention, the hollow body profile is a bright-finished and/or corrosion-protected aluminum extruded profile or a special lightweight profile. In a further embodiment, the hollow body profile has at least one hammerhead groove and/or hollow chamber groove and/or rectangular groove.

According to the invention, the modules are attached to the frame by means of connecting elements directly or by means of module brackets.

If there are high demands on environmental resistance, hollow body profiles in anodized version or with a surface coating in powder or paint coating are used.

In the embodiment of the invention, the complete frame is secured via universal frame brackets as roof hooks and via tabs and spacers in the rectangular groove of the

Hollow body profiles are attached to the roof using connecting elements. According to the invention, for large frames, several vertical and/ _or horizontal hollow body profiles with lengths corresponding to the grid of the roof rafters and/or roof battens are connected via connecting straps and hollow chamber grooves. In a further embodiment, the frame is designed as a frame grid with several horizontal and/or vertical hollow body profiles connected via connecting angles.

According to the invention, in the case of flat roof mounting or free-standing installation on the ground, the complete frame is connected at the required installation angle via stable and ballasted metal or concrete substructures via straps or directly via known connecting elements.

In one embodiment of the invention, for advertising purposes, a small frame on the horizontal or vertical upper hollow body profile is connected directly to a photovoltaic module at the corresponding installation angle as a frame triangle with a special gusset plate and contains an advertising surface with lighting devices, signal generators, a control device and an energy storage device.

The invention is explained in more detail below using an exemplary embodiment. The accompanying drawings show:
Fig. 1: small frame
Fig. 2: large frame

Fig. 3: Frame with photovoltaic-thermal solar modules Fig. 4: Frame triangular arrangement for advertising purposes Fig. 5: Section AA
Fig. 6: Section BB
Fig. 7: Section CC
Fig. 8: Section DD
Fig. 9: View X
Fig. 10: View Y

The stand according to the invention is self-supporting and can be used universally. If the structure according to the invention is maintained, it can be modified for a wide variety of applications. Its main application is as a self-supporting roof stand for installing photovoltaic and thermal solar modules on flat or pitched roofs.

According to Fig. 1, 2 and 3, the arrangement according to the invention consists of complete small or large frames 1, which in the case of photovoltaic modules 9 are designed according to the electrical power to be transmitted and are prefabricated as an assembly. The frames 1 are made of extruded horizontal and vertical aluminum hollow body profiles 2 and are screwed together using concealed corner connectors 3 located in the hollow chamber groove 12 and pre-assembled on the ground. Depending on the size of the frames 1, if required according to Fig. 5, 6 and 7, the horizontal and/or vertical hollow body profiles 2 are connected using connecting straps 4 from a certain size to ensure handling and to prefabricate optimized profile lengths. However, the large frame 1 can also be screwed together directly on the roof under certain local conditions.

After pre-assembly, the complete mechanical frame 1 prefabricated on the ground is lifted onto the pitched or flat roof according to its operating weight, by hand for small frames 1 and by means of a hoist for larger frames 1.

-3-

In the case of the pitched roof according to Fig. 9, the frame brackets 6 are already pre-mounted as roof hooks on the rafters 19 and at the appropriate distances according to the existing statics in order to ensure stable and secure support and the required setting angle for solar radiation on the photovoltaic modules 9 or thermal solar modules 14 in the setting angle of the roof and the roof shape. The frame brackets 6 as roof hooks are firmly connected to the horizontal and/or vertical aluminum hollow body profiles 2 via tabs 7 and intermediate layers 18 in the rectangular groove 13 behind the roof batten 20 and under the roof tile 21 using the necessary connecting elements, such as screws, washers and self-locking nuts. After the pre-assembly of the complete frame 1 on the pitched roof, the modules 9 are finally assembled; 14 via module angle 10, special nuts 8 and cylinder head screws with hexagon socket in the hammer head groove 11 according to Fig. 8 and their electrical wiring or mechanical connection of the connecting cables.

For flat roofs or when the modules are installed outdoors using so-called connecting frames that are fitted with ballast, the frame assembly and screwing of the frames 1 is carried out using the same construction principle as for pitched roofs. The connecting frames are reproduced at an angle optimized for solar radiation in accordance with the pitched roof and are installed freely. Depending on the harsh environmental influences, the aluminum hollow body profiles 2 are anodized or have a surface finish with powder and/or paint coating. All other steel and connecting elements are preferably made of stainless steel.

In an extension of the application area, for advertising purposes according to Fig. 4 and 10, the photovoltaic modules 9 can be screwed together as a triangular frame arrangement 15 directly on top of the horizontal and vertical aluminum hollow body profile 2 and stabilized using special gusset plates 16. By changing the setting angle, the sunlight can be optimally directed onto the photovoltaic module 9. The electrical energy supplied by the module 9 can be used directly or after being stored in an accumulator for the advertising area of the advertising frame. A wide variety of advertising effects can be used here via a control device using lamps, signal generators 17, etc.

In a special design of smaller and larger frames 1, these can be designed as so-called frame grids with additional horizontal and/or vertical aluminum hollow body profiles 2 in between and connected by means of connecting angles 5 and corresponding connecting elements.

List of reference symbols Frame »ΦC · · 1 Aluminium hollow body profile ; 2 Corner connectors : 3 Connecting strap 4 Connection angle 5 Frame bracket roof hook 6 Tab 7 Special nut 8th Photovoltaic module 9 Module angle 10 Hammer head groove 11 Hollow chamber groove 12 Rectangular groove 13 thermal solar module 14 Frame triangle setup 15 Special gusset plate 16 Lamps or signaling devices 17 Intermediate layers 18 Roof rafters 19 Roof batten 20 Roof tiles 21

Claims (10)

1. Stand, in particular a roof stand for photovoltaic and thermal modules, which contains module frames and frame holders, characterized in that open-type, framed and/or unframed photovoltaic modules ( 9 ) or thermal solar modules ( 14 ) and universal frame holders (6) and tabs (7) for connecting to the roof are attached to a complete frame ( 1 ) made of high-strength horizontal and vertical hollow body profiles ( 2 ) with grooves ( 11 ; 12 ; 13 ) and corner connectors ( 3 ) designed for the dimensions and occurring electrical/mechanical loads of the modules ( 9 ; 14 ) to be accommodated. 2. Stand according to claim 1, characterized in that the hollow body profile ( 2 ) is a bright-pressed and/or corrosion-protected extruded aluminum profile. 3. Stand according to claims 1 and 2, characterized in that the hollow body profile ( 2 ) has at least one hammer head groove ( 11 ) and/or hollow chamber groove ( 12 ) and/or rectangular groove ( 13 ). 4. Stand according to claims 1 to 3, characterized in that the modules ( 9 ; 14 ) are attached to the frame by means of connecting elements directly or by means of module angles ( 10 ). 5. Stand according to claims 1 to 4, characterized in that the hollow body profiles ( 2 ) are used in an anodized design or surface-coated in powder or lacquer coating. 6. Stand according to claims 1 to 5, characterized in that the complete frame ( 1 ) is fastened to the roof by means of connecting elements via universal frame brackets ( 6 ) as roof hooks and via tabs ( 7 ) and intermediate layers ( 18 ) in the rectangular groove ( 13 ) of the hollow body profiles ( 2 ). 7. Stand according to claims 1 to 6, characterized in that for large frames ( 1 ) several vertical and/or horizontal hollow body profiles ( 2 ) with lengths corresponding to the grid of the roof rafters and/or the roof battens or corresponding to the number of modules are connected via connecting straps ( 4 ) and hollow chamber grooves ( 12 ). 8. Stand according to claims 1 to 7, characterized in that the frame ( 1 ) is designed as a frame grid with several horizontal and/or vertical hollow body profiles ( 2 ) connected via connecting angles ( 5 ). 9. Stand according to claims 1 to 8, characterized in that in the case of flat roof mounting or free-standing installation on the ground, the complete frame ( 1 ) is connected at the required installation angle via stable and ballasted metal or concrete substructures via brackets ( 7 ) or directly via known connecting elements. 10. Stand according to claims 1 to 5, characterized in that a small frame ( 1 ) on the horizontal or vertical upper hollow body profile ( 2 ) is connected directly to a photovoltaic module ( 9 ) at the corresponding installation angle as a frame triangle ( 15 ) with a special gusset plate ( 16 ) and contains an advertising surface with lighting means ( 17 ), signal transmitters, a control device and an energy storage device.