DE10054349A1 - Stand-off mounting for solar cell modules with electrical connections employs clip fixing for solar panels and push fit connection system - Google Patents

Abstract

The mounting consists of a rail (2) with double hat shaped profile. The solar cells (1) rest on the profile shoulders and are held in position by spring clips (12) inserted through slots in the top of the rail. Contact pads (10) are provided on the underside (for environmental protection) of the cell edges and the cells interconnected by inserting them between spring loaded contacts (21).

Description

The invention relates to an arrangement for elevating solar cells modules and for the electrical connection of the same.

Designs are known for mounting solar cell modules in which the same on supporting frames in frame construction Screw are attached. The disadvantage is that such scaffolding are composed of a number of different parts. This is theirs Manufacturing and assembly complex. The screw fastening of the individual Solar cell modules and their electrical connection with each other under Ver it is also time to use cables and screw terminals complex, the replacement of defective solar modules is difficult to carry out.

A building shown in European patent application EP 0993051 A2 wise uses a T-profile as mounting rails for the solar cell modules. The disadvantage here is that the vertical section of this profile no flat surface of the solar cell arrangement can be reached, so that deposits such. B. snow or flying sand can not slide.

The invention has the task, with their coordinated dimensions took significant improvements in both technical and economic to achieve economic considerations.

These objects are achieved according to the invention according to claim 1 thereby fulfilled that mounting rails for holding the solar cell modules double hat-shaped shape are provided. The upper section of the profile is used here the mounting and fixing of the solar cell modules during bending on the lower profile part of the easy to carry out the support seemed on the support arrangement corresponding to the respective application serve.

According to claim 2, the solar cell modules are on the contact surfaces of the upper profile part and are fixed by resilient pressure plates. before some of the dimensions of the upper profile part can be chosen so who that in the assembled state there is a continuously flat surface of the Solar cell modules together with the mounting rails results. So sand or snow deposits easily slip off.

A significant reduction in the assembly time is according to claim 3 the fixing of the solar cell modules by means of spring clips. These clips can be used without tools and, if necessary Lich, in a simple way z. B. removed for module replacement.

With the measures according to claim 4 it is achieved that the mounting rails  according to the invention to facilitate storage, packaging and Transport can be stacked on top of each other.

The electrical connection of the solar cell modules to each other achieve according to claim 5 in that the solar cell modules have extensive contact tongues on which resilient Contact pieces are attached. These contacts are electrical with connected to each other and can be used when assembling the solar cell modules can be attached with little effort.

Due to the U-shaped design of the contacting sections Contact pieces according to claim 6 are two of each contact spring achieved independent contact points. The inclination of the two U-legs result in high contact through their cut edges specific contact pressures, which are cold welding and therefore gas tight contact connection result. Through these measures, a we considerable increase in contact security even in bad conditions such as B. Moisture reached.

The essence of the invention will nä with reference to drawings ago explained.

Show it:

Fig. 1 The profile of a mounting rail according to the invention in a perspective view.

Fig. 2 The attachment of the solar cell modules in a sectional view.

Fig. 3 The connection of two solar cell modules in plan view.

Fig. 4 The same in the sectional view.

Fig. 5 The representation of the contact points in section.

Fig. 1 shows in perspective a supporting rail 2 according to the invention. It has a double hat-shaped profile, the upper profile part 3 for receiving and fixing the solar cell modules 1 , the lower profile part 4 with its bevels 5 and 6 for fastening the mounting rail 2 on egg ner supporting structure 7 . For screw fastening, the bevels 5 and 6 are provided with rows of holes. A connection z. B. by spot welding is also possible. The surfaces 8 and 9 of the upper profile part 3 serve to support the solar cell modules 1 . The recesses 13 in the surface 14 are intended for the insertion of the resilient retaining clips 12 , which can be inserted by hand without tools.

Fig. 2 shows a sectional view of a support rail 2 with montier it ten solar cell modules 1. For this purpose, these are placed on the surfaces 8 and 9 of the upper profile part 3 . Your fixation is done by resilient retaining clips 12 , which are inserted into the recesses 13 . By means of the lugs 15 and 16 there is a locking, which can be released in a simple manner if necessary. By means of the bevels 5 and 6 , the support rail 2 is fastened to the support structure 7 by screwing or spot welding. In order to facilitate storage, packaging and transport of the support rails 2 , the side parts 17 are slightly inclined to enable nesting. Here, the lugs 18 serve as defined stops.

Fig. 3 shows in plan view, the electrical connection of two solar cell modules 1. For this purpose, they have the same flat contact tongues 10 . These can easily be attached in the form of thin conductor foils, particularly in the case of thin-film solar modules. Resilient contact pieces 19 , 20 , which are connected to one another by cables, are plugged onto these contact tongues 10 during the assembly. The one-piece design of the contact pieces 19 and 20 can also be advantageous in that diesel ben are connected to one another by a web 23 . In order not to transmit any disruptive mechanical forces to the contact points, a hairpin-shaped formation of the webs 23 is appropriate.

The arrangement according to FIG. 3 is shown in section in FIG. 4. It can be seen from this that the contact tongues 10 and the associated contact-making sections 21 of the contact pieces 19 and 20 are arranged on only one side of the solar cell module 1 . In order to protect the contact points 22 from interfering influences, they are placed on the underside of the solar cell modules.

Fig. 5 shows a single contact of the contact pieces 19 , 20 in section. Due to the approximately U-shaped configuration of the contacting sections 21 , two mutually independent contact points 22 result . Due to the inclination of the two contacting sections 21 , the contact is given only at their cut edges, so that high specific surface pressures result at the contact points 22. The same can be achieved by appropriate contact materials such as, for. B. silver or tin can be further improved in that at these high specific surface pressures a cold welding and since a gas-tight connection is achieved at the contact points.

Documents to be considered: DE 31 11 969, EP 0 993 051 A2.

Claims (7)

1. Arrangement for elevating solar cell modules and for electrical connection of the same, characterized in that support rails are provided for receiving the solar cell modules, the profile cross section of which has a double hat-shaped shape, the upper profit part serving to hold and fix the solar cell modules and the lower profile part being bent has to assemble the mounting rails on a carrier arrangement. 2. Arrangement for mounting solar cell modules according to claim 1, characterized, that the solar cells resting on the contact surfaces of the upper profile part lenmodule by resilient pressure plates in connection with fastening screws are fixed. 3. Arrangement for mounting solar cell modules according to claim 1, characterized, that the fixing of the solar cell modules with spring clips takes place, which in recesses of the horizontal surface of the upper Pro filteile are used, with a releasable Ver locking is achieved with the mounting rail. 4. Arrangement for mounting solar cell modules according to the claims Chen 1 to 3, characterized, that to facilitate the storage and transport of the mounting rails Stack them by spreading the side sections of the bottom pro filteile in connection with stop lugs on the same is made possible. 5. Arrangement for mounting solar cell modules according to the claims Chen 1 to 4, characterized, that for the electrical connection of the solar cell modules trained areal  Contact tongues are attached to the same, on which elec trically connected contact pieces are plugged. 6. Arrangement for mounting solar cell modules according to claim 5, characterized, that the contacting sections of the contact pieces are U-shaped are formed, the legs of these sections being inclined have, so that contact points with high specific surface pressure ge be formed. 7. Arrangement for mounting solar cell modules according to the claims Chen 1 to 4, characterized, that the carrier rails made of sendzimir galvanized steel strip go through without waste Roll cold forming are produced.