DE20303257U1 - Support frame for bank of solar cells puts cells at optimal angle to horizontal and has straight row of posts with brackets at top holding tilted channel-section beam - Google Patents

Abstract

Each post (14) is vertical and has an angled bracket (13). The brackets are bolted to the bottom portion of a modified U-shaped longitudinal rail (3) with sloping sidewalls (6,7). The top edges of the sidewalls are turned outwards to form flanges (11,12) which are bolted or screwed (16) to the backs of the solar panels (1). The edges of the flanges (8,9) are turned downward at an angle.

Description

Fischer Bath and Heating GmbH G 803

Dorfstr. 5 27.02.2003

95339 Neuenmarkt

Holding device for solar collectors and/or solar cell arrangements

The invention relates to a holding device for a plurality of surface modules of solar collectors and/or solar cell arrangements arranged in series, which are arranged at a certain angle of inclination and distance from the ground.

Solar cells, also called sun cells, are large-area versions of photo elements. The solar cells convert the incident radiation power of sunlight directly into electrical power. The solar cells themselves can be made of doped silicon as a semiconductor semiconductor contact, but also of gallium arsenide and cadmium sulfide. In the vicinity of the barrier layer of such a cell, electron-hole pairs are separated from each other, which are created by the internal photo effect in the semiconductor when light is irradiated. This generates an electromotive force, due to which a photovoltage is generated at the terminals of the solar cell and a photocurrent flows according to the size of the load resistance (photovoltaic conversion), the product of which determines the usable electrical power. Solar cells can be connected together to form solar batteries, also called solar generators. These form surface modules that are mounted on frames and arranged on holding devices at an angle to the ground and thus to the sun so that the sunlight can be used as efficiently as possible. On the earth's surface, under ideal conditions,

Under these conditions, around 1 kW of power can be achieved per square meter of surface area. Surface modules of solar cell arrangements can be lined up to form solar power plants. In large-scale systems, surface modules of this type are therefore mounted over a longer distance, for example over several hundred meters, on supports made of wooden frames. Further rows of surface modules can then be arranged parallel to such a row. The interconnection takes place in energy converters, which convert the electrical energy generated into transportable electrical energy. Solar cells are increasingly being used to generate energy not only in countries with many sunny days, but also in temperate zones, such as Europe.

The invention is not only limited to solar generators, but can also be applied to solar collectors, for example to produce hot water for heating and domestic use. Such solar collectors are also assembled in surface modules to make them easier to install. The sun's rays heat a liquid, which can be stored and/or fed to heat exchangers for hot water preparation and heating.

In all known solutions, complex frame structures and racks are used as holding devices for the surface modules of solar cell arrays and solar collectors, which are set up at an angle of inclination between approx. 20° and approx. 40° to the ground and at a distance from it. Such holding devices are extremely complex and, due to the relatively high load, require a distance of around 2 meters for the individual frame elements, which also rest on concrete bases for alignment. It goes without saying that such a holding device is extremely expensive and can amount to around 40% of the cost of a system. In addition, the time required to create the holding device is very

long, so that a quick assembly of a solar generator for generating electricity is not possible. In addition, it has been shown that extensive electrical grounding measures are required to connect the frame parts of the surface modules. Often, especially with longer systems, alignments still have to be carried out after installation in order to prevent tension in the individual fields of the surface modules.

Based on the state of the art, the invention is based on the object of designing a holding device in such a way that an inexpensive construction of the holding device is possible and a secure hold of the surface modules on the holding device can be produced in a simple manner. Furthermore, wiring problems should be avoided by the construction and the use of the material. An arrangement should also be chosen that can be set up quickly.

The invention solves the problem by designing the holding device with the features specified in claim 1.

According to the invention, known guard rails for road construction are used as longitudinal beams, which are extremely inexpensive, rigid and usually galvanized and thus weatherproof. Such guard rails are usually supplied in 4-meter long sections or in a length of a multiple of 2 meters. This makes it possible, for example, to drive a post into the ground of the installation floor at intervals of 2 meters. The known guide posts from road construction are also used for this, which are also sold inexpensively. Such posts are approx. 1.80 m long. This makes it possible to drive the post 80 cm deep into the ground, for example, and to place a row of posts, aligned at a distance of 2 meters, over the entire length of a solar field.

the assembly of the longitudinal beam. Angle irons are mounted on the posts as supports for the longitudinal beam, for example screwed, welded or riveted. The upper beam leg extends over the upper post face, so that an essentially central support point for the longitudinal beam is provided. The longitudinal beam consists of the guard rail elements joined together, which are screwed, riveted or welded to the supports on the post.

The guard rail profile is attached in such a way that the bottom of the central base part is on the support, so that a hollow groove is created practically over the entire length of the longitudinal support. The necessary cables and, if solar collectors are used, the pipes, can be laid in this groove. The support frames of the individual surface modules of the solar collector arrangement or the solar cell arrangement are then screwed - centrally aligned - to the two symmetrically extending upper cover walls of the side profile of the guard rail.

It is clear that this not only makes assembly very easy, but also the installation of the holding device as a whole easy.
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Advantageous further developments of the invention are specified in detail in the subclaims.

In addition to the simple construction using familiar profiles as longitudinal beams, it is clear that there is a significant price advantage. With this device, the costs for a system can be reduced by over 20% compared to the costs of conventional, complex frame constructions.
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For particularly large-scale arrangements, two longitudinal beams can of course also be arranged parallel to two rows of posts, with these being spaced apart from each other.

However, for the known field sizes of the surface modules of 1 m × 2 m, a single arrangement of a longitudinal beam is usually sufficient without causing static or dynamic overloads on the holding device.

The invention is explained in more detail below with reference to an embodiment shown in the drawings.

Figure 1 shows a section of a solar battery made of solar cells in a photo perspective. The individual solar cells have a size of approx. 100 cm x approx. 200 cm or approx. 100 cm x approx. 100 cm and are assembled to form module fields of approx. 1 m x approx. 2 m or approx. 1 m x approx. 1 m or approx. 0.5 m x approx. 1 m. The support frames 15 of these surface modules 1 are designed to be stable so that bending of the individual solar cell arrangements is avoided. The necessary wiring is led out on the underside and laid in the U-shaped central channel in the base part 4 of the longitudinal member 3. It can be seen from the illustration that the longitudinal member 3 has a known guard rail profile and is mounted on guard rail posts 14 which are specially arranged next to one another at a distance of 2 m.

The assembly and the inclined position arrangement are clearly visible in Figure 2. The guard rail post 14 is driven into the ground, e.g. with a lower, 80 cm long section of the base 2. It ends, for example, 1,000 mm above the ground. All other posts 14 arranged in a row are driven into the ground in a correspondingly aligned manner. An angle support 13 is provided on the top, which consists of an upper section that extends over the upper end face of the steel tubular profile of the guard rail post 14. The vertical holding part is screwed to the tube. The base 9 of the support is attached to the upper support arm of the angle support 13.

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pez-shaped base part 4 of the longitudinal member 3, which has a guard rail profile. Laterally projecting cover walls 11 and 12 are attached to the V-shaped upwardly extending side walls 6 and 7 and

.5 on the outside, angled side walls 8 and 9, which are short compared to the walls 6 and 7. The support frame 15 of a surface module 1, e.g. a solar cell or solar collector arrangement, rests on the surfaces of the cover walls 11 and 12 and is screwed in place using the screws 16 shown. Since all parts are made of steel, the holding device is also effectively earthed, so that the solar cells and their frames can be easily connected to earth potential, or are automatically connected to it when screwed on.

Claims (9)

1. Holding device for a plurality of surface modules ( 1 ) of solar collectors and/or solar cell arrangements arranged in a row, which are arranged at a certain angle of inclination (α) and distance (A) from the ground ( 2 ), characterized by at least one longitudinal support ( 3 ) made of steel with a profile of a guard rail for road construction, having a central trapezoidal base part ( 4 ) open at the top, consisting of a continuous base ( 5 ) and adjoining, upwardly extending walls ( 6 , 7 ) which form a longitudinal channel, - wherein the opening width is greater than the width of the floor ( 5 ), and on the other side parts ( 10 ) with an inverted trapezoidal profile ( 6 , 8 ; 7 , 9 ) each consisting of a connecting ceiling wall ( 11 , 12 ) and side walls ( 8 , 9 ) are provided, - wherein the bottom ( 5 ) of the base part ( 4 ) of the longitudinal beam ( 3 ) is fastened to a beam ( 13 ) which is mounted on a hollow and/or profiled post ( 14 ), in particular a guardrail post made of steel, at a certain angle relative to the upper end face of the post ( 14 ) or on a head mounted on a post ( 14 ) with a beam whose angle of inclination is adjustable, and the support frames ( 15 ) of the surface modules ( 1 ) are fastened to the ceiling walls ( 11 , 12 ) of the side parts ( 10 ) so as to rest on them. 2. Holding device according to claim 1, characterized in that the surface modules ( 1 ) have frame-shaped support frames ( 15 ) and the support frames ( 15 ) delimit the individual surface modules ( 1 ). 3. Holding device according to claim 1 or 2, characterized in that the longitudinal support ( 3 ) is arranged approximately centrally to the width or depth of a surface module ( 1 ). 4. Holding device according to claim 1 or 2, characterized in that an angle holder ( 13 ) with an upper support section and a vertical holding section is fastened to each post ( 14 ), and that the bottom of the trapezoidal base part ( 4 ) of the longitudinal support ( 3 ) is fastened to the support section arranged at a certain angle of inclination. 5. Holding device according to claim 1, characterized in that the posts ( 14 ) are guardrail posts of known design, in particular round or profiled steel tubes. 6. Holding device according to claim 1, characterized in that the posts ( 14 ) are driven into the ground and aligned in a row. 7. Holding device according to claim 1, characterized in that the cabling and/or pipes for the surface modules ( 1 ) for connection to associated energy converters are arranged in the trapezoidal base longitudinal part ( 4 ) of the longitudinal member ( 3 ). 8. Holding device according to claim 1, characterized in that the longitudinal member ( 3 ) consists of galvanized embossed sheet steel. 9. Holding device according to one of the preceding claims, characterized in that the connections of the longitudinal beam ( 3 ) to the beam ( 13 ) and/or the beam ( 13 ) to the post ( 14 ) are screw, rivet or welded connections.