DE102010029739B4 - Solar system with several power-generating foil elements - Google Patents

Abstract

A solar system (1) comprises a plurality of power-generating film elements (2) and a fastening system (3) for fastening the film elements (2). The film elements (2) are each held in their edge region (3b) at a plurality of fixing points (5), such that the film elements (2) cantilevered on the fastening system (3) are mounted.

Description

The invention relates to a solar system, comprising a plurality of power-generating foil elements and a fastening system for fastening the foil elements.

Such a solar system is from the DE 20 2004 000 398 U1 known.

The from the DE 20 2004 000 398 U1 become known solar system comprises a flexible solar cell, which is sewn tightly with a backpack cover, wherein the solar cell consists of flexible film material.

The solar cell is connected directly to the backpack lid or the textile part. Thus, the film element must be adapted to the shape of the backpack cover or the shape of the textile part.

Furthermore, it is off DE 20 2008 013 819 U1 is a photovoltaic system with frameless glass-glass solar modules known. There are provided profile support, with which the glass-glass solar modules are connected via point holder. The dot holders are glued to the glass-glass solar modules in their corners. The connection between point holders and profile beams by means of threaded bolts, which engage in holes in the profile carriers. The threaded bolts are movably mounted in the profile carriers by means of discs and a spacer sleeve. This movable storage serves to compensate for moments of displacement caused by deformations of the glass-glass solar modules due to wind and temperature changes, and to compensate for angular errors of the profile beam, thus ensuring a stress-free mounting of the glass-glass solar modules.

Out WO 2010/11 649 A1 Photovoltaic modules have become known, which are mounted on a strained membrane. The membrane is tensioned, but not the photovoltaic modules mounted on the membrane.

Object of the invention

It is the object of the present invention to provide a solar system in which the power-generating film elements are formed independently of the shape of a base support.

Brief description of the invention

This object is achieved by a solar system according to claim 1.

According to the invention, the film elements are each held in their edge region at a plurality of fixing points, such that the film elements are cantilevered mounted on the fastening system. The foil elements are exclusively connected to the fastening system. The film elements are flexible, in particular flexible, executed. Thus, the cantilevered mounting of the flexible film elements allows an independent of the shape of a base support arrangement of the film elements. For example, the foil elements no longer have to be adapted to rough surfaces of the base carrier. The film elements can be translucent, for example, d. H. partially translucent, or transparent, d. H. completely translucent, be formed.

In the solar system according to the invention, the film elements are held by the fastening system under tension. This increases their stability to external influences. For example, film elements under tension are less prone to wind or rain outdoors.

Preferred embodiments of the invention

In one embodiment of the invention, at least a part of the film elements is held in a curved state. The amount of power generation of the film elements is u. a. depending on the angle of incidence of the sun. Since the sunrays at different angles fall on the film elements during the course of the day, different arrangements of film elements can lead to a constant power generation seen over the day. In addition, curvable surfaces form creative freedom in the design of solar systems.

Particularly preferred is an embodiment in which the fastening system comprises a cable construction. A rope construction can assume a wide variety of geometric shapes, which solar systems can be realized in a variety of geometric arrangements.

A further development of the embodiment just described is characterized in that the cable construction comprises carrier cables and connecting elements, and that the connecting elements connect the carrier cables to the film elements, wherein the connecting elements act on the fixing points of the film elements. The rope construction consists of crossing carrier cables, which are made of fibers or metal, for example. Thus, the cable construction forms frames that surround the foil elements. By means of the connecting elements connections between the film elements and the cable construction are made at previously defined fixing points.

In a further development of the development just described, the connecting elements are elastic, in particular rubber-elastic or viscoelastic or resilient. Elastic connecting elements can transmit tensile stresses to the foil elements and compensate for forces acting on the foil elements. In addition, the fasteners deform elastically from a certain load and thus prevent damage to the film elements.

A development of the embodiment described above is characterized in that power lines are integrated into the cable construction, in particular conductor strands extend at least partially in the interior of carrier cables. Thus, the power cables do not have to be laid separately from the rope construction. This reduces the wiring effort and saves space.

An embodiment is preferred in which the fastening system comprises spacers for stationary attachment to a base support. Thus, the film elements are spaced from the base support. Rough or arbitrary surfaces can thus be covered, for example, without prior adaptation of the film elements.

In a development of the embodiment just described, the spacers have at least partially different spacing lengths. The arrangement of the film elements can thus be chosen independently of the surface shape of the base carrier. If the surface shape of the base support is flat, the film elements can describe, for example, curved surfaces. Plane film arrangements with a curved surface of the base support are also possible.

In a further development of the embodiment described above, the film elements are attached directly to the spacers, in particular the film elements are kept clamped. This type of attachment is cost effective. In addition, a fast and structurally simple fastening and rapid disassembly of the film elements are made possible.

In a further embodiment, a plurality of foil elements are electrically connected in series or in parallel. Thus, either an addition of the voltage dropping across the power generating foil elements or an addition of the currents can take place.

A preferred embodiment is characterized in that the fixing points are designed as eyelets, pockets, hook-and-loop fasteners, press studs, bayonet fasteners, etc. The fixing points can be individually tailored to the requirements of the fastening system. In the case of a cable construction, it can be advantageous, for example, to design the connecting elements as rubber-elastic cables which are guided through eyelets which are provided at the fixing points of the film elements. If the foil elements are fastened directly to the spacers, for example pushbuttons or latching connections can represent an advantageous method of attachment.

The invention is also realized in a use of a solar system as described above, wherein the fastening system is arranged on a building structure, in particular building facade, such that the film elements are spaced from the building structure. Building facades offer large areas that can be used as a basic support for large-scale high-performance solar systems. By having the film elements spaced from the base support, the film elements can be arranged in any geometric shapes independent of the surface of the base support.

Also advantageous is a use of the solar system described above, wherein the fastening system is self-supporting. Thus, the fastening system is connected at individual defined locations with the base support, whereby a simple disassembly of the film elements is possible. "Self-supporting" is to be understood as a dimensionally stable fastening system.

It is understood that the power generating films can be connected directly via clamping bolts with brackets (direct) and / or with tension cables. The clamping bolts are held on the one hand in through bolts, which are anchored to the fixing points of the film elements. The clamping bolts are fastened at one end to the holder and at the other end they have a thread in one end region, which allows an adjustable screw connection of the clamping bolt with the through bolt. About such a fork / eye principle, the films can be stretched as desired. On flat surfaces, foils can also be clamped flat using this stress principle. The foils then run parallel and spaced, z. B. to a housing wall to which they are attached via brackets and / or tension cables.

Further advantages of the invention will become apparent from the description and the drawings. Likewise, the above-mentioned and still further features according to the invention can be used individually for themselves or for several in any combination. The embodiments shown and used are not meant to be exhaustive, but rather to be exhaustive rather have exemplary character for the description of the invention.

Drawings and detailed description of the invention

The invention is illustrated in the drawings and will be explained in more detail with reference to embodiments. It shows:

1 a portion of a solar system according to the invention in plan view;

2 a portion of a solar system according to the invention in a perspective view;

3 two embodiments of connecting elements between a cable construction and a foil element in a perspective view;

4 a further embodiment of fixing points and the connection between a rope construction and a foil element in a perspective view;

5 a further embodiment of a spacer in a perspective view, and

6 a formed with foil elements curved surface in a perspective view.

Identical components are given the same reference numerals in the figures.

In 1 is a subarea of a solar system according to the invention 1 shown.

Such solar systems 1 For example, they are attached to building facades over a large area and include foil elements 2 that have a fastening system 3 with a base support (not shown) are connected.

The electricity generating foil elements 2 include solar cells 3a by means of which solar energy is converted into electrical energy and are made with a film material consisting of peripheral edge 3b surround. The foil elements 2 are flexible and in particular bendable and known in the art. The solar system 1 Can work with any kind of electricity generating foil elements 2 be used. Also conceivable is the use of cross-surface translucent and / or transparent power-generating film elements 2 with the solar system according to the invention 1 ,

The fastening system 3 has fasteners 4 on, about each foil element 2 as eyelets 5 trained fixation with a rope construction 6 and moreover with the adjacent foil element 2 connected is. The eyelets 5 are along the perimeter 3b of the film element 2 arranged. The rope construction 6 consists of carrier cables 7 and is about spacers 8th connected to the base support (not shown). The carrier cables 7 may consist of fibers or metal and are preferably arranged at a 90 ° angle to each other. They form rectangular frames with which the foil elements 2 are connected. There are also other angles between the carrier cables 7 conceivable.

The spacers 8th are located at junctions 9 on which are the carrier cables 7 cross. By means of the spacers 8th becomes the rope construction 6 and thus also the foil elements 2 from the base support, such as floor, façade surfaces, roofs, etc. (not shown).

Through the fastening system 3 become the foil elements 2 held under tension.

According to 2 is a spacer 8th at least partially as a cylinder 10 formed, which has on its side facing away from the base carrier through holes through which the carrier cables 7 are guided. The through-holes are preferably arranged at right angles to each other and along the longitudinal direction of the spacer 8th offset formed. The spacer 8th is attached to the body by means of known connection means.

The connecting elements 4 include a first rope 11 on the side of the rope construction facing the base beam 6 the carrier rope 7 encloses and a second rope 12 on the side of the rope construction facing away from the base carrier 6 encloses the carrier rope. Both ropes 11 . 12 are interconnected by known connecting mechanisms, with the resulting connecting element 4 through the eyelets 5 the foil elements 2 is guided. The connection of the two ropes 11 . 12 can be done for example by push buttons (not shown).

The two ropes 11 . 12 can also be designed as a one-piece rope, which is the carrier rope 7 surrounds several times and through the eyelets 5 is guided. The ends of the one-piece rope are interconnected by known linkage mechanisms.

3 shows a second and a third embodiment of a connecting element 4 ,

In the second embodiment, the connecting element 4a from a wide belt 13 that at its ends 14 is rounded. The belt 13 surrounds the carrier rope 7 and is at its ends with the film element 2 connected to the eyelets. The eyelets are through the belt 13 covered. The connection of the ends 14 of the belt 13 can be done for example by push buttons, hook and loop fasteners or similar known connection mechanisms.

In the third embodiment, the connecting element 4b as elastic rubber ring 15 formed, which is the carrier rope 7 embraces. The rubber ring 15 is arranged such that it on the side facing the base carrier and the base carrier side facing away from the film element 2 forms semicircular areas in which push buttons 16 are provided. At the snaps 16 is a recording 17 for the rubber ring 15 educated. The push buttons 16 are connected with each other, the size of the rubber ring 15 is chosen so that he with connected snaps 16 is under tension, so he is not out of the pictures 17 the push buttons 16 can solve.

According to 4 is in another embodiment of the fixation 5a the edge 3b of the film element 2 turned over in the direction of the base carrier and on the film element 2 fixed so that a loop 18 is trained. Through the loop 18 runs a rope or a cable 19 For example, a power line through the solar cells 3a ( 1 ) won electricity leads. Along the rope 19 has the foil element 2 bulges 20 on where the rope is 19 exposed.

The fixation points 5a are in this embodiment as bulges 20 trained in which the rope 19 runs. In the bulges 20 becomes the rope 19 by a further embodiment of a connecting element 4c with the carrier rope 7 connected. The connecting elements 4c are as elastic bands 21 executed, whose ends are each connected to connection mechanisms (not shown).

5 shows a further embodiment of a spacer 8a that has an at least partially cylindrical foot 10 having. The spacer 8a is connected by connecting means with the base body (not shown) and has on the side facing away from the base body a plurality of arms 22 on, which are formed as tubes. In these arms 22 become fasteners 23 introduced at the the spacer 8a opposite side a thickening 24 and in the direction of the arms 22 locking elements 25 exhibit. On the inside of the arms 22 are counterparts to the locking elements 25 (not shown) provided with which the locking elements 22 latch, leaving a positive connection between spacers 8a and fastener 23 arises.

The following is the use of the spacer 8a briefly explained:
A fastener 23 For example, by an eyelet of a film element ( 1 ), the thickening 24 larger than the eyelet is formed. As a result, the fastener engages behind 23 the foil element 2 , The locking elements 25 then be in your arms 22 of the spacer 8a pushed in and thus the film element 2 with the spacer 8a directly connected. Depending on the desired tension of the film element 2 can the locking elements 25 into your arms 22 be inserted.

6 shows a further embodiment of a solar system 1a with foil elements that have a curved surface 26 form. The foil elements 2 are about the attachment system 3 connected with each other. At the edge 27 is the attachment system 3 connected to a base body (not shown). Over the entire area 26 are the foil elements 2 the solar system 1a cantilevered.

A solar system 1 includes several power generating foil elements 2 and a fastening system 3 for fixing the foil elements 2 ,

The foil elements 2 are each in their peripheral area 3b at several fixing points 5 held, such that the film elements 2 self-supporting on the fastening system 3 are stored.

Claims (13)

Solar system comprising a plurality of power-generating film elements ( 2 ) and a fastening system ( 3 ) for fixing the foil elements ( 2 ), characterized in that the film elements ( 2 ) in each case in their edge region ( 3b ) at several fixing points ( 5 . 5a ) are held such that the foil elements ( 2 ) self-supporting on the fastening system ( 3 ) and that the film elements ( 2 ) through the fastening system ( 3 ) are held under tension. Solar installation according to claim 1, characterized in that at least a part of the foil elements ( 2 ) are held in a curved state. Solar installation according to one of the preceding claims, characterized in that the fastening system ( 3 ) a rope construction ( 6 ). Solar installation according to claim 3, characterized in that the cable construction ( 6 ) Carrier cables ( 7 ) and connecting elements ( 4 . 4a . 4b . 4c ), and that the connecting elements ( 4 . 4a . 4b . 4c ) the carrier cables ( 7 ) with the foil elements ( 2 ), the connecting elements ( 4 . 4a . 4b . 4c ) at the fixation sites ( 5 . 5a ) attack the film elements. Solar installation according to claim 4, characterized in that the connecting elements ( 4 . 4a . 4b . 4c ) are elastic, in particular rubber-elastic or viscoelastic or elastic, are formed. Solar installation according to one of claims 3 to 5, characterized in that power lines in the cable construction ( 6 ) are integrated, in particular conductor strands at least partially in the interior of carrier cables ( 7 ). Solar installation according to one of the preceding claims, characterized in that the fastening system ( 3 ) Spacers ( 8th . 8a ) for fixed attachment to a base support. Solar installation according to claim 7, characterized in that the spacers ( 8th . 8a ) have at least partially different pitch lengths. Solar installation according to one of claims 7 or 8, characterized in that the film elements ( 2 ) directly on the spacers ( 8th . 8a ) are fastened, in particular clamped. Solar installation according to one of the preceding claims, characterized in that a plurality of foil elements ( 2 ) are electrically connected in series or in parallel. Solar installation according to one of claims 1 to 10, characterized in that the fixing points as eyelets ( 5 ), Pockets, hook-and-loop fasteners, press studs, bayonet locks, etc. are formed. Use of a solar system according to one of claims 1 to 11, wherein the fastening system ( 3 ) is arranged on a building structure, in particular building facade, such that the film elements ( 2 ) are spaced from the building structure. Use of a solar system according to one of claims 1 to 11, wherein the fastening system ( 3 ) is self-supporting trained.

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