EP4055707A1

EP4055707A1 - Solar assembly for generating solar power

Info

Publication number: EP4055707A1
Application number: EP20803490.0A
Authority: EP
Inventors: Marcel Stöber
Original assignee: Goldbeck Solar GmbH
Current assignee: Goldbeck Solar GmbH
Priority date: 2019-11-05
Filing date: 2020-11-05
Publication date: 2022-09-14
Also published as: DE102019129733A1; WO2021089679A1

Abstract

The invention relates to a solar assembly for generating solar power, comprising at least three solar modules (8) which have a mounting frame (4) and solar cells (6), at least two base elements (12), connection elements (14) for interconnecting the mounting frames (4), and support elements (16) for connecting the mounting frames (4) to one of the base elements (12), wherein each of the mounting frames (4) has two first lateral edges (18) running parallel to the base elements (12) and at least two additional second lateral edges (20), each of the connection elements (14) connects two respective first lateral edges (18) of at least two pairs of mounting frames (4) together at a specified angle of less than 180°, and at least three mounting frames (14) are connected together along the first lateral edges (18) and form a curved solar module section (22). The invention solves the technical problem of providing a solar assembly for generating solar power with an improved use of the surface area of the underlying surface.

Description

Solar system for generating solar power

The invention relates to a solar system for generating solar power with a plurality of solar modules having a holding frame and solar cells.

As is known, solar systems are set up on the roof of a house or on an open area. A row-wise arrangement of the solar modules is known, in particular on open spaces, the solar modules being oriented largely to the south at an angle that is as favorable as possible in order to subject the solar modules to as much solar radiation as possible.

Likewise, solar systems used mainly in southern countries are known in which the solar modules are aligned as well as possible with the sun during a day by means of a movable and controlled supporting structure. The technical effort is greater here, but the power yield is maximum due to the optimal alignment of the solar modules throughout the day.

Furthermore, an arrangement of solar modules is known which has a supporting structure in the form of a pointed roof, the solar modules being arranged with an orientation on the one hand to the west and on the other hand to the east. As a result, the individual solar modules are not used optimally due to the lack of south orientation, but the combination of west and east orientation results in a higher power yield per unit area of the subsurface.

In all the solar systems mentioned, the individual solar modules are carried by a supporting structure which is formed from a self-supporting rod, so that the solar modules only have to be placed and fixed on the supporting structure. The area arranged under the solar modules is acted upon by the supporting structure through individual supports in such a way that the area can no longer be used.

One known solution is that the supporting structure is built so high that the areas between the individual supports under the solar modules can be walked on and driven over and thus cultivated. However, the technical effort involved is considerable.

The present invention is therefore based on the technical problem of specifying a solar system for generating solar power with an improved use of the surface area.

The aforementioned technical problem is solved according to the invention by a solar system with at least three solar modules having a holding frame and solar cells, preferably with a plurality of solar modules, with at least two base elements, with connecting elements for connecting the holding frames to one another and with support elements for connecting the holding frame to one of the Base elements, the holding frames each having two first side edges running parallel to the base elements and at least two further second side edges, the connecting elements each connecting two first side edges of at least two pairs of holding frames to one another at a predetermined angle of less than 180 ° and at least three Holding frames are connected to one another along the first side edges and form a curved solar module section.

According to the invention, the solar modules are built up in sections to form a self-supporting structure, so that no further supports are required between the two external solar modules. The construction therefore resembles a classic archway or window arch construction made of stones. Thus can already a curved solar module section can be formed with three solar modules. The individual solar module sections preferably have six to ten, in particular eight solar modules, so that on the one hand the span is greater than with three modules and the angles between the individual solar modules are greater and closer to 180 °. In the case of a solar module section with six to 10 solar modules, there is a larger chip width and larger angles between the holding frames.

The angle between the holding frame or the solar modules depends on the number of solar modules used. In the case of a solar module section with only three solar modules, the angle is preferably approximately 130 ° to 150 °. In the case of solar module sections with 6 to 10 solar modules, the angle is preferably between 160 ° and 185 °.

The solar module sections can span a distance of five to ten meters in a vault-like manner. The height of the solar module sections can be in the range from 1 to 3.5 meters, preferably 2 meters. The limits are not fundamentally limited, but rather by the stability of the individual solar modules and their connections.

The outer solar modules, which are connected on a first side edge to the support elements on the base elements, are preferably aligned in such a way that the central plane of the solar module runs in the direction of the base element. In this way, a favorable introduction of force to the base element is achieved.

A solar module is understood to be a known solar module in which a plurality of solar cells are arranged in an outer holding frame. The solar cells can be monofacial and convert sunlight into electrical energy from only one side. The solar cells can, however, also have a bifacial design and convert light incident from both sides of the solar module into electrical energy. Sunlight that passes through the solar module can thus also be used to generate electricity after being reflected on the ground. The shape of the solar modules is usually rectangular and has two long first side edges and two short second side edges. In contrast, the solar modules can also have a different shape, but in the present case the formation of parallel first side edges is necessary.

For example, the solar modules can also have two short first side edges and two long second side edges, or the solar modules can be square with first side edges and second side edges of the same length. The invention is described below with the preferred embodiment with two long first side edges and two short second side edges.

The solar modules are electrically or electronically connected to one another in a known manner and the power generated is transmitted to a transformer station in a conventional manner and with known means, without this being important in the construction of the solar systems.

The basic elements described are usually designed to be connected to a substrate. As a result, good stability is achieved, especially when the subsurface is not paved, for example if it is an open field. In contrast, the base elements can also be arranged on a solid base, in which case no fixing to the base is required, and a construction that can be moved on the base is even possible.

The connecting elements are designed as profile frames made of metal, in particular aluminum or an aluminum alloy, or hard plastic. The connecting elements can therefore be produced and made available in large quantities at low cost.

The self-supporting construction of the interconnected solar modules is a vault-like structure. Therefore, the solar system described spans a free one Area without significantly restricting its use. One possible application is a free field, the surface of which can be ordered with an existing solar system. Although the solar system provides shade, plants that thrive in the shade can be grown and harvested. The solar system described can also be set up on a paved surface, for example in urban areas such as squares, platforms or parks. As long as the solar radiation is not significantly restricted, the solar systems described can shade areas and make them more usable for people on sunny days or even on rainy days. For this purpose, the base elements can also be fastened on stilts in order to increase the height of the spanned space. Furthermore, the solar system described can be used as an underlay device such as a shed or a carport.

The connecting elements preferably connect the holding frames of at least some of the solar modules to one another at the same angles along the row of holding frames. This results in a symmetrical structure that ensures increased stability. It is possible, in particular in the edge area, to arrange the solar modules in a planar manner, that is to say at an angle of approximately 180 °. This allows a greater height of the vault to be achieved.

Furthermore, it is advantageous if the connecting elements are designed like rails and have a length not greater than the length of the first side edges. In this way, the first side edges of adjacent solar modules can possibly even be connected to one another along the entire length.

In contrast, it is less complex to design the connecting elements as individual fastening elements. The assembly can thereby be simplified.

In a further preferred embodiment of the system described, at least two solar module sections are connected to one another at least in sections along second sides of holding frames, preferably only at the corners of holding frame. This creates a curved roof that can be extended to a long roof similar to a greenhouse by using a large number of solar module sections. If not only the first side edges but also the second side edges are connected to one another, for example by means of rail-shaped connecting elements, a construction that is largely closed at the top can be achieved, which reduces or even prevents the ingress of air and moisture.

The length of such a construction of a multiplicity of solar module sections in the direction of the second side edges is in principle not restricted and depends on the length of the subsurface. Thus, for example, lengths of over 100 meters or even 500 meters or more are possible.

A further advantageous embodiment of the described arrangement consists in that the support elements are designed to be displaceable with respect to the base elements. For example, a construction can be selected in which the support elements are displaceable with respect to the base elements, that is to say can slide or roll. Thus, for example, a subsurface can only be partially shaded by the solar system, while another part remains free. By regularly moving the solar system in relation to the subsurface, an averaged lower shadowing of the subsurface can be achieved.

The base elements are preferably designed as pipes, in particular as concrete pipes. Other alternatives, such as concrete foundations or steel profiles or sheets rammed into the ground, can also be used, depending on the nature of the ground. Conventional building materials can thus be used economically. The attachment of the support elements to the pipes or alternative foundations can then be carried out on site. It is further preferred that the base elements are suitable for carrying two support elements of two different solar module sections in a longitudinal position. This further reduces the cost of materials for the solar system. In a further embodiment of the solar system, the connecting elements, the support elements and / or the base elements can take on further functions, such as those required in agriculture, for example.

The connecting elements and / or the support elements can be provided with water pipes and water distribution systems in order to irrigate the space below the arched arrangement of the solar modules and, if necessary, to supply other substances such as fertilizers or plant or insect repellants. Alternatively or in addition, lighting means can also be provided. The base elements can, for example, also be provided with rails on which movable and possibly automated processing devices for sowing, caring for and harvesting the plants grown underneath the solar system can be guided.

The connecting elements, the support elements and / or the base elements can also have channels and openings for ventilation of the space below the arched solar systems.

In the following, the invention is explained on the basis of exemplary embodiments with reference to the drawing

1 shows an embodiment of a solar system according to the invention with a solar module section with three solar modules in cross section,

Fig. 2 shows the embodiment shown in Fig. 1 in a perspective

View,

3 shows an embodiment of a connecting element,

4 shows a further exemplary embodiment with three solar systems, each with several solar module sections, each with eight solar modules, FIG. 5 shows the solar system from FIG. 4 with a displaceable connection of the

Solar systems with the basic elements,

6 shows a further exemplary embodiment of a plurality of solar systems in a view from above,

7 shows a base element in cross section,

Fig. 8 shows a further embodiment of a connecting element in

Cross-section,

9 shows the connecting element shown in FIG. 8 in a perspective view

View and

10 shows a further exemplary embodiment of a solar system with an alternative connecting element. In the following description of the various exemplary embodiments according to the invention, components and elements with the same function and the same mode of operation are provided with the same reference numerals, even if the components and elements in the various exemplary embodiments may differ in their dimensions or shape.

1 and 2 show a first embodiment of a solar system 2 for generating solar power with three solar modules 8 having a holding frame 4 and solar cells 6. Two laterally arranged base elements 12 connected to the substrate 10 serve to support the arrangement of the solar modules. The holding frames 4 are connected to one another with connecting elements 14, and support elements 16 each connect the holding frames 4 to one of the base elements 12. As FIG. 2 shows, the holding frames 4 each have two first side edges 18 running parallel to the base elements 12 and at least two further second side edges 20; the solar modules 8 are thus rectangular with two long first side edges 18 and two short second side edges 20 educated.

The connecting elements 14 connect two first side edges 18 of at least two pairs of holding frames 4 to one another at a predetermined angle a of less than 180 °, so that three holding frames 4 are connected to one another along the first side edges 18 and form a curved solar module section 22.

3 shows a previously described connecting element 14 in cross section, which has two receptacles 24 for receiving holding frames 4, which are laterally bounded by cheeks 26. Fastening means, not shown in detail, serve to hold and fix the holding frame 4 in the receptacle 24. It has been found to be advantageous that the connecting elements 14 connect the holding frames 4 of at least some of the solar modules 8 to one another at the same angles along the row of holding frames 4. This results in a uniformly curved solar module section 22, as shown in FIGS. 1 and 2.

Furthermore, the connecting elements 14 are designed like rails and have a length not greater than the length of the first side edges 18 of the holding frame 4. Thus, the holding frames 4 are possibly even completely enclosed along the entire side edges 18 and securely fixed.

1 and 2 show a solar module section 22 with only one row of solar modules 8 assembled together to form a vault make longer arched roof. Fig. 4 also shows the three side by side arranged solar systems 2 each with eight solar module sections 22, which in turn each have eight solar modules 8.

FIG. 5 shows a further embodiment of the solar systems 2 according to FIG. 4, in that the support elements 16 are designed to be displaceable with respect to the base elements 12. The solar systems 2 can thus be moved to and fro along the double arrows shown in order to achieve a variable covering of the subsurface 10.

The mobility can be achieved by means of skids or rollers.

The figures also show that the base elements 12 are designed as concrete pipes which are suitable for supporting two support elements 16 of two different solar module sections 22 in a longitudinal position.

6 shows a further exemplary embodiment with a plurality of solar systems 2, each with eight solar modules 8, which are connected to one another at their first longer side edges 18 and form a vault-like arch as a solar module section 22. In contrast to the exemplary embodiment according to FIGS. 4 and 5, the second side edges of the holding frames of the solar modules are not connected to adjacent holding frames, so that each solar module section 22 forms a solar module 2 by itself.

Also shown in FIG. 6 are the base elements 12, which are each formed from a plurality of parts in the form of concrete pipe sections 30. Such a concrete pipe section 30 is shown in cross section in FIG. The concrete pipe sections 30 have support elements 16 in pairs on opposite upper outer sections in the form of a running rail 32 bent at right angles and an associated running element 34, which is placed on the protruding end of the running rail 32 with a running wheel 36. Thus, the support element 16 is designed as a two-part support element that can be rolled against one another, so that the solar module sections 22 are designed to be individually rollable and thus displaceable against one another. 8 and 9 show a further embodiment of a connecting element 14 in the form of a profile. The profile has a base 40 with a bottom 42 and two top sides 44 which are aligned at an angle of less than 180 ° to one another. A central section 46 extends upwards from the base 40, the two side walls 48 of the central section 46 each being aligned essentially perpendicular to the two upper sides 44 and thus forming an angle between one another. The middle section 46 has an upwardly directed opening 50 into which a clamping element 52 can be inserted.

During the assembly of a solar module 2, a connecting element 14 according to FIGS. 8 and 9 is arranged between the first side edges 18 of two solar modules 8, which rest on the upper sides 44 of the base 40 and rest against the side walls 48 of the central section 46. Due to the vault-like structure, the holding frames 4 are pressed against the connecting elements 14 due to the force of gravity and form a stable solar module section 22.

FIG. 10 shows a further exemplary embodiment of a solar system with an alternative connecting element 14 which is screwed laterally onto the holding frame 4. The connecting element 14 is therefore not arranged between the first side edges 18, but is screwed laterally onto the second side edges 20. The connecting element 14 described here can be used as an alternative or in addition to the connecting elements described above. In the embodiment shown in FIG. 10, the connecting elements 14 each connect two first side edges 18 of at least two pairs of holding frames 4 to one another at a predetermined angle of less than 180 °, even if in FIG. 10 the connecting element is laterally on the second side edges 20 is attached.

Claims

Patent claims

1. Solar system for generating solar power, with at least three solar modules (8) having a holding frame (4) and solar cells (6), with at least two base elements (12), with connecting elements (14) for connecting the holding frame (4) to one another and to Support elements (16) for connecting the holding frame (4) to one of the base elements (12), the holding frames (4) each having two first side edges (18) running parallel to the base elements (12) and at least two further second side edges (20) , wherein the connecting elements (14) each connect two first side edges (18) of at least two pairs of holding frames (4) with one another at a predetermined angle of less than 180 ° and wherein at least three holding frames (14) along the first side edges (18) with one another are connected and form a curved solar module section (22).

2. Solar system according to claim 1, characterized in that the connecting elements (14) connect the holding frames (4) of at least some of the solar modules (8) to one another at the same angles along the row of holding frames (4).

3. Solar system according to claim 1 or 2, characterized in that the connecting elements (14) are rail-like and have a length not greater than the length of the first side edges (18).

4. Solar system according to one of claims 1 to 3, characterized in that at least two solar module sections (22) are connected to one another at least in sections along second sides of the holding frame (4).

5. Solar system according to one of claims 1 to 4, characterized in that the support elements (16) are designed to be displaceable relative to the base elements (12).

6. Solar system according to one of claims 1 to 5, characterized in that the base elements (12) are designed as pipes, in particular concrete pipes.

7. Solar system according to one of claims 1 to 6, characterized in that the base elements (12) are suitable to carry two support elements (16) of two different solar module sections (22) in a longitudinal position.