WO2018218263A1 - Device for generating electrical energy from sunlight - Google Patents

Abstract

The invention relates to a device (1) for generating electrical energy from sunlight, comprising at least two solar cells (2). In order to achieve a device (1) for supplying energy that can be simply and reversibly set up, according to the invention, the solar cells (2) are movably connected such that the solar cells (2) can be brought into a working position, in which the solar cells (2) are positioned parallel next to each other for simultaneous irradiation with sunlight, and into a transport position, in which the solar cells (2) are arranged at an angle to each other or one over the other to enable compact transporting.

Description

 Device for generating electrical energy from sunlight

The invention relates to a device for generating electrical energy

Sunlight with at least two solar cells.

Various devices for generating electrical energy from sunlight have become known from the prior art. Such devices are

Usually stationary, for example, on rooftops, used to generate electrical energy. A disadvantage of devices of the prior art is that a cost for commissioning the same is high and requires expertise.

This is where the invention starts. The object of the invention is to provide a device of the type mentioned, which can be taken in a simple manner in a short time and without special expertise in operation.

According to the invention this object is achieved by a device of the type mentioned, in which the solar cells are movably connected, so that the solar cells can be brought into a working position in which the solar cells are positioned parallel to each other for simultaneous irradiation with sunlight, and in a transport position, in which the solar cells are compactly transportable at an angle to each other or one above the other.

In the context of the invention it was recognized that a commissioning of a

corresponding device which has been transported to any location, is possible in a simple manner when the solar cells are movably connected so that they can be easily brought from a transport position to a corresponding working position in which the solar cells are arranged over a large area to generate electrical energy , In the context, it should be understood next to one another that the solar cells are not arranged one behind the other in the direction of the sun's rays. Preferably, the solar cells are arranged in the working position in a single plane. Alternatively, the solar cells may be arranged in different planes, which are aligned parallel and preferably perpendicular to an irradiation direction. Basically, there are various possibilities, the solar cells movable, in particular foldable, form interconnected, so that they can be brought into both the working position and in the transport position. For example, all the solar cells may be part of a flexible film which is rolled up or folded to bring it from a cocked position or the working position in a transport position with a small volume. In the transport position is usually an imaginary, all solar cells enveloping surface smaller than in the working position, that the solar cells can be transported in the transport position in a simple manner, for example in a truck or the like. The solar cells can be used in the

Transport position parallel or anti-parallel one above the other and be arranged under a Wnkel each other to be compactly transportable.

To achieve a particularly robust construction, it is advantageous if at least two solar modules are provided with solar cells, wherein the solar modules are movable relative to each other, in particular foldable, connected to each other. In contrast to a flexible film, in which all the solar cells are arranged, high robustness is achieved with a usually inherently rigid or rigid solar module, so that the device can also be used, for example, for decentralized energy supply in development areas.

It is advantageous if a body rotatably mounted relative to a substrate about an axis is provided, which is connected to the solar cells in such a way that the

Solar cells during rotation of the body in a first direction can be wound on the body and unwound in rotation of the body in a second direction. The in the

Solar modules arranged solar cells can then be brought by simple rotation of the body in a simple manner from the transport position to the working position. As a result, a commissioning of the device is also possible by completely untrained personnel in a particularly simple and reliable manner. In order to achieve a low weight of the device, the body can only consist of a frame, which is formed for example of steel profiles.

A high packing density of the solar cells in the transport position with at the same time simple possibility to put the plant into operation, is achieved, if the body in a cross-section as a polygon, preferably as a regular polygon, in particular as a square, is formed. In addition, the device can then be produced particularly easily, for example, corresponding profiles of the same length are welded to a correspondingly rotatable body. As a rule, the body is formed along an axis or a rotation axis with a length which corresponds at least to twice a diameter at the cross section. When

Cross-section is understood to mean a surface or a sectional surface of the body in a plane arranged perpendicular to the axis. It is favorable that the solar cells are arranged in a plurality of solar modules which are movably connected to each other, wherein a side length of the polygon corresponds to a length of a side edge of a solar module. This is when winding the

Solar modules given a defined position of the solar modules on the body, thereby reducing opportunities for mistakes during winding and unwinding.

It is advantageous if the solar modules are connected along a longitudinal direction via a cable, wherein the cable is connected to the body in such a way that the cable together with the solar modules can be wound up on the body. It thus results in a chain

Solar modules, which are connected by cables, usually steel cables. Through a given flexibility over the ropes, the chain on a simple and at the same time robust on the body up or unwound. In general, two ropes are provided along a chain of solar modules, which are arranged approximately parallel and connect all the solar modules. Usually, the solar modules are connected via steel profiles, in which the ropes are guided, with the ropes. An electrical connection of the individual solar modules or the individual solar cells can also be done via the ropes.

Of course, multiple chains of solar modules can be arranged side by side on a body or unwound to be able to generate a producible electrical energy

maximize.

It is advantageously provided that the solar modules have identical dimensions and a distance between the solar modules is in each case dimensioned such that the solar modules are essentially congruently positioned one above the other when wound on the body. As a result, on the one hand, a high degree of uniformity is achieved in the solar modules, so that the device can be produced with low production costs. On the other hand, a corresponding positioning ensures that the solar modules lie flat against one another, as a result of which a high packing density is achieved. It is understood here that the solar modules are arranged with increasing distance from the body usually with increasing distance on the rope, since when winding arranged on the rope

Solar modules a diameter of the body including the already located on it

Solar modules steadily increasing. Usually, solar modules with a thickness of only a few millimeters, preferably less than 20 mm, in particular less than 10 mm, preferably about 6 mm, used to allow for a large area to produce energy compact transport.

Furthermore, a compact arrangement of the solar modules in the transport position can be achieved when focal points of the solar modules when wound on the body in

Essentially positioned one above the other.

In order to transport the device in a simple manner, it is advantageous if a housing is provided in which all solar modules can be positioned when the solar modules are in the transport position. A surface of the housing essentially corresponds to a surface enveloping the solar modules in the transport position. Furthermore, a device for transformation or reversal direction and / or storage of electrical energy generated by the solar cells can be provided in the housing. The device together with the housing can then be positioned in a simple manner at any desired location in order to provide electrical energy in a defined or standardized voltage amplitude and frequency after simple startup of the device.

It is advantageous in this context if the housing is parallelepiped-shaped, in particular as a container. Advantageously, the housing as

trained standardized container, which is set up, for example, for a transport of objects with ships.

A mechanically stable construction of the housing results when the housing has an activation flap and the solar cells with opening of the activation flap of the transport position can be brought into the working position. In general, this is a single side surface of a cuboid obviously designed so that the activation flap, which may also be divided into two, preferably by a movable wall of the cuboid container is formed. For this purpose, one wall of the container can be divided, for example, and arranged pivotably on both sides on the other walls of the container. A stability of the usually trained as a container

Housing is then reached over the five non-revealed and rigidly connected surfaces or side walls of the cuboid, which is usually designed as a steel construction.

In principle, the solar cells can be easily placed in the working position, for example on a floor, usually after they have been folded out and / or rolled out of the transport position. In order to be able to carry out a commissioning of the device independently of a substrate and at the same time to achieve a parallel alignment of the solar cells for optimum efficiency, it is advantageous if a, in particular separable, clamping device is provided, with which the solar cells can be clamped in the working position , A contact of the

Solar cells with a bottom are thus not required, so that a risk is avoided, the solar cells to pollute, which would affect the efficiency. The solar cells can thus be clamped, for example, between a clamping device and a housing, in which housing the solar cells can be transported. For this purpose, the clamping device can be rigidly connected to a substrate, for example, separately from the housing. However, the clamping device may also have a clamping spar, via which a clamping point is rigidly connected to the housing, wherein the solar modules are clamped between the clamping point and the housing. Usually, the clamping spar is formed from a plurality of modular connectable carriers, so that the clamping spar can be disassembled and disposed in the disassembled state in the housing and transported together with the other components of the device. The clamping point at which preferably the solar modules supporting cables are fastened, which are connected at a second end with the body rotatably mounted in the housing, may also be formed as a carrier and transported in the transport position of the device together with the other components of the device. The carriers can, for example trusses be how they are used for example in a stage construction, especially trusses.

To be able to transport the clamping device in a simple manner together with the solar cells, it is advantageous if the clamping device in a housing with the

Solar modules is transportable when the solar modules are in the transport position. This is achieved in a simple manner when the clamping device and a clamping point usually having clamping device is formed from carriers, which are in particular similar, preferably designed as truss trusses.

Further features, advantages and effects of the inventions will become apparent from the embodiment illustrated below. In the drawings, to which reference is made: FIG. 1 and 2 show a device according to the invention in different views;

Fig. 3 shows a detail of a device according to the invention.

Figs. 1 and 2 show a device 1 according to the invention in different views in the working position. As shown in the device 1, a plurality of solar modules 3 are arranged on ropes 10 movable relative to one another. In the solar modules 3 are

Solar cells 2 for generating electrical energy from sunlight positioned, which are arranged in the working position approximately parallel side by side.

Through the connection of the solar modules 3 via cables 10, a flexible connection is provided, so that the solar modules 3 can be brought into a compact transport position, in which the solar modules 3 are wound on a body 4. The body 4 is cuboid shaped in the embodiment and rotatably supported in a container designed as a housing 6 about an axis 5, so that all

Solar modules 3 wrapped in the transport position on the body 4 enclosed in the container are transportable. The container has an apparent side wall, which is divided in the middle and pivotally connected on both sides with the other side walls, so that this side wall forms an activation flap 7. In order to bring the device 1 in the working position, the activation flap 7 is opened, constructed by a modular connectable truss girder formed Spannholm 8 and connected to the container. On Spannholm 8 a likewise formed by a truss girder clamping point 9 is arranged at the end, to which the ropes 10 are fixed, on which ropes 10, the solar modules 3 are arranged. The solar modules 3 are unwound when tensioning the ropes 10 at the clamping point 9 of the body 4, wherein the body 4 is rotated about the axis 5. To bring the device 1 then back into the transport position, the body 4 in

Turned opposite direction, so that the solar modules 3 are wound up again on the body 4. An electrical connection of the solar modules 3 is usually carried out via the cables 10 or via lines attached to the cables 10.

In the exemplary embodiment, three chains of solar modules 3 arranged on two cables 10 are positioned next to one another in order to optimally utilize an available space in the container. Depending on the field of application, an energy store for the electrical energy generated by the solar modules 3 as well as an inverter can be positioned in the container, so that electrical energy can be directly provided with the device 1 for a final consumption. Fig. 3 shows a part of the body 4 in detail, on which the solar modules 3 are wound in the transport position. The body 4 is thereby through to a

cuboid frame associated profiles, especially steel or

Aluminum profiles, formed and has in a plane perpendicular to an axis 5, about which the body 4 is rotatable, a square cross section. A side edge of the square cross section corresponds to a side length of the modules along the direction of the longitudinal spar in the working position, so that the modules without

Interspaces one above the other on the body 4 can be wound, wherein

Focal points of the solar modules 3 are arranged approximately one above the other. In the apparatus 1 shown in Figs. 1 and 2, three parts shown in Fig. 3 of a body 4 are connected to a rotatable body 4, on which the three parallel chains of solar modules 3 can be wound.

With a device 1 according to the invention, generation of electrical energy from sunlight can be achieved in a simple manner, since the device 1 can be easily transported and can be easily put into operation by untrained personnel. Commissioning usually takes less than an hour. Furthermore, the device 1 can be made particularly simple and inexpensive, since the

Components of the device 1 as the body 4, on which the solar modules 3 are wound up as a rule, as well as the clamping beam 8 and the clamping point 9 by

 Standard profiles or standard trusses, in particular trusses can be formed. The device 1 is therefore particularly suitable for a decentralized energy supply in development areas. Due to the electrical devices usually arranged in the device 1, electrical energy adapted to frequency and voltage for an end user can be provided directly.

Claims

claims 1. Device (1) for generating electrical energy from sunlight with at least two solar cells (2), characterized in that the solar cells (2) are movably connected, so that the solar cells (2) in a working position in which the Solar cells (2) are positioned parallel to each other for simultaneous irradiation with sunlight, and in a transport position can be brought, in which the solar cells (2) are arranged compactly transportable at an angle to each other or one above the other. 2. Device (1) according to claim 1, characterized in that at least two solar modules (3) with solar cells (2) are provided, wherein the solar modules (3) are movable relative to each other, in particular foldable, connected to each other. 3. Device (1) according to claim 1 or 2, characterized in that a relative to a substrate about an axis (5) rotatably mounted body (4) is provided, which is connected to the solar cell (2) such that the solar cells (2) upon rotation of the body (4) in a first direction on the body (4) wound up and unwound upon rotation of the body (4) in a second direction. 4. Device (1) according to one of claims 1 to 3, characterized in that the body (4) in a cross section as a polygon, preferably as a regular polygon, in particular as a square, is formed. 5. Device (1) according to claim 4, characterized in that the  Solar cells (2) in a plurality of movably interconnected solar modules (3) are arranged, wherein a side length of the polygon corresponds to a length of a side edge of a solar module (3). 6. Device (1) according to claim 4 or 5, characterized in that the Solar modules (3) along a longitudinal direction via a cable (10) are connected, wherein the cable (10) with the body (4) is connected such that the cable (10) together with the Solar modules (3) on the body (4) is wound up. 7. Device (1) according to one of claims 4 to 6, characterized in that the solar modules (3) have identical dimensions and a distance between the solar modules (3) is in each case dimensioned such that the solar modules (3) when wound on the body (4) are positioned substantially congruently one above the other. 8. Device (1) according to one of claims 4 to 6, characterized in that focal points of the solar modules (3) are positioned one above the other when wound on the body (4) substantially. 9. Device (1) according to one of claims 1 to 8, characterized in that a housing (6) is provided, in which all solar modules (3) are positionable when the solar modules (3) are in the transport position. 10. Device (1) according to claim 9, characterized in that the housing (6) is cuboidal, in particular as a container formed. 1 1. A device (1) according to claim 9 or 10, characterized in that the housing (6) has an activation flap (7) and the solar cells (2) under opening of the activation flap (7) can be brought from the transport position to the working position. 12. Device (1) according to one of claims 1 to 11, characterized in that a, in particular separable, clamping device is provided, with which the solar cells (2) can be clamped in the working position. 13. Device (1) according to one of claims 1 to 12, characterized in that the clamping device in a housing (6) with the solar modules (3) can be transported if the solar modules (3) are in the transport position.