DE202021001230U1 - Energy generation plant - Google Patents

Abstract

Energy generation plant (1) for arrangement on inclined surfaces (2), having a foundation (13) arranged at the foot of the inclined surface (2), a supporting structure (3) resting on the inclined surface (2), at least one above the supporting structure (3) ) arranged and with the supporting structure (3) connected energy generation module (4, 4a, 4b) as well as a clamping device (17) firmly connected to the foundation (13), characterized in that the supporting structure (3) rotatable on the foundation (13) an axis of rotation (14) running along a slope line (15) of the inclined surface (2) is mounted, the clamping device (17) being coupled to the supporting structure (3) in such a way that a force emanating from the clamping device (17) hits the supporting structure ( 3) pushes towards the inclined surface (2).

Description

The invention relates to an energy generation system for arrangement on inclined surfaces, in which energy generation modules are arranged on a support structure resting on the inclined surface.

For the generation of electrical energy it is becoming more and more important to use sustainable raw materials. The generation of electrical energy from the sun and wind is of particular relevance. It is necessary to provide additional areas on which such energy generation systems can be installed in order to meet the great demand. It is necessary to make large areas available, since such systems usually require a lot of space in order to generate correspondingly large outputs. An important task in the field of renewable energies is therefore to find suitable areas for such energy generation systems.

Inclined surfaces are particularly suitable for setting up both photovoltaic systems and wind turbines. Inclined surfaces offer excellent conditions for photovoltaic systems because the inclination of the photovoltaic modules in the direction of the sun promises increased efficiency. Due to the inclination of the surfaces, directed wind currents also occur, which are well suited to be used for energy generation by means of wind turbines.

There are a large number of previously unused inclined surfaces, such as pointed cone heaps of mining waste or green waste dumps, the slope of which offers ideal conditions for the installation of energy generation systems. One reason for the low use of these areas so far is that fastening energy recovery systems, such as photovoltaic systems, to such surfaces is very problematic. Pointed cone heaps usually have a loose fill, which means that there is a risk of the systems slipping. Green landfills, on the other hand, harbor the risk of uncontrolled exhaust gas if the surface layers are damaged.

For the installation of photovoltaic systems on slopes, different designs are already known from the prior art. In DE 100 62 697 B4 a sheet of inert material covers the ground on the slope and the solar modules are mounted on two or three stilts, which in turn are attached to this sheet. The advantage here is that the foil is not damaged when the stilts are attached, since the stilts are glued in place. Due to the limitation of the number of stilts, a stable stand is guaranteed even when the subsoil settles. The separating joints between the individual solar modules enable the solar modules to tilt when the subsurface settles, without the solar modules being damaged. These are simply tilted. However, this type of fastening has the disadvantage that it is not very stable and the solar modules cannot be aligned as desired. On the contrary, the exact alignment of the modules depends on the subsurface. An alignment according to the course of the sun cannot be achieved.

In the DE 20 311 989 U1 a system for the generation of solar energy on slopes and on flat open spaces is proposed. The principle of this system is based on the fact that a solar module is arranged on a support frame, which is fastened in or on a container. This container can be weighted down by means of weights, in particular by means of a filling made of metallic or mineral material, and thereby obtain stability. The disadvantage here is that the weights have to be filled in individually. The container must also be selected to be of a correspondingly large size in order to limit the surface pressure in order not to risk sinking into the ground.

A photovoltaic unit consisting of a photovoltaic module and a supporting structure is in the DE 10 2012 007 743 A1 disclosed. The photovoltaic unit can be placed loosely on the ground, and it can be secured with weights or pegs. The disadvantage is that the security is not sufficient for sloping or sloping areas. The photovoltaic unit could lose its grip and slip off, especially under the additional influence of wind.

A method and a device for securing slopes with an additional arrangement of photovoltaic elements for energy generation is in EP 2 584 283 A1 described. Securing and stabilization of slope systems is achieved in that a ground anchor system is introduced into the ground, with a photovoltaic module being attachable to an adapter element arranged thereon. Slope securing by means of ground anchors is not feasible, especially in landfills, because this could damage existing protective and covering foils.

In the DE 203 14 665 U1 describes an arrangement for the surface covering of elevations, such as bulk material or spoil heaps, with an inclined or curved surface. A support structure is provided to accommodate solar modules and is slightly embedded in the heap. The supporting structure can be at levels of Heap, so in an area of horizontal ground, be supported on foot elements. The heap is additionally stabilized by the supporting structure. This arrangement has the disadvantage that the stability of the arrangement is inadequate, especially when wind occurs.

The systems from the prior art thus have major disadvantages and are particularly unsuitable when wind occurs.

The object of the invention is to provide an improved device for positioning energy generation modules, in particular photovoltaic modules, on inclined surfaces, which device overcomes the disadvantages of the prior art. In particular, the device should be suitable to be arranged on loose ground on which an anchoring for absorbing and dissipating forces is problematic. It is crucial that the device has sufficient stability so that it is not endangered even when wind occurs.

The object is achieved by an object with the features according to the independent protection claim. Further developments are given in the dependent claims.

The object is achieved in particular by an energy generation system for arrangement on inclined surfaces, which has a foundation arranged at the foot of the inclined surface, a supporting structure resting on the inclined surface, at least one energy recovery module arranged above the supporting structure and connected to the supporting structure, as well as a fixed to the foundation having connected jig. According to the invention, the supporting structure is rotatably mounted on the foundation about an axis of rotation running along a slope line of the inclined surface. The clamping device is coupled to the support structure in such a way that a force emanating from the clamping device presses the rotatably mounted support structure in the direction of the inclined surface.

The energy generation module is a device for generating energy, in particular for generating electrical energy from the sun or wind. The energy generation module is preferably designed as a photovoltaic module. In another variant, wind is used to generate energy. Wind refers to any directed air movement that is sufficiently strong to be used to generate energy. The term also refers in particular to a directed wind flow on the slope. The devices for generating electrical energy from wind are preferably wind turbines. According to one possible embodiment, there is a combination of photovoltaic modules and devices for generating electrical energy from wind, in particular wind turbines.

A sloping surface can also be referred to as a slope. Such inclined surfaces are, for example, dumps or landfills.

The jig is suitable for pushing the supporting structure in the direction of the slope. The supporting structure is preferably fixed by creating a bracing, i.e. a non-positive connection by pressing together parts of the clamping device with elements of the supporting structure, so that the supporting structure is locked on the inclined surface by tensioning.

The supporting structure is rotatably mounted on the foundation. The axis of rotation runs along a slope line of the inclined surface. In the context of the invention, the axis of rotation can also run parallel to a slope line of the inclined surface. It is relevant that the axis of rotation extends parallel to the ground and perpendicular to the direction of the slope.

According to a preferred embodiment, the support structure has at least one elongate support element arranged on the inclined surface in the direction of the slope. This support element is coupled to the clamping device in such a way that the support structure is pressed onto the inclined surface by means of the force transmitted from the clamping device to the support element. The support element is rotatably mounted about the axis of rotation running parallel to the slope line of the inclined surface. The support elements can also be arranged resting on the inclined surface in a different position. It is relevant that the support elements are arranged parallel to the surface of the inclined plane.

According to an advantageous embodiment, the elongate bearing element is supported on at least two bearing elements, each with a base plate resting on the inclined surface, at a distance from the floor. The bearing element of the energy generation system is mounted at a distance from the floor such that both the weight of the elongate bearing element and the weight of the energy generation module, such as the photovoltaic module, are distributed over the base plates with the aid of the base plates.

The support element is then pressed against the inclined surface by the clamping device via the bearing elements and the floor panels.

According to one possible embodiment, the support element of the support structure has a lever element which projects away from the floor and on which the force of the tensioning device is transmitted to the support element.

The lever element is rotated by the clamping device. Due to the rigid connection between the lever element and the rest of the support element, the entire support element is pressed in the direction of the inclined plane.

The support element is optionally designed as a segmented support profile.

The support structure preferably has at least two parallel, elongated support elements. Both support elements are rotatably mounted and coupled with the clamping device or with several clamping devices. The axes of rotation around which the support elements are rotatably mounted preferably coincide. According to an advantageous embodiment, the two support elements are arranged at a distance from one another. This distance from one another improves the load distribution and increases the stability of the supporting structure. To increase the stability, stiffening cross connections are particularly preferably arranged between the support elements. According to an advantageous embodiment, the cross connections run parallel to one another.

According to an alternative embodiment, the support structure has only one support element for fastening an energy generation module. Preferably, but not necessarily, the support element is then made wider in order to ensure sufficient stability.

Optionally, the supporting structure has loads on the supporting elements, such as, for example, attachable weights. These can be selected depending on the length of the support elements and the slope and serve to increase the contact pressure and prevent the system from swinging up. A plurality of weights can also be arranged on the support elements at defined intervals. This advantageously improves the fixation and stability of the energy generation system.

A power generation module is supported by the supporting structure and is arranged on this. An energy generation module can be supported by one or more support elements. According to a preferred embodiment, several energy generation modules, in particular several photovoltaic modules, are arranged on two support elements running in parallel. Each of the energy generation modules is arranged on both support elements and is supported by both support elements.

The supporting structure optionally has receiving elements for receiving the energy generation modules. The receiving elements are arranged on the support elements and rotatably mounted about a horizontal axis of rotation.

The horizontal axis of rotation runs at right angles to the extension of the support elements and parallel to the bearing axis of the support elements. The bearing axis of the support elements preferably runs at right angles to the direction of slope of the inclined surface. According to one possible embodiment, the angle of rotation of the photovoltaic modules is limited by mechanical stop points as a function of the slope.

In an advantageous embodiment, the axis of rotation of the receiving elements is arranged eccentrically above the center of gravity axis of the receiving elements.

According to a particularly advantageous embodiment, the rotatable mounting of the receiving elements can also be used to track the energy generation modules. This is particularly advantageous in the case of an embodiment which contains photovoltaic modules, since the system's yield situation can then be improved by setting an optimal angle of attack to the sun. A decoupling mechanism for the tracking system should be provided to protect the system from increasing wind loads.

According to an advantageous embodiment, the receiving elements have an enlarged area. In the event of wind attack against the slope, the receiving elements are placed in the wind due to the increased area below the bearing axis. In this way, additional contact pressure is generated for the system via the energy generation elements. The receiving elements preferably have guide plates.

The clamping device preferably has a force transmission element and a threaded spindle. The power transmission element can be moved against the supporting structure through the threaded spindle. A spindle is preferably used for the one-time basic setting, that is to say basic fixing of the supporting structure. The support structure can also be re-tensioned, for example in the course of maintenance work, by means of the spindle. In a particularly preferred variant, the position of the supporting structure is additionally fixed by locking nuts arranged on the spindle.

The clamping device optionally has a mechanical or an electrical or a hydraulic or a pneumatic drive.

The foundation of the energy generation system is preferably designed as a block foundation or also as a deep foundation by rammed piles. Such foundations can advantageously absorb large forces and are therefore well suited for the establishment of such an energy generation plant. According to the invention, the foundation is arranged at the foot of the inclined surface. The foot of the inclined surface is characterized by a horizontal surface which adjoins the inclined surface. In the context of the invention, the foot of the inclined surface is any horizontal surface below an inclined surface that is sufficiently solid to absorb the forces of the energy generation system. In particular, this can also be implemented on inserted berms.

According to the conception of the invention, a support structure with attached energy generation modules is arranged on an inclined surface, such as, for example, an embankment of a dump. This support structure is mounted on a foundation arranged at the foot of the inclined surface or at the foot of the embankment so as to be rotatable about an axis running parallel to an embankment line. In addition, the invention has a clamping device which is firmly connected to the foundation. This clamping device can transmit a force to the supporting structure, so that the supporting structure is thereby fixed on the inclined surface or the slope. The embankment can advantageously also have a loose structure, since the necessary forces are diverted via the foundation arranged at the foot of the embankment. It is consequently possible here to mount the supporting structure with the energy generation modules firmly on the embankment without damaging the surface of the embankment. This type of energy generation system can therefore also be used advantageously in landfills, since the protective devices usually present in landfills, such as protective films, do not have to be damaged in order to ensure that the energy generation system is fixed on the slope, i.e. the inclined surface.

• 1: eine Energiegewinnungsanlage mit Photovoltaikmodulen,
• 2: eine Energiegewinnungsanlage mit Windturbinen und
• 3: eine Energiegewinnungsanlage als Aufsicht.

Further details, features and advantages of embodiments of the invention emerge from the following description of exemplary embodiments with reference to the associated drawings. Show it:

• 1 : an energy generation system with photovoltaic modules,
• 2 : an energy generation plant with wind turbines and
• 3 : an energy generation plant as supervision.

In the 1 and 2 is in each case an energy generation system 1 shown from the side which is on a sloping surface 2 is arranged. Such a sloping surface 2 can be any slope 2 , for example the slope of a pointed cone slope. The energy generation plant 1 out 1 has a supporting structure 3 on which energy generation modules 4th in the form of photovoltaic modules 4a are attached. In 2 are those on the supporting structure 3 arranged energy generation modules 4th than wind turbines 4b educated.

The supporting structure 3 has either a single support element 5 or several support elements arranged in parallel 5 on. The supporting elements 5 are elongated and along the slope direction 6th aligned. The direction of the slope 6th points from the base of the embankment along the sloping surface 2 up.

The supporting elements 5 are on stock items 7th arranged so that the support elements 5 spaced from the surface of the inclined surface 2 are positioned. To distribute the load on the supporting structure 3 are the supporting elements 5 on base plates 8th arranged.

Above the support elements 5 are preferably rotatably mounted receiving elements 9 arranged on which the energy generation modules, here the photovoltaic modules 4th , are attached. On the receiving elements 9 are optionally rigid with the receiving elements 9 connected area enlargements 10 attached. When there is strong wind blowing against the slope, they can be rotated on the support elements 5 mounted receiving elements 9 through the increase in area 10 put in the wind. The rotatable mounting of the receiving elements 9 allows the surfaces of the photovoltaic modules 4th as well as optional area enlargement 10 for additional contact pressure on the supporting structure 3 on the inclined surface 2 to use. The influence of suction forces is due to the rotatably mounted receiving elements 9 greatly diminished. The receiving elements 9 are through above the bearing axis of the receiving elements 9 arranged counterweights 11 in the desired position to the inclined surface 2 held.

Wind attacks from the side and over the slope are in an advantageous variant through repellent baffles 12th in their suction effect on the supporting structure 3 limited.

The supporting structure 3 is on one at the foot of the inclined surface 2 arranged foundation 13th rotatably mounted. The axis of the rotatable bearing 14th the supporting structure 3 runs perpendicular to the direction of the slope 6th along an embankment line 15th , i.e. horizontally along the inclined surface 2 .

The supporting structure 3 in this exemplary embodiment also has one or more lever elements 16 on. Each of the lever elements 16 is perpendicular to the course of the supporting elements 5 , from the inclined surface 2 arranged protruding away. One firmly to the foundation 13th connected jig 17th engages the lever element 16 at. By one of the jig 17th on the lever element 16 The force transmitted will be rigid with the lever element 16 connected support elements 5 against the inclined surface 2 pressed. A change in length or a shift in position of a power transmission element 18th the jig 17th leads to one on the lever element 16 acting force, so that the support element 5 and with it the entire supporting structure 3 by means of this lever element 16 on the inclined surface 2 is pressed. It is thus possible to use the entire supporting structure 3 with the energy generation modules 4th by means of the jig 17th generated force on the inclined surface 2 to fix.

The supporting elements 5 consist in one possible embodiment of segmented and thus variable-length support profiles 5 . The segmented support profiles 5 bump into segment joints 19th to each other.

In 3 becomes an energy generation plant 1 shown with a view from above. The inclined surface, not shown here, is thus below the energy generation system 1 positioned. The energy generation modules 4th are, as in 2 shown, also here as wind turbines 4b educated. This energy generation plant 1 but can also be designed with photovoltaic modules (not shown here) or other energy generation modules. Several along the direction of the slope 6th running support elements 5 are arranged in parallel. The supporting elements 5 are components of the supporting structure 3 , on which the energy generation modules 4th are arranged and attached. The supporting elements 5 are like in the 1 and 2 Here designed as segmented support profiles, whose length-adjustable support profiles at segment joints 19th butt against each other. For fixing the supporting structure 3 are on several foundations 13th mounted clamping devices 17th present, which by means of a power transmission element 18th a force on the supporting structure 3 transferred and this on the inclined surface 2 press.

In this illustration there are several parallel to the slope line 15th running axes of rotation of the wind turbines 20th marked. The embankment line 15th runs horizontally.

Baffles 12th are at the top of the supporting structure 3 arranged. In connection with wind turbines 4b favor the baffles 12th advantageous the wind guidance in the turbine system.

List of reference symbols

1

Energy generation plant

2

Sloping surface, embankment

3

Supporting structure

4th

Energy generation module

4a

Photovoltaic module

4b

Wind turbine

5

Support element, support profile

6th

Direction of slope

7th

Bearing element

8th

Base plate

9

Receiving elements

10

Area enlargement

11

Counterweights

12th

Baffles

13th

foundation

14th

Bearing, rotating bearing, axis of rotation

15th

Embankment line

16

Lever element

17th

Jig

18th

Power transmission element

19th

Segment joint

20th

Axis of rotation of the wind turbine

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 10062697 B4 [0005]
• DE 20311989 U1 [0006]
• DE 102012007743 A1 [0007]
• EP 2584283 A1 [0008]
• DE 20314665 U1 [0009]

Claims (14)

Energy generation plant (1) for arrangement on inclined surfaces (2), having a foundation (13) arranged at the foot of the inclined surface (2), a supporting structure (3) resting on the inclined surface (2), at least one above the supporting structure (3) ) arranged and with the supporting structure (3) connected energy generation module (4, 4a, 4b) as well as a clamping device (17) firmly connected to the foundation (13), characterized in that the supporting structure (3) rotatable on the foundation (13) an axis of rotation (14) running along a slope line (15) of the inclined surface (2) is mounted, the clamping device (17) being coupled to the supporting structure (3) in such a way that a force emanating from the clamping device (17) hits the supporting structure ( 3) pushes towards the inclined surface (2). Energy generation system (1) according to Claim 1 , characterized in that the energy generation module (4) is designed as a photovoltaic module (4a). Energy generation system (1) according to Claim 1 or 2 , characterized in that the at least one energy generation module (4) is designed as a wind turbine (4b). Energy generation system (1) according to one of the Claims 1 to 3 , characterized in that the supporting structure (3) has at least one elongated supporting element (5) which is arranged on the inclined surface (2) in the direction of the slope (6) and which is coupled to the clamping device (17) in such a way that the supporting structure (3) is pressed onto the inclined surface (2) by means of the force transmitted to the support element (5) by the clamping device (17). Energy generation system (1) according to Claim 4 , characterized in that the elongated support element (5) is mounted on at least two bearing elements (7), each with a base plate (8) resting on the inclined surface (2) and spaced from the floor. Energy generation system (1) according to one of the Claims 4 or 5 , characterized in that the support structure (3) has a lever element (16) which projects away from the floor and by means of which the force of the clamping device (17) is transmitted to the support element (5). Energy generation system (1) according to one of the Claims 4 to 6th , characterized in that the support element (5) is designed as a segmented support profile (5). Energy generation system (1) according to one of the Claims 4 to 7th , characterized in that the support structure (3) has at least two parallel, elongated support elements (5). Energy generation system (1) according to one of the Claims 4 to 8th , characterized in that the supporting structure has receiving elements (9) for receiving the energy generation modules (4, 4a, 4b), which are arranged above the supporting elements (5) and are rotatably mounted about a horizontal axis of rotation. Energy generation system (1) according to Claim 9 , characterized in that the receiving elements (9) have an enlarged area (10). Energy generation system (1) according to one of the Claims 9 to 10 , characterized in that the receiving elements (9) have guide plates (12). Energy generation system (1) according to one of the Claims 1 to 11 , characterized in that the clamping device (17) has a power transmission element (18) and a threaded spindle, the power transmission element (18) being designed to be movable against the supporting structure (3) by the threaded spindle. Energy generation system (1) according to one of the Claims 1 to 12th , characterized in that the clamping device (17) has a mechanical or electrical or hydraulic or pneumatic drive. Energy generation system (1) according to one of the Claims 1 to 13th , characterized in that the foundation (13) is designed as a block foundation.

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