WO2017093540A1 - Building kit for a roof construction having solar panels, and method for assembling and disassembling such a roof construction - Google Patents

Abstract

The invention relates to a method for assembling a roof construction having solar panels on a ground surface (2), comprising: arranging a plurality of height-adjustable supporting elements (3) on the ground surface (2) in an arrangement with a plurality of rows of supporting elements (3) extending in parallel in a longitudinal direction; attaching a respective rail string (4a; 4b), which extends in the longitudinal direction of the rows, to upper ends of the supporting elements (3) of each of the rows of supporting elements (3); arranging a plurality of containers (5) in the transverse direction and next to one another at one end of the rail strings (4a, 4b), wherein the containers (5) are each opened towards the rail strings (4a 4b) and wherein each of the containers (5) has arranged therein a respective solar panel arm (6) with a plurality of connected panels (6a, 6b), which can be folded relative to one another, in a folded state according to a leporello folding pattern, and wherein some or all of the panels of a respective solar panel arm (6) are designed as solar panels; and moving the folded solar panel arms (6) out of the containers (5) onto the rail strings (4a, 4b) in the longitudinal direction, wherein the solar panels of a respective solar panel arm are unfolded relative to one another on being moved out of the containers.

Description

 Kit of a solar panels having roof construction and method for assembling and dismantling such a roof construction

The present invention relates to a method for constructing a solar panel roof construction and constructed by means of such a method roof construction or a kit of a build-up by means of such a method roof construction. Furthermore, the present invention relates to a method for dismantling such a roof construction.

In the prior art, solar power plants or solar panel constructions with a plurality of solar panels having, guided on rail tracks or retractable solar panel arms in zig-zag folding, which is also called Leporello folding, known.

For example, US 2013/0186450 A1 relates to a mobile, expandable and degradable solar power plant in which a solar panel arm is arranged in a transportable state with a plurality of connected, relatively foldable panels in a folded state according to a Leporello folding in a container and the Solar panel arm for the construction of the solar power plant on rail tracks from the container on the rail tracks is extended laterally, the solar panels of the Solarpaneelarms are deployed in the extension from the container relative to each other. Concerning the mobile buildable solar power plant according to US 2013/0186450 A1, the inventors found that the basis for the present invention is that there are problems that solar panel arms extending laterally out of the containers require a lot of space that can not be used elsewhere, and also electrical ones Lines must be routed to any positioned at a distance, electrical consumers or energy supply systems, and also have the container respective additional lateral control rooms that complicate a dense positioning of the container and their solar panel arms next to each other.

The principle of extending a solar panel arm from a folded state similar to the principle of US 2013/0186450 A1 according to a leporello folding on rail tracks to form a solar panel having solar panel construction on a roof of a fixed building is further described in US 201 1/0253193 A1 known. However, this is only about the fixed installed solar panel arm construction on the roof of the fixed building depending on the needs and weather conditions or sunlight flexibly extendable and extendable design. For mobile Devices or constructions, the technical teaching of US 201 1/0253193 A1 is not designed.

The object of the present invention, starting from the above-described prior art, in particular on the basis of the technical teaching of US 2013/0186450 A1, to provide a plurality of solar panel arms having construction that is space-saving and versatile use and degradable, the above avoids problems described and at the same time easy, efficient and inexpensive to build up and is degradable and easy, efficient and inexpensive mobile use, especially in construction and dismantling or the use of mobile solar power plants. To achieve the above objects is according to the present

Invention proposed a method for building a solar panels having roof construction on a soil surface according to claim 1. Furthermore, a roof construction constructed using such a method or a kit of a buildable roof construction according to claim 18 as well as a method for dismantling a roof construction constructed according to such a construction method according to claim 17 are proposed. Dependent claims relate to preferred embodiments of the present invention.

A method according to the invention for constructing a solar panel-mounted roof construction on a floor surface comprises: arranging a plurality of height-adjustable support elements on the floor surface preferably in an arrangement with a plurality of rows of support elements preferably parallel in a longitudinal direction; attaching a respective rail track extending in the longitudinal direction of the rows, preferably at upper ends of the support elements of each of the rows of support elements; arranging a plurality of containers preferably in the transverse direction next to one another at one end of the rail tracks, the containers preferably being opened in each case towards the rail tracks and wherein in each of the containers a respective solar panel arm having a plurality of connected, relatively foldable panels is preferably in a folded state is arranged according to a zig-zag folding, and wherein, by way of example, some or preferably all or every other of the panels of a respective solar panel arm are formed as a solar panel; and / or the extension of the folded solar panel arms from the containers on the rail tracks in the longitudinal direction, wherein the solar panels of a respective solar panel arms are preferably deployed relative to each other during the extension from the containers.

This results in the advantages that an easily transportable and easily, quickly, efficiently, time-saving and cost-effective to set up or degradable system or an associated construction method can be provided to form a roof or even hall construction with a solar panel having roof, which can be used particularly advantageous for the construction and dismantling of mobile solar power plants. In addition, due to the zig-zag folding of the Solarpaneelarme results in a high stability or rigidity of the roof structure, eg. B. against occurring forces in strong winds.

Depending on local regulations, building permits are either not necessary or at least easier to acquire than permanently installed roof constructions, especially since no building foundations need to be provided. In addition, the roof or solar power plant can be easily and sustainably completely degraded without remaining residues at the construction site. This also protects nature and the environment.

Even before the transport, all or parts of the required components can be easily, efficiently and inexpensively combined in a well transportable kit together, and a simple and inexpensive construction is also advantageously allows, with no complex installation work is needed. At the same time, the interior resulting from the roof structure makes it possible to provide a large covered area under the solar panel arms as fully usable, covered and dry space, which can also be supplied directly with electrical energy and can therefore be used as a mobile factory hall, in the machines or factory fixtures The integrated solar power plant can be supplied directly with electrical energy. Alternatively, the covered area may alternatively be used as a parking space with an electric charging option for electric vehicles.

Thus, there is also the advantage that the roof structure with integrated solar energy worldwide, is fast and easy to use or buildable and thus is particularly advantageous where fast and easy a sheltered space and energy are needed, eg. For example, refugee accommodation in crisis regions or short-term needs, migrant construction sites or mining operations or even at research stations.

In addition, such a roof construction can be advantageously used as a warehouse, hall, shelter or shelter, the required hall or storage height is advantageously adjustable by the height-adjustable support elements as needed. For the efficient and cost-effective transport of the kit of buildable

Roof construction can be advantageously used simple and inexpensive standard containers (eg size-standardized container with a length of 20 or 40 feet), which can be preferably modified if necessary, such that they can be opened on the sides. When set up, the containers can advantageously also efficiently form the walls of an emerging hall construction on one side of the roof construction. The extension or extraction of the solar panel arms from the containers can z. Example by means of rails running on rail tracks wheels or slideways or sliding guides, which may optionally be provided in addition to the internal solar panel arms an internal or external cable system. According to an expedient, exemplary preferred embodiment, the

Construction method further include raising the rail tracks and possibly also the lifting of the arranged on the rail tracks, unfolded solar panel arms by means of height adjustment of the arranged on the bottom surface supporting elements.

This has the advantage that the height of the roof construction can be adjusted depending on the space required. Here, it is possible to first mount the rail tracks at a low level to extend at low height, the solar panel arms from the containers and then set the predetermined height of the roof structure by simultaneous height adjustment of the support elements (possibly hydraulically, electrically and / or pneumatically controlled) , In further embodiments, however, it is also advantageously possible, the

Rail tracks at already set, predetermined height of the roof structure on the support elements, preferably approximately horizontal or at a predetermined angle to the already height-adjusted support elements and raise the container for extending the Solarpaneelarme on the rail tracks, possibly by one or more cranes, lifts, height adjustable Support elements or by placing the container on a voraufgebaute scaffolding construction for receiving the container at the level of the rail tracks. In this case, the method preferably comprises lifting the containers to rail track height.

This has the advantage that the height of the support elements can be accurately adjusted before attaching the rail tracks, and the orientation of the rail tracks parallel to each other at a predetermined distance and horizontally or at a predetermined angle of inclination can be accurately positioned before the Solarpaneelarme on the rail tracks from the containers be extended.

Preferably, the containers are positioned directly next to one another in a flight, possibly simultaneously or in one operation. This has the advantage that the containers can be tightly packed, ie precisely positioned at a small distance from each other in contact with each other and in a line transversely to the longitudinal direction and thus easily positioned a substantially closed roof from exactly can be formed parallel to each other extended solar panel arms. According to an expedient, exemplary preferred embodiment, the construction method may further comprise the laying of a plurality of flat floor slabs, in particular concrete slabs or plastic slabs, wherein the support elements are preferably arranged on the laid floor slabs. This has the advantage that under the roof construction, a hall floor or a solid floor surface can be formed, so that the roof construction can be easily placed on a solid base, which can be formed flat before positioning the support elements. Alternatively, it is possible to arrange the support elements on a flat concrete surface or on a solid floor surface. According to an expedient, exemplary preferred embodiment, the

Rail tracks are each arranged in a horizontal orientation or at a predetermined angle of inclination, but parallel to each other, at the upper ends of the support elements. It is advantageously possible to adjust the orientation of the rail elements by the support elements are adjusted in their set height before the rail tracks are mounted. Alternatively, the height, the inclination or the horizontal orientation can be adjusted by adjusting the heights of the support elements in already mounted rail tracks, but preferably before extending the solar panel arms from the containers.

According to an expedient, exemplary preferred embodiment, the upper ends of the support elements can be positioned on uneven ground surface before arranging the rail tracks by height adjustment of some or all support elements at the same height or depending on a predetermined angle of inclination of the rail tracks to each other. This has the advantage that any unevenness of the soil or the soil surface can be compensated by adjusting the heights of the height-adjustable support elements. Consequently, the construction of the roof construction according to the invention can not only be done on a level floor, but simple, but versatile, even on uneven ground surfaces.

According to an expedient, exemplary preferred embodiment, each panel of the solar panel arms is designed as a solar panel. In this case, such an embodiment is optimally suited to construct the roof construction such that the longitudinal direction is oriented in an east-west direction or substantially in an east-west direction. Namely, if the solar panel arms are deployed so that the panels are not all aligned horizontally in the extended position, but still have a respective predetermined folding angle to each other (especially leporello-like), then the solar panels of a Solarpaneelarms are paired so aligned that a solar panel with after The east facing surface is inclined and the other facing west Surface is inclined. This has the advantages that power generation is more evenly distributed throughout the day and that radiation reflected from opposite solar modules can be better utilized.

According to an expedient, exemplary preferred embodiment, every second panel of the solar panel arms is designed as a solar panel. In this case, such an embodiment is optimally suited to construct the roof construction such that the longitudinal direction is aligned in a north-south direction or substantially in a north-south direction. Namely, if the solar panel arms are deployed so that the panels are not all aligned horizontally in the extended position, but still have a respective predetermined folding angle to each other (especially leporello-like), then the panels of a Solarpaneelarms are aligned in pairs so that a solar panel with North facing surface is inclined and the other is inclined with a south-facing surface. The orientation of the solar panel arms can then be advantageously chosen such that only one of the panel pairs is designed as a solar panel, and points in the direction that guarantees the higher solar radiation, d. H. especially to the south when building up in the northern hemisphere of the earth or to the north in the southern hemisphere of the earth.

According to an expedient, exemplary preferred embodiment, the roof structure is preferably formed closed at the top, preferably by each adjacent in the transverse direction adjacent panels of Solarpaneelarme in unfolded state after extending out of the containers on the rail tracks to form the closed top roof construction together. This has the advantage that the roof construction can be completed upwards easily and inexpensively, in order to avoid in particular a penetration of precipitation in spaces between pairs adjacent solar panel arms.

In this case, adjacent panels may preferably be connected by means of plastic strips which can be attached between the panels, in particular of transparent plastic material. This has the advantage that the connection can be made simple and inexpensive and also waterproof. Alternatively, it is also possible to form the connection by means of tarpaulin sections.

Preferably, the roof structure is inclined transversely to a longitudinal side, so that on the roof construction collecting rainfall, especially rainwater or snow or thawed snow, runs in the transverse direction to the lower longitudinal side and there conveniently is collected in a along a longitudinal groove extending to advantageous for a further use, for example, an irrigation of Fields, greenhouses or the supply to a public or private drinking water supply to be supplied.

Preferably, the panels are heated at low temperatures to advantageously prevent accumulation of snow on the roof structure and reduce roof loads.

The use of transparent or translucent material has the advantage that light irradiation during the day can be embedded in the lying under the panel arms of the roof interior and at least during the day can be dispensed with additional electrical lighting of the interior or at least the requirements for additional electrical lighting of the Interior can be kept lower. For this purpose, it is additionally or alternatively preferred that some or all of the panels or solar panels are transparent, in particular with transparent solar modules. This also facilitates the use of the roof construction as a greenhouse roof.

According to an expedient exemplary preferred embodiment, the method may further comprise attaching a plurality of wall elements to outboard rows of support members to form a hall structure based on the formed roof construction. This has the advantage that in addition a laterally protected interior can be formed under the roof construction in a simple and cost-effective manner. It is advantageously possible to complete one, several or all sides of the roof structure with wall sections or wall elements, wherein preferably at least one wall element can have an opening for doors or gates. In this case, it is furthermore preferred and advantageously possible for some or all wall elements to be designed as solar panels, in particular in order to be able to further increase the solar yield. Alternatively, or in addition to the use of wall panels, the method may also include attaching one or more tarpaulin sections to outboard rows of support members to form a tent construction based on the formed roof construction. This has the advantage that in addition a laterally protected interior can be formed under the roof construction in a simple and cost-effective manner. In this case, it is advantageously possible to complete one, several or all sides of the roof construction with wall sections or wall elements.

According to an expedient, exemplary preferred embodiment, the method may further comprise removing the arranged containers after extending the solar panel arms out of the containers. This advantageously allows a completed on all sides roof or hall construction without space-reducing container. Alternatively, however, the containers may remain positioned in position after extension of the solar panel arms. This has the advantage that any required energy converters (eg DC-AC converters and / or electromagnetic transformers) or electrical installation equipment electrically connected to the solar panel arms can be provided in the containers and protected against wind and weather or precipitation in the containers as well as being protected against unauthorized human intervention. In addition, this has the advantage that a reduction of the roof construction is simplified, since for retracting the degraded solar panel arms in containers they do not need to be accurately repositioned and / or lifted with accurate positioning, but the solar panel arms could be easily retracted after opening the container.

According to an expedient, exemplary preferred embodiment, respective adjacent, relatively folding or unfoldable panels of a Solarpaneelarms by means of a hinge connection and / or by means of one or more plastic strip or tent tarpaulin sections, in particular made of transparent material, be connected to each other. The plastic strips or tarpaulin sections have the advantage that the interior lying under the roof structure can be easily and inexpensively protected against precipitation. The use of transparent or translucent material offers the above-described advantages of incident light into the interior during the day.

According to an expedient, exemplary preferred embodiment, the solar panels of a solar panel arm may include one or more respective electrical connectors for electrical connection to one or more electrical loads, to a power supply system and / or to one or more other solar panels of the same solar panel arm and / or other solar panel arms of the roof structure exhibit.

This has the advantage that the electrical connection of the solar panels with each other, with a power grid, with energy converters or with storage devices for storing electrical energy in the structure can be carried out easily and inexpensively, since the wiring and connectors are already provided.

The already provided connectors also have the advantages that on the one hand when constructing high voltages can be avoided because the solar panels can be electrically connected to each other or finished with a roof or hall construction with each other or with a power supply device, and also makes this possible especially when connecting the panels Lips, for example In Firm of a tongue and groove Engagement, for example in the form of a piping connection a simple and cost-effective replacement of individual solar panels or solar modules in case of failure.

According to an expedient, exemplary preferred embodiment, the solar panels of a solar panel arm can each have on their respective surfaces a plurality of solar modules which are arranged on a panel structure, in particular a panel frame or a panel plate. The solar modules may comprise one or more solar cells or photovoltaic cells. In addition, thermal solar collectors can be integrated in other exemplary embodiments for connection to a build-up under the roof construction treatment system for warming up water with solar energy.

According to an expedient, exemplary preferred embodiment, each panel structure may comprise a water-impermeable layer, and the water-impermeable layer may in particular comprise a water-impermeable connecting material. This has the advantage that the interior can be better protected against precipitation. The above-described aspects or their individual features describe preferred embodiments of the invention, but the invention is in no way to be construed as limited to these aspects and features, but rather other embodiments are conceivable and to be included in the invention, insofar as they fall under the independent claims. In particular, it should be noted that further embodiments can be formed solely by any combination of the above aspects and their individual features, which are not individually described or enumerated solely because of the high number of possible combinations.

Further, according to the present invention, there can be provided a method for dismounting a roof structure constructed according to a method of any one of the preceding aspects, including retracting the solar panel arms into the containers on the rail strands disposed on height adjustable support members in the longitudinal direction until each of the solar panel arms are folded State is arranged in the respective container, and wherein after retraction of the Solarpaneelarme the roof structure of the rail tracks and the height-adjustable support elements is reduced.

Furthermore, according to the present invention, there can be provided a roof structure which is or may be constructed according to a method as described above or degraded according to a method as described above. In particular, according to the invention, a kit of a roof construction which is buildable according to a method described above or degradable in the assembled state according to a method described above, comprising: a plurality of height-adjustable support elements which in construction of the roof construction on the ground surface in a plurality of arrangement arranged in a longitudinally parallel rows of support members; a plurality of rail tracks which are arranged, when the roof structure is constructed in the longitudinal direction of the rows, at upper ends of the support elements of respective rows of support elements; and / or a plurality of foldable solar panel arms, which are adapted to be extended in the construction of the roof structure on the rail tracks in the longitudinal direction of each of the rail tracks open containers.

Preferably, the kit further comprises a plurality of transversely positionable in a row directly next to each other positionable containers.

In summary, the invention and its numerous embodiments advantageously makes it possible to provide a construction comprising several solar panel arms which is space-saving and versatile in use and can be dismantled, avoids the problems described above and at the same time is simple, efficient and inexpensive to construct and dismantle and simple, efficient and cost mobile, especially in construction and dismantling or the use of mobile solar power plants.

 Hereinafter, aspects and features of preferred embodiments of the present invention and exemplary combinations of these aspects will be described in detail, by way of example, with reference to the accompanying drawings.

Show it:

1 is an exemplary, schematic perspective view of a hall construction based on a roof construction according to an exemplary embodiment of the invention,

2 is an exemplary schematic perspective view of a roof construction according to an exemplary embodiment of the invention,

3 is an exemplary schematic perspective view of a roof structure under construction according to an exemplary embodiment of the invention;

4 shows an exemplary, schematic, detailed perspective view of a roof structure under construction according to an exemplary embodiment of the invention, 5 shows an exemplary, schematic, detailed perspective view of a roof structure under construction according to a further exemplary embodiment of the invention,

6 is an exemplary, schematic perspective view of two connected solar panels,

7 shows an exemplary, schematic perspective detailed representation of the connection of the adjacent solar panels according to FIG. 6, FIG.

8 is an exemplary schematic perspective view of a roof structure under construction on an uneven floor surface according to another exemplary embodiment of the invention and

9 is an exemplary schematic perspective view of a structure of the roof structure with diagonal braces of an exemplary embodiment of the invention under construction.

Identical or similar elements in the figures may be designated by the same reference symbols, but possibly also with different reference symbols. It should be emphasized that the present invention is in no way limited or limited to the exemplary embodiments described below and their design features, but may furthermore also comprise further exemplary embodiments and modifications of the exemplary embodiments, in particular those which are modified by modifications of the features of the described examples or FIGS are included by combining one or more of the features of the described examples within the scope of the independent claims.

In Fig. 1, the exemplary roof construction 1 is shown with an optional side cladding with laterally mounted wall elements 8, this being an exemplary embodiment of a hall construction based on an embodiment of a roof construction according to the present invention. The exemplary roof construction 1 without the optional side trim or wall cladding is shown in FIG.

By way of example, a plurality of height-adjustable support elements 3 are arranged in rows on the flat bottom surface 2, which is laid, for example, from parallel floor slabs, which are positioned parallel to one another in the longitudinal direction. By way of example, FIG. 2 shows ten parallel rows of support elements 3, which extend, for example, from obliquely lower left to obliquely upper right in FIG. 2. On the rows of height-adjustable support elements 3, respective rail tracks 4a and 4b are arranged, each extending along a respective row in the longitudinal direction and consequently parallel to one another. Here, the rail tracks 4a and 4b are arranged in pairs, for example, in such a way that a distance between the rail tracks 4a and 4b of a rail track pair is set as a function of a width of the later described solar panel arms 6. Adjacent rail tracks 4b and 4a of various adjacently arranged rail track pairs are, in contrast, arranged such that they run substantially directly next to one another in parallel and a predetermined minimum distance of, for example, less than or equal to 50 cm or preferably less than or equal to 20 cm is not exceeded.

A respective solar panel arm 6 (for example a total of five solar panel arms is movably guided or mounted longitudinally in Fig. 2. The solar panel arms 6 comprise by way of example a plurality of panels 6a and 6b connected in pairs (see also Figs. Fig. 2 shows the arrangement of the solar panel arms 6 in an unfolded state of the formed roof construction, wherein preferably the panels of the respective solar panel arms have a folding angle.

Preferably, the panels of all parallel solar panel arms 6 each have the same folding angle, and also adjacent panels of adjacent Solarpaneelarme 6 are preferably inclined at the same angle and seen in the transverse direction the same position (or arranged in the transverse direction in each case in an alignment), so that the panels adjacent solar panel arms 6 advantageous with a closing connection z. B. by plastic strip or tarpaulin sections to complete the roof construction can be joined up or connected up. The predetermined folding angle can z. B. by intended fixing system, such. B.

Fixing ropes or Fixierseilzüge, set or be set adjustable.

The principle of construction of the roof structure 1 according to an embodiment is described with reference to Figs. 3 and 4 can be seen. Preferably, the support elements 3 are positioned in the rows in the longitudinal direction and set to a predetermined height of the roof construction, here for example at the same height on a flat ground or a flat bottom surface 2, such that after setting up the height-adjusted support elements 3, the rail tracks 4a and 4b placed and fixed or fixed, in particular by way of example in horizontal extent in the longitudinal direction.

At one end of the parallel rail tracks 4a and 4b, for example, a plurality of containers 5 are placed in the transverse direction in alignment next to each other and with an openable container side to the rail tracks 4a and 4b arranged indicative. Standard containers can be used here (eg 20-foot or 40-foot-long standard containers) or modified standard containers that can be opened or opened to the longer container side. In the containers 5 are before the construction of the roof structure 1, the respective

Solar panel arms 6 arranged in the folded state according to Leporello folding, wherein the panels 6a and 6b are preferably arranged in the fully folded state in the containers 5 in parallel or with a folding angle of substantially 180 degrees (see Fig. 3).

In the structure of the roof structure 1, the containers 5 are preferably raised to rail track height, so that the solar panel arms 6 can be extended on the rail tracks 4a and 4b (see FIG. 4), particularly preferably until the predetermined angle of inclination between all adjacent panels 6a and 6b in FIG Substantially over the entire length of the roof construction 1 is achieved and adjacent panels 6a and 6a or 6b and 6b of adjacent solar panel arms 6 to each other (preferably lying in a plane) are positioned (see Figures 1, 2 and 3).

In Fig. 4, the containers are exemplarily positioned such that a lower side of the container 5 is positioned at rail track height. Fig. 5 shows an alternative exemplary embodiment, in which the panels 6a, 6b are also vertically aligned in the container 5 and are extended on an upper side of the container 5, wherein preferably an upper side of the container 5 is positioned at rail track height. The vertical arrangement of the panels 6a and 6b in the folded state in the container 5 reduces the risk of mutual scratching during transport against, for example, horizontal storage in the container. 5

FIGS. Figures 6 and 7 show an exemplary foldable connection of adjacent panels 6a and 6b, with only one for north-south orientation - i.e. H. preferably every other - the panels 6a and 6b may be formed as a solar panel 6 with solar modules or alternatively both - d. H. preferably all - panels 6a and 6b of the solar panel arm 6 can be designed as solar panels with solar modules.

By way of example, the panels 6a and 6b each comprise a panel frame 10, on each side of the panel frame 10 a plastic strip 9 for forming the foldable connection of the panels 6a and 6b is arranged and attached to the respective sides of the panel frame 10, for example according to an exemplary dimensional accuracy (For example, by pushing out in the transverse direction detachable) groove connection according to FIG. 7. In preferred embodiments, the plastic strips 9 are made of transparent or translucent plastic material formed. In further embodiments, it is also possible to design the panels themselves or the solar panels translucent.

An opening or folding of the panels 6a and 6b relative to each other is easily possible by elastically bending the plastic strip 9, and, moreover, the connection for protection against precipitation can thus be designed to be impermeable to water.

Similarly, in the unfolded state, adjacent panels of adjacent solar panel arms strip with plastic or alternatively be connected to tarpaulin sections to provide even better protection against precipitation and form the entire roof structure 1 closed. Another advantage of the invention is shown in the exemplary illustration of FIG.

8, in which a roof structure according to an embodiment on an uneven floor or an uneven floor surface 2 is placed so that the lower sides of the support members 3 can not be aligned at a height. However, by adjusting the height adjustment of the height-adjustable support members 3, it is possible to favorably set a state in which all the upper sides of the support members 3 are positioned at a height corresponding to a predetermined inclination angle to align the rail tracks 4a and 4b despite the unevenness the soil surface

2 to align exactly.

FIG. 9 shows an exemplary development of the invention. In the transverse direction of adjacent rail tracks 4a and 4b supporting pillars 3 are connected by two diagonal braces 1 1 with each other. It can all the adjacent pillars

3 adjacent rail tracks 4a and 4b be braced with each other. Alternatively, only a few buttresses 3 are connected to each other in the transverse direction by diagonal braces, for example, every second, third, fourth, etc. supporting pillar 3 of a rail track 4a connected to a second, third, fourth, etc. support pillars 3 of an adjacent rail track 4b. The diagonal struts 1 1 prevent tilting of the structure in the transverse direction.

In FIG. 9, by way of example, additional diagonal corner braces 12 are preferably provided between the rail tracks 4 a, 4 b and the supporting pillars 3. Each or some pillars 3 are suitably fixedly connected to one or two opposing corner braces 12 with the associated rail track 4a and 4b. The corner braces prevent tilting of the support structure in the longitudinal direction.

It should again be emphasized that the present invention is in no way limited or limited to the aspects described above, embodiments and their embodiment features, but also further Embodiments and modifications of the embodiments may include, in particular, those included by modifications of the features of the described examples or by combination of one or more of the features of the described examples within the scope of the independent claims. Further possible and advantageous aspects arise, for example, as follows:

The longitudinal direction of the roof or hall construction during construction (installation of the PV hall or photovoltaic hall) can be done in different spatial directions to optimize the power requirements depending on the local conditions, eg. B .: approximate east-west orientation of the longitudinal direction of the solar panel arms or PV modules (photovoltaic modules or solar panels 6a, 6b) for generating a possible even over the course of the day power generation with relatively high production in the morning and evening; Approximate south orientation of the longitudinal direction of the solar panel arms 6 or PV modules (photovoltaic modules or solar panels 6a, 6b) and use of non-photovoltaic active areas on the north-facing surfaces to maximize the yield per module (or the reverse in the southern hemisphere) , d. h., z. B. each second panel 6a, 6b of each Solarpaneelarms 6 may be formed as a solar panel 6a, 6b and possibly also an optimization of the setting of the predetermined inclination or folding angle of the PV module surfaces or solar panels 6a, 6b in unfolded state and / or adjusting an inclination angle of the rail tracks to site-specific conditions. Another advantage is the use of transparent materials between the PV

Module surfaces or between the panels 6a, 6b and for connecting a plurality of PV module tracks or solar panel arms 6, to better illuminate the building or the roof or hall construction by daylight.

Another advantage is the use of transparent PV modules or solar panels 6a, 6b to better illuminate the building or the roof or hall construction by daylight.

Also advantageous is a possible replacement of individual PV modules or solar panels 6a, 6b by transparent materials to better illuminate the building or the roof or hall construction by daylight, z. B. in the northern hemisphere instead of PV modules glass surfaces or transparent tarpaulins or plastic surfaces in the north-facing areas in construction of the roof structure with south-facing modules or solar panel 6.

Also advantageous is the design of side walls with PV modules or solar panels 6a, 6b to maximize power production per base area. Further advantageous is an exemplary option for heating the PV modules or solar panels 6a, 6b (eg by applying a reversed voltage) and / or heating the PV module frame or panel frame or PV module lower edges for reduction Yield losses due to dew, snow and ice and to reduce maximum roof loads.

Related electrical installations, such. As inverters, batteries or rechargeable batteries, transformers, etc., can advantageously be protected under the roof structure or preferably remain in the containers 5.

In addition, a simple cleaning z. B. be performed automatically by robots, especially in closed roof construction.

In particular, it should be noted that the formed by embodiments of the invention large closed (roof) surface advantageously allows the greatest possible area utilization and leads to the greatest possible power production per base. Assuming a module efficiency of z. For example, 15% with East-West orientation of the PV modules or solar panels 6 maximum powers of approximately 1.5 MW per hectare are possible, while conventional arrangements for non-photovoltaic active free areas between the modules reach only about half the size ,

The direct inclusion of the PV modules or solar panels 6a, 6b in the roof construction and the high intrinsic strength of the Leporelloanordnung allow very low construction costs and a rigid and stable, mobile up and degradable roof or hall construction with directly integrated energy supply by solar energy.

In summary, the invention and its numerous embodiments advantageously make it possible to provide a construction comprising several solar panel arms 6 that is space-saving and versatile in use and can be dismantled, avoids the problems described above and at the same time is simple, efficient and inexpensive to assemble and disassemble, and simply can be used efficiently and inexpensively mobile, in particular in the construction and dismantling or the use of mobile solar power plants.

Claims

 claims

A method of constructing a solar panel roof construction on a floor surface (2), comprising:

 Arranging a plurality of height-adjustable support elements (3) on the

Floor surface (2) in an array having a plurality of longitudinally parallel rows of support members (3);

Attaching a respective extending in the longitudinal direction of the rows

Rail track (4a, 4b) at upper ends of the support members (3) of each of the rows of support members (3);

 Arranging a plurality of containers (5) in the transverse direction next to each other at one end of the rail tracks (4a, 4b), the containers (5) in each case to the

Rail tracks (4a, 4b) are opened and wherein in each of the containers (5) a respective solar panel arm (6) is arranged with a plurality of connected, relatively foldable panels (6a, 6b) in a folded state according to a Leporello folding, and wherein some or all of the panels of each solar panel arm (6) are formed as solar panels (6a, 6b); and

 Extending the folded solar panel arms (6) from the containers (5) to the

Rail tracks (4a, 4b) in the longitudinal direction, wherein the panels of a respective solar panel arm (6) are deployed in the extension from the containers relative to each other.

Method according to claim 1,

characterized by lifting the rail tracks (4a, 4b) and on the

Rail strands (4a, 4b) arranged unfolded solar panel arms (6) by means of height adjustment of the bottom surface (2) arranged support elements (3).

Method according to claim 1 or 2,

characterized in that the containers (5) are positioned simultaneously and immediately adjacent to one another in a flight.

Method according to one of the preceding claims,

characterized in that the containers (5) are raised to rail track height.

5. Method according to one of the preceding claims,

 characterized by laying a plurality of flat floor panels, in particular concrete slabs, wherein the support elements (3) are arranged on the laid floor slabs.

6. Method according to one of the preceding claims,

 characterized in that the rail tracks (4a, 4b) are arranged in each case in a horizontal orientation or at a predetermined angle of inclination at the upper ends of the support elements (3).

7. The method according to claim 5,

 characterized in that the upper ends of the support elements (3) at uneven bottom surface (2) before positioning the rail tracks (4a, 4b) by height adjustment of some or all support elements (3) are positioned at the same height to each other.

8. Method according to one of the preceding claims,

 characterized in that the roof structure is formed closed at the top by each respective adjacent in the transverse direction of the panel panels Solarpaneelarme (6) after deployment from the containers (5) on the rail tracks (4a, 4b) to form the closed top roof construction be connected to each other.

9. The method according to claim 8,

 characterized in that adjacent panels strip by means of attachable between the panels material, in particular made of transparent material, are connected.

10. The method according to any one of the preceding claims,

characterized in that the roof construction is constructed inclined in the transverse direction in the direction of the sun track south and thus on the closed roof construction collecting precipitation is discharged to a longitudinal side.

1 1. Method according to one of the preceding claims,

 characterized by attaching a plurality of wall elements (8)

 outer rows of support members (3) for forming a hall structure based on the formed roof construction.

12. The method according to any one of the preceding claims,

 characterized by removing the arranged container (5) after extending the solar panel arms (6) from the containers (5).

13. The method according to any one of the preceding claims,

 characterized in that respective adjacent, relative to each other folding or

 deployable panels of the solar panel arm (6) by means of one or more

 Plastic strips, in particular made of transparent plastic material, are movably connected to each other.

14. The method according to any one of the preceding claims,

 characterized in that the panels (6a; 6b) of a solar panel arm (6) comprise one or more respective electrical connectors for electrical connection to one or more electrical loads, to a power supply system and / or to one or more other solar panels of the same solar panel arm (6). and / or other solar panel arms (6) of the roof construction.

15. The method according to any one of the preceding claims,

 characterized in that the solar panels (6a; 6b) of a solar panel arm (6) each have on their respective surface a plurality of solar modules which are arranged on a panel structure, in particular a panel frame or a panel plate.

16. The method according to any one of the preceding claims,

 characterized in that the solar panels (6a, 6b) are heated.

17. A method for degrading a according to a method according to any one of the above

Claims constructed roof construction, comprising: Retracting the Solarpaneelarme (6) in the container (5) on the height-adjustable support elements (3) arranged rail tracks (4a, 4b) in the longitudinal direction until each of the solar panel arms (6) in the folded state in the respective container (5) is arranged , and wherein after retracting the solar panel arms (6), the roof structure of the rail tracks (4a, 4b) and the height-adjustable support elements (3) is degraded.

18. Kit of a roof construction, which can be built according to a method according to one of claims 1 to 16, comprising:

 a plurality of height-adjustable support elements (3), which in construction of the

 Roof construction on the ground surface in an arrangement with a plurality of longitudinally parallel rows of support members (3) are arranged;

 a plurality of rail tracks (4a; 4b) arranged to extend along the longitudinal direction of the rows when the roof structure is constructed, at upper ends of the support members (3) of respective rows of support members (3); and

 a plurality of foldable solar panel arms (6), which are adapted to be extended in the longitudinal direction of each of the rail tracks (4a, 4b) open containers (5) when building the roof structure on the rail tracks (4a; 4b).

19. Kit of a roof construction according to claim 18,

 characterized by the plurality of containers (5) which can be positioned directly next to one another in a transverse direction in a transverse direction.