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WO2019058149A1 - Élément de couverture de toit pourvu d'un module de cellules solaires - Google Patents

Élément de couverture de toit pourvu d'un module de cellules solaires Download PDF

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Publication number
WO2019058149A1
WO2019058149A1 PCT/HU2018/000011 HU2018000011W WO2019058149A1 WO 2019058149 A1 WO2019058149 A1 WO 2019058149A1 HU 2018000011 W HU2018000011 W HU 2018000011W WO 2019058149 A1 WO2019058149 A1 WO 2019058149A1
Authority
WO
WIPO (PCT)
Prior art keywords
solar cells
tile
roof covering
electric connection
solar cell
Prior art date
Application number
PCT/HU2018/000011
Other languages
English (en)
Inventor
Attila GÓDI
Original Assignee
Godi Attila
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Godi Attila filed Critical Godi Attila
Priority to ATGM9005/2018U priority Critical patent/AT17532U1/de
Priority to DE212018000327.0U priority patent/DE212018000327U1/de
Publication of WO2019058149A1 publication Critical patent/WO2019058149A1/fr

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Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02SGENERATION OF ELECTRIC POWER BY CONVERSION OF INFRARED RADIATION, VISIBLE LIGHT OR ULTRAVIOLET LIGHT, e.g. USING PHOTOVOLTAIC [PV] MODULES
    • H02S20/00Supporting structures for PV modules
    • H02S20/20Supporting structures directly fixed to an immovable object
    • H02S20/22Supporting structures directly fixed to an immovable object specially adapted for buildings
    • H02S20/23Supporting structures directly fixed to an immovable object specially adapted for buildings specially adapted for roof structures
    • H02S20/25Roof tile elements
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/10Photovoltaic [PV]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy

Definitions

  • the invention relates to a roof covering element having a solar cell module.
  • each roof covering element comprises a separate solar cell module
  • a (roof) tile comprising a solar cell wherein the tile is specifically configured for receiving the solar cell module.
  • a recessed receiving portion that has dimensions exactly corresponding to the dimensions of the solar cell module is formed in the tile.
  • the electric connector is arranged on the side of the solar cell module (prepared for installation) that is inserted into the receiving portion of the tile. Therefore, a groove adapted for receiving the connector is formed in the receiving portion; to provide for the appropriate arrangement of the device this groove has to be formed in the receiving portion such that, if the solar cell module is fitted against the edges of the receiving portion, the connector is exactly received in the groove.
  • the connector is led out to one of the tile's edges.
  • a (roof) tile provided with a solar cell is disclosed also wherein the tile prepared for receiving the solar cell module has a number of special configuration features to allow for receiving the solar cell.
  • the solar cell module is arranged also in a recessed receiving portion of the tile.
  • On the backside of the solar cell to be attached to the tile the electric connections are connected to a module located on the backside.
  • a respective recess for arranging the backside module and for the sideways passing of the connectors.
  • the (roof) tile shown in Figs. 15A-15B of US 6,294,724 B1 is recessed for receiving the solar cell module.
  • the illustrated solar cell module has an undulating shape, i.e. follows the shape of the tile.
  • the application of such a "shape following" solar cell module is described also in DE 29915196 U1. Although these "shape following" units can be applied with tiles having an undulating shape, their great disadvantage is that they are only capable of a much lower power output compared to flat panels.
  • the primary object of the invention is to provide a roof covering element, which is free of disadvantages of prior art approaches to the greatest possible extent.
  • a further object of the invention is to provide a roof covering element having a solar cell module that has a relatively simple structure, so it can be manufactured efficiently and at relatively low cost, while at the same time it has a nearly identical electric power output in comparison to conventional approaches (i.e. which are mounted on a roof afterwards).
  • the roof covering element according to the invention can be manufactured in a simple manner, and is capable of being reproduced with identical results. With using the roof covering element according to the invention results in a more aesthetic roof surface compared to the application of large solar cell panels, while preserving the visual character of tile roofing. With the application of the roof covering element according to the invention there is no need for applying the support structures and solar cell frames applied with large solar cell panels. Furthermore, the application of the roof covering element according to the invention allows for various different roof shapes (for example, non-rectangular shapes), with better use of space compared to large solar panels.
  • the roof covering element according to the invention can be easily integrated into conventional tile systems, by way of example, concrete tile systems. The application of clay tiles is also conceivable, i.e.
  • the tile element of the roof covering element according to the invention can also be implemented as a clay tile. It is more preferable to apply concrete tiles because the generally used clay tile types are too thin for performing the function of a carrier tile (therefore it is conceivable that for such applications the generally used clay tiles should be made thicker). Concrete tiles can comply with the requirements of the standard EN 490 also together with the solar cell module placed thereon, while a different standard (EN 1304) is applicable for clay tiles, and most probable clay tiles together with a solar cell module mounted thereon comply with that standard only in case the widely applied thinned portions are not included in the clay tile.
  • the roof covering element according to the invention can be combined (and is interchangeable) with roof covering elements that have no solar cell modules mounted, and, of course have no wire pass- through openings.
  • roof covering elements that have no solar cell modules mounted, and, of course have no wire pass- through openings.
  • the roof covering element according to the invention can be attached to a roof shell preferably in a watertight manner, in many cases without the application of further tinned components.
  • the roof covering element according to the invention preferably has better electric efficiency, its power output deteriorates slower, and the solar cells are secured to the roofing tile more reliably. Furthermore, by including the roof covering element (solar tile) fitted with a solar cell module in a series or parallel-connected system - complying with the electric specifications - an electric network of an arbitrary voltage and current level can be provided. In the case of partial shading, the reduction in power output is smaller because a unit is preferably constituted by a single roof covering element.
  • the appropriate contacts are provided while applying a flat front surface.
  • the connector members and the wires leading up to them are situated in a covered space, under the roof shell, at a location protected from the environmental effects (rain, snow, UV radiation, wind, etc.) that - provided that a modern layer sequence is applied - is situated in a ventilated space between the roof foil and the tiles.
  • the heat transfer characteristics of the roof covering element according to the invention are more favourable in comparison to conventional tiles, i.e. the solution does not raise the inside temperature of the tile element (and thus the temperature of the loft space).
  • the application of the roof covering element according to the invention allows that any one of the roof covering elements (solar tiles) can be replaced individually in the case of a solar cell fault (or a diode fault).
  • the roof shell system produced applying the roof covering element according to the invention is preferably electrically insulated and provides a high IP rating.
  • the roof covering element according to the invention complies with the applicable standards, among others thanks to the fact that in the roof covering element according to the invention the solar cell module is present as an additional component of the roof shell solution (the tile element of it is a conventional roofing tile of which the structure need not be modified).
  • Fig. 1 shows, in a spatial drawing, an embodiment of the roof covering element according to the invention from the direction of the front surface
  • Fig. 2 shows, in a spatial drawing, the embodiment of Fig. 1 from the direction of the back surface
  • Fig. 3 shows the embodiment of Fig. 1 from the direction of the back surface
  • Fig. 4 is a view depicting the embodiment of Fig. 1 .
  • Fig. 5 is a front view of the embodiment shown in Fig. 1 .
  • Fig. 6 is a top view of the embodiment of Fig. .
  • Fig. 7 is a spatial drawing of a further embodiment of the roof covering element according to the invention, showing the roof covering element from the direction of the back surface, Fig. 8 shows the embodiment of Fig. 7 from the direction of the front surface,
  • Fig. 9 shows the embodiment of Fig. 7 in a sectional side view taken along the line A-A of Fig. 8,
  • Fig. 10 is a front view of the embodiment of Fig. 7, not showing the wiring and the electric connector unit,
  • Fig. 1 1 is the side view of a unit that is applicable to the tile element as shown in Fig. 7, and
  • Fig. 12 is a rear view of the unit shown in Fig. 11. MODES FOR CARRYING OUT THE INVENTION
  • the roof covering element comprises a tile element 10, a solar cell module (photovoltaic module, it can also be called a solar cell arrangement or photovoltaic arrangement) connected (mounted) to a front surface 19 of the tile element 10, the front surface 19 facing outwards in case of built-in tile element 10, and an electric connection arrangement connected to the solar cell module; in the embodiment shown in Fig 1 the electric connection arrangement is connected to the solar cell module through the tile element 10 (for another exemplary possibility for connection see Figs. 7-12).
  • a solar cell module photovoltaic module, it can also be called a solar cell arrangement or photovoltaic arrangement
  • the tile element 10 is for example a concrete tile (roof tile) but can also be a clay tile (roof tile). Since according to the invention, the tile is modified only to a minimal extent (pass- through openings are formed for the interconnections of the solar cell module and the electric connection arrangement, or for example, an indentation is made in one edge, e.g. the upper edge, of the tile, see Fig. 7), the breaking strength of the applied tile is not essentially smaller than the breaking strength of conventional tiles, e.g. concrete tiles. The tile also remains as watertight as it was before the modifications, and thus it conforms to the standard EN 490.
  • the solar cell module comprises (preferably flat) solar cells 12a, 12b, 12c, 12d being connected in series
  • the electric connection arrangement comprises a first electric connection module 14a (unit) and a second electric connection module 14b (unit), each connected to a respective extreme (extreme-position, outer, outward) solar cells of the solar cells being connected in series (in the embodiment of Fig. 1 these are preferably connected (mounted) to a back surface 21 of the tile element 10 situated opposite the front surface 19 thereof), and the front surface 19 of the tile element 10 being of flat configuration at least partially, and the solar cells 12a, 12b, 12c, 12d being connected to a part of the front surface 19 having flat configuration.
  • the solar cell module (solar module, solar unit) comprises further subassemblies, i.e. solar cells.
  • the solar cell is an independent (self-contained) unit that is capable of generating electricity when irradiated by light based on the operating principle of the crystal forming it and thanks to the electrodes arranged thereon.
  • the manufacturing method and the configuration of the solar cell module mounted on the tile element is presented in relation to an exemplary case wherein the solar cell module is made from the solar cells by lamination.
  • the tile element 10 and the solar cells 12a, 12b, 12c, 12d are connected to each other over a large surface area (this also holds true for the embodiment according to Figs.
  • the solar cell can transfer heat to the tile element over a large surface area, while the air in the ventilated air gap between the tile and the foil located behind it in the mounted state behaves as a high- volume cooling medium for the tile.
  • the solar cells are not heated more than conventional solar arrays, so their power output is reduced to a lesser extent (the more a solar cell module is heated up the more its power output deteriorates).
  • the flat backside of the solar cell is preferably placed on the flat portion of the front surface of the tile element, providing that they are in contact over the largest possible surface area.
  • the invention can be realized applying any number of series-connected solar cells considering to the electric specifications, i.e. not only with the four solar cells applied in the illustrated embodiments.
  • the term "electric connection arrangement" refers collectively to all electric connection modules, components, etc., i.e. it is a collective term for these.
  • the electric connection arrangement comprises a(n) (first and second) electric connection module.
  • connection modules 14a, 14b can be configured in a manner different from the illustrated electric connection modules 14a, 14b (wherein both units comprise a connection cable and a connector member at its end), for example such that one of them has a configuration similar to the electric connection modules 14a, 14b (having a connection cable/solar cable), while the other has, for example, a connector member secured directly onto the back surface of the tile element. It is possible to connect the connector member of the cable connector unit of the adjacent roof covering element to the electric connection module configured this way, i.e. applying a connector member. In relation to this see also Figs. 7-12.
  • the tile element 10 has a natural, obvious orientation (most tiles may only be built in according to a single orientation). Thereby the tile element 10 also has a well- defined front surface that is situated at the outside when it is built in, and the solar cells 12a, 12b, 12c, 12d are arranged over this surface according to the invention.
  • the solar cells 12a, 12b, 12c, 12d preferably have a square shape (see Fig. 5), in Fig. 1 they are illustrated in a slightly perspective view.
  • the back surface of tiles can have a number of different configurations; in case of the tile element 10 two support elements 22 (mounting tabs, holding members) are formed on its back surface 21 (see e.g. Fig.
  • a number of different grooves and support surfaces are usually formed in the back surface of a tile (an exemplary configuration of the back surface is illustrated in Fig. 7, a similar configuration can be applied also for the embodiment of Figs. 1 -6).
  • the tile element 10 When the tile element 10 is installed, the two support elements 22 are supported on the tile batten. It is not necessary to provide the tile element applied in the invention with a coating either on the front or on the back surface (side); as adhesive is applied to the front surface for attaching the solar cells (the sides and the water groove can be coated).
  • tile element 10 (and other similar tile elements) is also clear.
  • a fundamental feature of tiles is that they have to be built in in an overlapping manner, i.e. the tiles in any particular row are arranged to overlap the tiles in the row below, that is, the higher-situated tiles slightly cover the ones situated below them.
  • the degree of the overlap depends on the roof inclination angle: the lower the inclination angle, the larger the overlap. Accordingly, the front surface of the tile element will have a portion that will be covered by the corresponding tile in the next row.
  • this overlap region is located in the upper part (as defined by the "natural" orientation of the tile built in the roof plane) of the front surface of any given tile element (see also further below), the height of the overlap region being, provided that the tile element is held in the "natural" upright orientation, is approximately 20-45%, preferably approximately 25-40% of the height of the front surface of the tile element.
  • the roof covering element comprises, arranged in a first row and in a second row, two solar cells in each row (a first and second solar cell 12a and 12b in the row that can be called the "upper row” according to the orientation of the tile element, and a third and a fourth solar cell 12c and 12d in the row that can be termed the "bottom row”).
  • the two-row solar cell module comprises exactly four solar cells (in a two-by-two arrangement).
  • the solar cells 12a, 12b, 12c are arranged in the lower part of the front surface 19 of the tile element 10 (according to the "natural" orientation).
  • the solar cell module comprises more or less than four solar cells
  • the configuration with four solar cells is particularly preferable.
  • the solar cells 12a, 12b in the first row are connected in series with the respective adjacent solar cells 12c, 12d in the second row (it is shown in Fig. 1 that the solar cell 12a is connected in series with the solar cell 12c, and also solar cell 12b with solar cell 12d), the solar cells 12c, 12d of the second row are connected in series with one another, and (as shown in Fig.
  • the solar cells 2c and 12d are connected in series by means of a wire element 17b), and the solar cells 2a, 12b of the first row (i.e. extreme solar cells of the series connection) are connected to the first electric connection module 14a and to the a second electric connection module 14b, respectively.
  • Electrodes 13 passed (in a direction parallel with the edge of the solar cells) through the solar cells that are implemented utilizing silicon monocrystals or polycrystals.
  • the electrodes 13 also run parallel with the longitudinal side of the tile element 10 and of the front surface thereof (as with the electrodes 33 according to Fig. 8 that run parallel with the longitudinal side of the tile element 30).
  • the longitudinal side of the tile element is the side (edge) which extends vertically when the tile element is set in its natural orientation (there are two such sides or edges, typically these are the longer sides of the tile element; the sides extending horizontally in this orientation are typically the shorter sides that are perpendicular to the longitudinal sides), this side of the tile element is perpendicular to the tile batten applied therewith.
  • the ends of the electrodes 13 are passed outside the cell, these ends are called “connection ends” (or “electrode connection ends”). These connection ends are interconnected between two adjacent solar cells (e.g. the solar cells 12a and 12c) to make the series connection.
  • connection ends are passed into the first (junction) and third (junction) wire elements 17a, 17c arranged beside the first (top) row of the solar cells (essentially vertically oriented thin connection ends run into the wire elements shown in a horizontal orientation in the figure) and into the second wire element 17b arranged beside the second (bottom) row.
  • the wire element 17b is adapted for making the series connection between the solar cells 12c and 12d of the bottom row, while the wire elements 17a and 17c are adapted for making connection to the electric connection modules 14a and 14b, respectively (see below for more details).
  • the wire elements 17a and 17c are of course not interconnected at their adjacent ends but a bypass diode 15, the functionality of which is presented below, is connected to these ends.
  • connection ends adapted for connecting the solar cells 12a, 12b, 12c, 12d to one another, to the first electric connection module 14a and to the second electric connection module 14b are arranged on the sides of the solar cells 12a, 12b, 12c, 12d that are perpendicular to its plane.
  • the connection ends are preferably of the same configuration also in the embodiment according to Figs. 7-12. Certain connection ends may also be arranged in an alternative manner. It is also shown in Fig. 1 that in this embodiment the flat portion of the front surface 19 of the tile element 10, i.e.
  • the flat portion covered by the solar cells 12a, 12b, 12c, 12d has a rectangle (or optionally, preferably to a good approximation, square) shape.
  • the entire front surface 19 is of rectangle shape and has flat configuration. Accordingly, the part of the front surface 19 of the tile element 10 having flat configuration and being covered by solar cells 12a-12d has mutually parallel straight longitudinal edges on opposite sides thereof (this also holds true for the embodiment according to Figs. 7-12; in the natural orientation of the tile element those edges/sides are called the longitudinal edges/sides that connect the upper and bottom edges).
  • Fig. 7-12 in the natural orientation of the tile element those edges/sides are called the longitudinal edges/sides that connect the upper and bottom edges.
  • a first grooved connection portion 20a and a second grooved connection portion 20b are arranged along the longitudinal sides of the tile element 10, i.e. along the sides interconnecting with the sidewise neighbour of the tile element 10 supported by the same tile batten (the front-facing grooved connection portion 20a is considered not to form part of the front surface).
  • the front surface, or the corresponding portion thereof is rectangular in an embodiment.
  • the rectangle shaped surface thus produced is particularly well suited for arranging solar cells thanks also to the fact that solar cells typically have rectangle or in special cases, square shape (or rectangle-like/square-like shape, see below), and thus can be preferably arranged over a rectangle shaped surface. None of the conventional approaches presented in the introduction applies for connecting the solar cell module a rectangle shape, flat (plane) surface lying in the same plane as the front side of the tile element.
  • the application of a tile element with such a large flat surface is also preferable from the aspect of manufacturing technology, because the flat solar cells can be efficiently attached to it, e.g. by adhesive bonding (applying for example a two-component epoxy adhesive).
  • the prefabricated solar cell module (solar cell panel) is attached to the tile element by an intact, completely continuous adhesive bond, the bond running along and around the sides of the solar cell modules lying perpendicular to the flat surface, sealing these edges as well. Thereby it is ensured that moisture cannot enter the space between the two layers (i.e. the solar cells and the front surface of the tile element). The danger of frost damage can thus be avoided.
  • the front surface of the tile element is completely smooth and flat, at least over a part thereof (disregarding naturally occurring surface irregularities; a water groove is optionally also included at the lower edge of the tile element).
  • the flat front portion of the tile element is completely covered by the solar glass that is applied for making the solar cell module from the solar cells.
  • a glass plate 24 is arranged on the front surface of the tile element 10.
  • the applied glass plate is transparent such that the Sun's rays can reach the solar cells. Both tinted and non-tinted glass can be applied. Therefore, a solar glass covering also the so-called overlap region in addition to the solar cells is preferably applied for the solar cells.
  • the overlap region is that part of the flat front surface of the tile element over which no solar cells are arranged (see below in more detail).
  • the lamination layer realized utilizing the preferably applied inner foil, described in detail later on, covers the entire side of the glass plate facing the tile element.
  • the cells and their accompanying wiring are preferably very thin and are arranged between the lamination and the glass plate.
  • the solar cell module thus obtained has a uniform thickness; in the regions with no cells or wiring the small volume remaining there between the lamination and the glass plate is filled up by the applied adhesive.
  • this solution makes manufacturing easier and facilitates waterproofing. If the solar glass covered only the region covered by the solar cells, then, because of the stepped surface shape, a so-called water barrier could be produced between the edges of the overlap region and the region covered by solar cells In a disadvantageous manner, the water barrier could be the starting location of a water intrusion or frost damage.
  • a uniform- thickness covering is formed by the solar glass on the front surface which is covered by it in its entirety.
  • Tiles with such a large flat surface is not widely applied, however this configuration has the advantage that the roof covering element fitted with a solar cell module according to the invention preserves its character as a tile and yet it is particularly preferably suitable for the attachment (connection) of the solar cells thereto.
  • the solar cells are arranged at a distance of 0.1-0.5 cm from one another, and at a distance of 0.2-2 cm, preferably 0.5-2 cm, from the longitudinal edges of the flat portion of the front surface 19 of the tile element 10.
  • An arrangement with proportionally identical dimensioning is shown also in Fig. 1 , and in the embodiment of Figs. 7-12. With such an arrangement the solar cells are arranged as close to one another as possible, i.e. the smallest possible place is used.
  • the solar cell modules are typically manufactured in the following manner. First, thin slices (wafers) are cut from the appropriate crystalline base material (e.g. silicon or other monocrystal or polycrystal) that is typically bar-shaped. Then, etchings adapted to receive the electrodes (cf. Fig. 1 , electrodes 13) are made in the slices, and the electrodes, which are made for example of tinned copper strip wire, are soldered (by way of example, applying tin solder) into these etchings (recesses) to produce a solar cell. A plate that is typically made of glass (e.g. low-iron content glass) or a polymer material is then placed over the outside face of the sidewise arranged solar cells.
  • crystalline base material e.g. silicon or other monocrystal or polycrystal
  • a foil e.g. Tedlar foil
  • Tedlar foil is applied to the inside face of the crystals of mutually corresponding solar cells.
  • a transparent foil a so-called laminating foil made e.g. of EVA (ethyl vinyl acetate) which is adapted to melt under heat, functioning as an adhesive
  • laminating foil made e.g. of EVA (ethyl vinyl acetate) which is adapted to melt under heat, functioning as an adhesive
  • the solar cell module is being made (i.e. when it is subjected to heating in case of lamination).
  • the side lengths of the crystal can be chosen arbitrarily, so the size of the solar cells can be freely chosen corresponding to the flat surface of the tile, and a solar cell module of the desired size can be made carrying out the above described steps. Rectangle, rectangle-like, square or square-like cells with arbitrary side lengths may be applied. Accordingly, in an embodiment of the roof covering element according to the invention the solar cells have square or square-like or rectangle or rectangle-like shape.
  • the length of the sides of the solar cells is preferably approximately between 120 mm and 160 mm, so their sides can be approximately 130 mm (5 inches) or 156 mm (6 inches) long, or particularly their side length can be between 130 mm and 156 mm.
  • the side length of the cells is preferably in this range and, if solar cells with a rectangle or rectangle-like shape are applied (as shown in Fig. 8), the two different side length values are in this range.
  • the solar cells made of an appropriate crystalline material
  • the inner foil laminated on the inside face (i.e. the side facing the tile element) of all the solar cells arranged on a tile element, and the (solar) glass laminated onto their outside surface are collectively called a solar cell module.
  • the solar cell module, and therefore the solar cells are connected (e.g.
  • the solar cell module further comprises a glass plate (preferably a solar glass plate) covering the entire flat portion of the front surface and the solar cells (in addition to that, the entire flat portion is also covered and bounded by the laminated inner foil).
  • a glass plate preferably a solar glass plate
  • the solar cells and the glass plate are kept together by a lamination applied to them, with the resulting laminated unit being attached to the flat front portion of the tile element.
  • the Tedlar foil cannot perform the function of an adhesive (cannot keep together the components).
  • the dimensions of the glass plate (and the lamination under it), i.e. its height and width, are the same as the dimensions of the flat portion (with a rectangular configuration their length and width are the same). Therefore, in an example the preferred layer sequence is: solar glass, solar cell (with interconnecting wiring), EVA foil, Tedlar foil; the unit thus obtained is then adhesively bonded to the tile element.
  • the entire front surface of the tile element 10 has flat (plane) configuration (the grooved connection portions, for example the grooved connection portions 20a, 20b, are not comprised by the front surface).
  • the solar cell module preferably further comprises a glass plate 24 covering the front surface of the tile element 10 and the solar cells 12a-12d arranged on the front surface 19.
  • the solar cell module preferably further comprises an inner foil being laminated onto the glass plate 24 along the side of the glass plate 24 facing the front surface, covering the solar cells 12a, 12b, 12c, 12d, and the solar cell module is connected to the front surface of the tile element 10 by means of (through) the inner foil (an analogous configuration is applied in the embodiment of Figs. 7-12).
  • An embodiment is also conceivable wherein the glass plate is mounted on the front surface of the tile element directly (without lamination), for example applying adhesive bonding such that the solar cells are located between the glass plate and the tile element, however, it is expedient to apply lamination (and thus an inner foil) in this structure, as described above.
  • Lamination provides electrical insulation between the solar cells, the wiring, and the surface of the tile element. ln addition to that, simpler solar cell modules wherein the solar cell module is formed by only a few (e.g. four) solar cells that are directly glued (or otherwise fixed) to the tile element are also conceivable.
  • a square-like (rectangle-like) shape it is meant that, when viewed straight on, the shape of the solar cell can be square (rectangle) or rounded/cut-corner square (rectangle).
  • This shape is produced as follows: the crystalline wafers for the solar cells are typically cut from a cylindrical crystal, followed by cutting these circular wafers into square-like or rectangle-like shapes for more efficient use of space.
  • the side length is defined in the same way, as the distance between the straight sections of mutually opposing sides.
  • a non-square number of solar cells is may not be arranged on a single tile with efficient use of space.
  • Nine of the above solar cells on a single tile would require so large a surface area with which it would be practically unfeasible to carry out the usual construction tasks.
  • With a tile having a rectangular front surface it is expedient to apply a square number of solar cells also because in such a case the overlap region can be left free of solar cells, the most preferable number of solar cells being four because a tile with a size appropriate for accommodating this number of cells can be easily produced.
  • the expedient number of such cells to be arranged on a single tile is also four; thus the roof covering element according to the invention can be advantageously applied even with standard-size tile elements.
  • a tile element 10 having a front surface area of 325 * 420 mm is applied in an exemplary embodiment.
  • the horizontal and vertical distance between the solar cells is 2.3 mm and 2.2 mm, respectively, with a zone with a width of 5.7 mm being left free on both sides between cells and the edge of the front surface.
  • the dimension of the overlap region measured perpendicular to the width direction of the tile is approximately 93-94 mm.
  • the connector units are passed out from the backside of the tile element at a distance of 1 13 mm from the upper edge, and at a distance of 1 15 and 83 mm of both longitudinal sides of the tile element.
  • the combined thickness of the tile element covered by the glass plate is 23 mm, of which 3 mm is the thickness of the glass covering.
  • an overlap region 23 being arranged beside the region covered by the solar cells 12a, 12b, 12c, 12d and allowing for placing the roof covering elements in an overlapping manner is arranged on the front surface 9 of the tile element 10 arrangement of the overlap region 23 is necessary for overlapping arrangement of the roof covering elements.
  • the size of this region can be adjusted for an ideal or a given application, or it can be adjusted based on the distance between the tile battens.
  • the covering tile element covers the entire overlap region, and thus, applying the system of roof covering elements provided by an embodiment of the invention it can be achieved that the combined surface area of the fully uncovered solar cells essentially reaches the combined area covered by the system of roof covering elements.
  • the conventional approaches do not intend to achieve this because therein various frame structures are arranged around the solar cell module, or the overlap region is completely left out of consideration. With the four solar cells, the surface area exposed to solar radiation of the roof covering element provides maximal use of space on each roofing tile.
  • the electric power output of the roof covering element according to the invention is only negligibly lower than (almost identical to) the output of the conventional solar panels.
  • This is provided in a particularly preferable manner if the surface area of the tile element not affected by inter-tile overlaps is essentially fully covered by the solar cells (e.g. by applying solar cells with a side length of 6 inches).
  • the first electric connection module 14a and the second electric connection module 14b are each connected to a respective extreme solar cell of the solar cells being connected in series by means of (through) a first pass-through wire element and a second pass-through wire element passing through the tile element 10, respectively.
  • the first pass-through wire element and the second pass-through wire element are passed through the tile element 10 in the overlap region 23.
  • the overlap region may preferably comprise the region where the wiring connected to the solar cells runs, because this region is not required to be exposed to sunlight.
  • the wiring gets through the tile element typically very close to the solar cells, somewhere near the boundary between the region covered by the solar cells and the overlap region, i.e.
  • the pass-through wire element is passed through the tile element 10 between the region covered by the solar cells 12a, 12b, 12c, 12d and the overlap region 23.
  • an approach may be applied according to which the wire elements 17a, 17c form a part of the pass-through wire element.
  • the wire elements 17a, 17c are connected to the extreme ones of the solar cells 12a, 12b, 12c, 12d (i.e. the solar cells 12a and 12b), their other ends is connected to another wire element section that is passed through the tile element 10 and connect the wire elements 17a, 17c to the electric connection modules 14a, 14b, respectively, that form a part of the electric connection arrangement.
  • the (branching) wire elements 17a, 17c do not form a part of the pass-through wire element.
  • the pass-through wire element is a non-branching (straight) wire, with one of its ends being connected to the corresponding electric connection module typically at the cable bushing (in general, at the insulating-mounting element), the other end being connected either to the (branching, junction) wire element 17a, 17c (this latter wire element is a branching one, as illustrated in the figures), or, if a branching is not required, directly to the corresponding solar cell.
  • the pass- through wire element - and, if necessary, the branching wire element implemented either as a part thereof or separately - therefore extend(s) from the above described connection ends hanging out from the solar cells to the electric connection modules.
  • the roof covering element comprises a bypass diode 15 connected in parallel with the solar cells 12a, 12b, 12c, 12d being connected in series.
  • the bypass diode protects the solar cell module of respective roof covering elements from excess current (and from overheating) that may occur in the event of the module being shaded.
  • Inclusion of the bypass diode 15 can also provide protection against such a failure of the solar cell module (or a cell thereof) wherein the faulty cell essentially operates as a load.
  • the module In case the solar cell module is locally shaded, the module can be overloaded and heated up (due to the current flowing through it). As a result of this, the voltage of the shaded solar cell module is reversed and the solar cell module can be damaged under the effect of the high reverse (closing direction) voltage. Therefore, in order to protect the solar cell modules of shaded roof covering elements a bypass diode, connected in parallel with the solar cell module, can be included. If the polarity of the solar cell module is reversed due to partial shading, the bypass diode becomes forward biased (being of opening direction) and so current flows through it.
  • the interconnected system of roof covering elements according to the invention can be prevented from becoming inoperable due to one (or more) locally shaded or faulty roof covering element(s). Therefore, the system with such a configuration can be operated even until the faulty roof covering element is replaced with a functioning one. Accordingly, applying this embodiment of the invention an extremely efficient system can be made that is resistant against potential failures.
  • the system can of course comprise standalone tiles that do not have a solar cell module arranged on them.
  • Fig. 2 the embodiment shown in Fig. 1 is depicted in a spatial rear view.
  • the support elements 22 protrusions
  • Fig. 2 there is also shown how the electric connection modules 14a, 14b are connected to the back surface 21 of the tile element 10 in this embodiment. It is shown that in this embodiment the first electric connection module 14a and the second electric connection module 14b are connected to the back surface 21 of the tile element 10 by means of cable bushings 18a, 18b.
  • other insulating-mounting element e.g.
  • first electric connection module and/or the second electric connection module is mounted onto the back surface of the tile element by means of (through) an insulating-mounting element.
  • Attaching the electric connection module (cable) applying an adhesively bonded cable bushing provides electric insulation, high IP rating and mechanical attachment.
  • an electric connector box connection unit
  • the cable bushings are arranged on the backside in two openings (having a size of, for example, 25 mm) arranged on the tile element by filling up the openings with resin, the openings being adapted for passing the wires through to the cable bushing.
  • the electric connection modules 14a, 14b can be standard cables routinely applied in solar systems, while the connector members 16a, 16b can be for example standard MC4-type solar connectors that are protected against slipping apart and have high IP rating (IP65). It is not absolutely necessary to achieve so high an IP rating because after installation the connector will not be located outdoors. It is more preferable to apply this or other type of connector member compared to conventional solar cell roof covering elements wherein the connector member adapted for interconnecting adjacent roof covering elements is arranged at the side of each roof covering element facing the next one. This contact usually gets dirty in a short time, so it does not provide appropriate connection (the connector element of the embodiment of Figs. 7-12 is also arranged in a covered manner, i.e. not arranged outdoors).
  • IP65 IP rating
  • the distance between the electric connection modules 14a, 14b is therefore shown to be relatively large in Fig. 2 only for better comprehension.
  • the wire element can also be passed through the tile element 10 obliquely, in which case such a distance can be achieved but it is not expedient.
  • the electric connection modules 14a, 14b are therefore in most cases located (and attached to the back surface 21 of the tile element 10) much closer to each other.
  • the distances between the cable bushings 18a, 18b and the support elements 22 are illustrated at real proportions in Fig. 2. Since the side length of the illustrated solar cells 12a, 12b, 12c, 12d is, by way of example, approximately (to a good approximation, i.e.
  • Fig. 3 the tile element 10 is shown in a rear view (the support elements 22 are shown in more detail).
  • the first and second connector members 16a, 16b, also illustrated in the previous drawings, are clearly shown in Fig. 3.
  • the grooved connection portion 20b adapted for being connected to the grooved connection portion 20a of an adjacent roof covering element is also shown. Thanks to the grooved configuration, the roof covering element in itself provides a fully watertight covering (watertightness is also a feature of the completed roof shell, not only of the individual roof covering elements). In addition to that, the roof covering element is also protected against storms, i.e. has wind uplift protection preferably without being secured by screws or storm clamps thanks to its own weight.
  • Fig. 4 the embodiment of Fig. 1 is shown in side view. In Fig. 4 it is shown to what extent the support elements 22 protrude from the plane of the backside of the tile (to the extent that is usual with other tile types). In addition to that, the electric connection module 14a protruding from the back surface 21 and the glass plate 24 arranged over the front side is also shown.
  • Figs. 5 and 6 the embodiment of Fig. 1 of the roof covering element is shown in front and top plan view, respectively.
  • Fig. 5 it is illustrated that, in contrast to a number of conventional approaches, in this embodiment of the invention the solar cells are attached to the tile independently, without a frame structure.
  • the glass plate 24 is also shown in Fig. 6. This also allows for the application of the simple wiring utilized in the illustrated embodiment of the invention.
  • Figs. 7-12 a further embodiment of the roof covering element according to the invention is illustrated.
  • the following components are also comprised in this embodiment of the roof covering element (it may have other features introduced above with which it is compatible).
  • the roof covering element comprises a tile element 30, a solar cell module connected to a front surface 39 of the tile element 30 facing outwards in case of built-in tile element 30, and an electric connection arrangement connected to the solar cell module.
  • the solar cell module comprises first, second, third, and fourth solar cells 32a, 32b, 32c, 32d being connected in series
  • the electric connection arrangement comprises a first electric connection module 34a and a second electric connection module 34b, each connected to a respective extreme solar cell of the solar cells connected in series
  • the front surface 39 of the tile element 30 being of flat configuration at least partially, the solar cells 32a-32d being connected to a part of the front surface 39 having flat configuration.
  • the entire front surface of the tile element 30 has flat configuration; in the illustrated embodiment an indentation 45 adapted for receiving a preferably applied electric connector unit 31 (electric junction unit) protrudes into the flat front surface.
  • first electric connection module 34a and the second electric connection module 34b are each connected to a respective extreme solar cell of the solar cells being connected in series by means of (through) a first interconnection wire element and a second interconnection wire element that being arranged along the front surface 39 of the tile element 30 (for a first interconnection wire element 48a and a second interconnection wire element 48b see Fig. 8).
  • the connections between the first electric connection module 34a, the second electric connection module 34b and the corresponding solar cells are provided by the interconnection wire elements that are run along the front surface 39 of the tile element 30.
  • the interconnection wire elements that are run along the front surface 39 of the tile element 30.
  • flat wires for example, the ribbon (band) wires shown also in Fig. 8, as interconnection wire elements and as wire elements 37a- 37c.
  • the interconnection wire element runs between the tile element and the glass plate secured to its front surface (provided with lamination), which is another reason why ribbon wires are expedient.
  • a distinction is made between the interconnection wire element and the (branching) wire elements 37a, 37c.
  • the interconnection wire element is a non-branching (single) wire, with one of its ends being connected to the corresponding electric connection module (at the electric connector unit or directly), the other end being connected either to the (branching) wire element 37a, 37c (this latter wire element is a branching one, as illustrated in the figures), or, if a branching is not required, directly to the corresponding solar cell.
  • the interconnection wire element - and, if required, the branching wire element - therefore extends from the above described connection ends hanging out from the solar cells 32a-32d to the electric connection modules.
  • the first electric connection module 34a and the second electric connection module 34b are connected to the first interconnection wire element 48a and the second interconnection wire element 48b, respectively, by means of (through) an electric connector unit 31.
  • an indentation 45 (notch, cut, recess) is formed along the edge (side) of the front surface 39 of the tile element 30, and the electric connector unit 31 (or, to use another term - also used to refer to the element providing connection applied in the configuration according to Figs. 7-12 - an electric connector [junction] box) is arranged in the indentation 45.
  • the indentation 45 is formed in the overlap region 43.
  • the connection point connection unit
  • the electric connector unit 31 is not visible even if a non-transparent lamination foil is not applied.
  • the indentation 45 is formed in the edge of the overlap region 43 being opposite the solar cells 32a-32d; it is thus arranged in the most protected place.
  • the overlap region is formed beside the region covered by the solar cells, i.e. its side lying opposite the solar cells is the side of the tile element located at the top in the figures (covered by the adjacent overlapping tile).
  • the indentation is most expediently formed here.
  • the first electric connection module 34a and the second electric connection module 34b applied in the embodiment of Figs. 7-12 are therefore each connected to a respective extreme solar cell of the solar cells being connected in series by means of the electric connector unit 31 (see Fig. 8).
  • the basic function of the electric connector unit 31 is to provide electric connection (by means of wires) between the electric connection modules 34a, 34b and the solar cells of the solar cell module.
  • the features of the electric connector unit 31 are described in detail below.
  • a first connector member 36a and a second connector member 36b is arranged at the free end of the electric connection module 34a and 34b, respectively.
  • the electric connection modules 34a, 34b have essentially the same configuration as the connector units 14a, 14b described above, but are connected to the wiring of the solar cell module in a different manner.
  • support elements 42 protrusions
  • Figs. 7 and 8 respectively, there are shown first and second grooved connection portions 40a, 40b being arranged along the longer sides of the tile element 30 and being configured in a similar manner as the grooved connection portions 20a and 20b (but in contrast to them do not extend all along the longer side of the tile element 30).
  • Fig. 7 shows a number of recesses, grooves, shapes and protrusions/thickenings (the latter defining the total thickness of the element) that are formed in the concrete tiles similar to the tile element 30 (usually clay tiles also have such features, but the ones shown in Fig. 7 are characteristic of concrete tiles): This is not relevant for the configuration details (solar cell module, connection arrangement, etc.) that are essential to the subject matter of the invention.
  • Fig. 8 shows the embodiment of Fig.
  • FIG. 8 there are shown solar cells 32a, 32b, 32c, 32d forming the solar cell module and being arranged on the front side of the tile element.
  • the solar cells 12a, 12b, 12c, 12d these are connected in series with each other (the solar cells 32a, 32b, 32c, 32d are connected one after the other, and the extreme solar cells 32a and 32b are directly connected to the connector units 34a, 34b); and first, second and third wire elements 37a, 37b and 37c are also arranged in an analogous manner with the wire elements 17a, 17b, 17c.
  • the solar cells 32a-32d are configured in a very similar way as the solar cells 12a- 12d. Unlike these, however, the solar cells 32a-32d do not have a square-like shape but a rectangular shape (their width dimension in the figure is greater than their height; for more information on that see the section below describing the exemplary dimensions). Accordingly, the corners of the solar cells 32a-32d are not cut off. Vertical electrodes 33 (or, in a technical term commonly used in the field, "bus bars”) as well as horizontal components extending perpendicular thereto (called “fingers” in the jargon of the field) can also be observed on these. Fig.
  • FIG. 8 is a front view showing certain components and the electric connector unit 31 located above the solar cells 32a-32d in dashed lines because they are obstructed from view in the illustrated embodiment (preferably by the foil laminated on the inside of the front glass plate fitted against the tile element 30).
  • Fig. 8 therefore it is shown that the arrangement of the indentation 45 adapted for receiving the electric connector unit 31 and the electric connector unit 31 itself inside the indentation 45.
  • the front surface 39 of the tile element 30 and the overlap region 43 that is situated at the top part of the front surface 39 (in the "natural" orientation of the tile) and is adapted to allow for laying the tile elements 30 on a roof in an overlapping manner are indicated.
  • Fig. 8 the front surface 39 of the tile element 30 and the overlap region 43 that is situated at the top part of the front surface 39 (in the "natural" orientation of the tile) and is adapted to allow for laying the tile elements 30 on a roof in an overlapping manner are indicated. As illustrated in Fig.
  • the rectangular indentation 45 shaped to match the arrangement of the electric connector unit 31 protrudes into the overlap region 43. It therefore reduces only the surface area that is to be covered by another tile but does not reduce the useful surface area of the tile. Forming the indentation 45 for the purpose of receiving the electric connector unit 31 thus does not have any disadvantage.
  • the function performed by the electric connector unit 31 can also be comprehended based on Fig. 8.
  • the wire element 37a is arranged slightly further away from the solar cells 32a-32d than the wire element 37c (the function of the wire elements is not affected by this; in an example the wire elements are implemented as a 5-mm- wide strip [band] wire).
  • the wire element 37b is arranged in a similar manner as the wire element 17b.
  • Fig. 8 there is shown in dashed lines a first interconnection wire element 48a adapted for interconnecting the solar cell 32a and the electric connector unit 31 through the wire element 37a and a second interconnection wire element 48b adapted for interconnecting the solar cell 32b and the electric connector unit 31 through the wire element 37c that are both obstructed from view due to the application of the non-transparent foil, i.e. the electric connection between the solar cells 32a-32d and the electric connector unit 31 is illustrated. Due to being covered by the non-transparent foil these are not shown (not visible) in Fig. 10 that also shows a front view.
  • the wire elements 37a-37c are also arranged along the front face of the tile element (a foil may be inserted under them), and have preferably flat configuration. Accordingly, the electric connector unit 31 is adapted for providing that the interconnection wire elements 48a, 48b and the electric connection modules 34a, 34b are electrically connected.
  • Fig. 8 there is not separately shown a bypass diode that is connected between the wire elements 37a and 37c and is arranged in a manner analogous to the bypass diode 15. This is because the bypass diode is inserted between the two outputs in the electric connector unit 31.
  • Fig. 9 the roof covering element of Figs. 7-8 is shown in a side elevation sectional view.
  • the glass plate 44 adapted for covering the entire front surface (fitted with the solar cells 32a-32d) is shown, and the tile element 30 bearing the glass plate.
  • the section illustrated in Fig. 9 crosses the electric connector unit 31 (according to section A-A of Fig. 8), so the cross section of the unit can be seen behind the glass plate 44 in the top part of the figure.
  • the wiring i.e. the wire elements 37a, 37b, 37c and the interconnection wire elements 48a, 48b
  • the solar cells 32a-32d, and the lamination are located between the glass plate 44 and the tile element 30, these cannot be seen in side view.
  • the thickness of the applied solar cells is approx. 0.2 mm, so they cannot be seen in the figure because they are much thinner than the glass plate. Accordingly, the wiring is lead out from the solar cells 32a-32d (more accurately, from the extreme solar cells 32a and 32b) to the electric connector unit 31 between the glass plate 44 and the tile element 30.
  • Fig. 9 the support element 42 is also shown because it is not obstructed from view when the section is viewed from the appropriate direction.
  • Fig. 9 certain structural details of the tile element 30, i.e. grooves and recesses, are illustrated. As it was discussed in relation to Fig. 7, because they are formed/arranged on the backside of the tile element 30, these latter are not relevant for the arrangement of the solar cell module.
  • the electric connector unit 31 essentially does not protrude from the back surface of the tile element 30, so the installation of the roof covering element on a tile batten is not affected by the electric connector unit 31.
  • Fig. 10 an arrangement corresponding to the one shown in Fig.
  • the non-transparent foil that is laminated onto the backside of the solar cells preferably covers the entire front surface 39, so it obstructs the electric connector unit 31 from a front view (from the direction of the glass plate 44).
  • the non-transparent foil laminated onto the backside of the solar cells is located behind the wiring from the glass plate 44; in order to conceal the wiring (the wire elements 37a, 37b, 37c and the interconnection wire elements) either the foil (that is appropriately oversized) is folded back or separate, appropriately dimensioned pieces of non-transparent foil are inserted between the glass plate and the wiring.
  • a foil between the front surface of the tile element and the interconnection wire elements that are arranged along the front surface in the embodiment according to Figs. 7-12 (i.e. the inclusion of the foil does not change that the interconnection wire element is arranged along the front surface).
  • the wires in this case, the interconnection wire elements 48a, 48b
  • the wires are preferably passed through the foil (that is laminated onto the backside of the solar cells) near the electric connector unit 31.
  • a preferably non-transparent plastic foil for example Tedlar foil is applied (as the covering material), which can be preferably laminated onto the arrangement utilizing a laminating foil (e.g. EVA foil which also constitutes the adhesive material).
  • Wiring can be preferably concealed also in the embodiment according to claims 1-6.
  • the solar cells 32a-32d have a height of 124 mm and a width of 143 mm, i.e. they have a rectangle shape (unlike the solar cells 12a-12d of Fig. 1 the corners of the solar cells 12a-12d are not cut off).
  • the front side of the tile element (not counting the grooved connection portion 40a) has a width of 298 mm and a height of 420 mm, the solar cells 32a-32d being arranged at 2 mm from each other, i.e. the adjacent cells are spaced apart by this amount.
  • the solar cells 32a-32d are preferably arranged at a distance of 5 mm from the longitudinal edges of the front side, and at a distance of 10 mm from the lower edge (not counting the water groove).
  • the indentation adapted for receiving the electric connector unit 31 preferably has a rectangle shape, with a width of 72 mm and a length (i.e. the dimension taken along the longitudinal direction of the tile element 30) of 78 mm in the example.
  • the wire elements 37a and 37c preferably extend at a distance of 15 mm and 5 mm, respectively, from the solar cells 32a and 32b.
  • the grooved connection portions 40a protrude from the front surface to a distance of 32 mm, i.e. this is the width of their grooved connection surface.
  • the dimension of the overlap region is as measured perpendicular to the width direction of the tile is approximately 160 mm.
  • the thickness of the tile element 30 (measured in a region with no groove or recess) is 15.3 mm, the total thickness of the roof covering element measured at the same location is 22.3 mm, the thickness of the glass plate 44 (plus the thickness of the adhesive layer, if it has a relevant thickness) is 7 mm; the thickness of the electric connector unit 31 being approximately the same as the thickness of the tile element 30 that in the example is 15.8 mm.
  • the electric connector unit 31 is not placed symmetrically on the front surface 39 of the tile element 30, its centre line extending at 166 mm from the left edge of the tile element 30 as seen in the figure.
  • Figs. 1 1- 2 show a side and rear view, respectively, of the unit of the roof covering element that is applied to the tile element.
  • the illustrated unit comprises the laminated structure (laminated unit) wherein the solar cells 32a-32d and the wiring are laminated with the glass plate 44 (covered by a non-transparent inner foil at the side that will face the tile element 30), and the electric connector unit 31 is attached (e.g. by adhesive bonding) and electrically connected to the completed laminated unit and to the interconnection wire elements passed out therefrom.
  • the unit of Figs. 1 1-12 therefore further comprises the electric connector unit 31 (making up a laminated unit provided with the electric connector unit), as well as the electric connection modules 34a, 34b that are connected therein and is fitted with respective connector members 36a, 36b.
  • the connection of the electric connector unit 31 to the glass plate 44 is illustrated (in Fig. 12 it is shown that the electric connector unit 31 is attached to the backside of the glass plate), the unit thus obtained can preferably be attached (e.g. by adhesive bonding) as a single piece to the tile element 30.
  • the above described unit is shown in side view (which can also be a partial sectional view depending on the details shown).

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Roof Covering Using Slabs Or Stiff Sheets (AREA)
  • Photovoltaic Devices (AREA)

Abstract

L'invention concerne un élément de couverture de toit comprenant un élément de tuile (10), un module de cellules solaires relié à une surface avant (19) de l'élément de tuile (10), la surface avant (19) étant orientée vers l'extérieur dans le cas d'un élément de tuile intégré (10), et un agencement de connexion électrique connecté au module de cellules solaires, le module de cellules solaires comprenant des cellules solaires (12a-12d) connectées en série, l'agencement de connexion électrique comprenant un premier module de connexion électrique (14a) et un second module de connexion électrique (14b), chacun étant connecté à une cellule solaire extrême respective des cellules solaires connectées en série, et la surface avant (19) de l'élément de tuile (10) présentant une configuration plate au moins partiellement, et les cellules solaires (12a-12d) reliées à une partie de la surface avant (19) présentant une configuration plate.
PCT/HU2018/000011 2017-09-19 2018-03-19 Élément de couverture de toit pourvu d'un module de cellules solaires WO2019058149A1 (fr)

Priority Applications (2)

Application Number Priority Date Filing Date Title
ATGM9005/2018U AT17532U1 (de) 2017-09-19 2018-03-19 Dacheindeckungselement mit Solarzellenmodul
DE212018000327.0U DE212018000327U1 (de) 2017-09-19 2018-03-19 Mit einem Solarzellenmodul versehenes Dacheindeckungselement

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Application Number Priority Date Filing Date Title
HUU1700169 2017-09-19
HU1700169 2017-09-19

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WO2019058149A1 true WO2019058149A1 (fr) 2019-03-28

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DE (1) DE212018000327U1 (fr)
HU (1) HU5030U (fr)
WO (1) WO2019058149A1 (fr)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021048310A1 (fr) 2019-09-10 2021-03-18 Maguire Desmond Michael Tuile de toit

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN116065762A (zh) * 2022-10-26 2023-05-05 天合光能股份有限公司 光伏瓦及具有坡度的光伏屋顶

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1010429B (de) 1953-01-12 1957-06-13 Maerklin & Cie Gmbh Geb Tauchankerelektromagnet zum Betaetigen von Stellgliedern bei Spielzeugen und Modellen mit mehrteiligem Anker
DE2818474A1 (de) * 1978-04-27 1979-10-31 Bauer Geb Koerzdorfer Ingeborg Dachabdeckung, sowie dazugehoerige anlage bzw. anordnung
JPS609642B2 (ja) 1977-07-13 1985-03-12 株式会社東芝 避雷器
DE29610674U1 (de) 1996-06-18 1996-10-02 Podlowski, Lars, Dr., 12203 Berlin Spezialdachziegel zur Umwandlung der einfallenden Solarstrahlung in elektrische Energie ("Solardachziegel") unter Beibehaltung der originären Funktion eines Dachziegels (z.B. Witterungsschutz)
DE29915196U1 (de) 1999-08-30 1999-12-09 Kuhn, Volkhart, 48683 Ahaus Dachpfanne mit Solarzelle
US6294724B1 (en) 1999-01-14 2001-09-25 Canon Kabushiki Kaisha Solar cell module and power generation apparatus
DE202004009677U1 (de) * 2004-06-14 2004-11-04 Hoseit, Winrich, Dr. Photovoltaik-System zur Dachintegration
DE202010016159U1 (de) * 2010-03-03 2011-03-31 Grosse, Bernd L., Guardamar Solardach- oder Solarfassaden-Konstruktion
EP2322738A1 (fr) * 2008-09-10 2011-05-18 Kaneka Corporation Module de cellules solaires et réseaux de cellules solaires
EP2442371A1 (fr) * 2010-10-15 2012-04-18 Wegaplast S.p.A. Structure de toiture pour bâtiments, en particulier des maisons, des pâtés de maisons et/ou des logements

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP3609642B2 (ja) 1998-06-18 2005-01-12 積水化学工業株式会社 太陽電池付屋根瓦
DE102009022732A1 (de) 2009-05-26 2010-12-02 Creative Solar Solutions Gmbh & Co.Kg Photovoltaischer Solardachstein

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1010429B (de) 1953-01-12 1957-06-13 Maerklin & Cie Gmbh Geb Tauchankerelektromagnet zum Betaetigen von Stellgliedern bei Spielzeugen und Modellen mit mehrteiligem Anker
JPS609642B2 (ja) 1977-07-13 1985-03-12 株式会社東芝 避雷器
DE2818474A1 (de) * 1978-04-27 1979-10-31 Bauer Geb Koerzdorfer Ingeborg Dachabdeckung, sowie dazugehoerige anlage bzw. anordnung
DE29610674U1 (de) 1996-06-18 1996-10-02 Podlowski, Lars, Dr., 12203 Berlin Spezialdachziegel zur Umwandlung der einfallenden Solarstrahlung in elektrische Energie ("Solardachziegel") unter Beibehaltung der originären Funktion eines Dachziegels (z.B. Witterungsschutz)
US6294724B1 (en) 1999-01-14 2001-09-25 Canon Kabushiki Kaisha Solar cell module and power generation apparatus
DE29915196U1 (de) 1999-08-30 1999-12-09 Kuhn, Volkhart, 48683 Ahaus Dachpfanne mit Solarzelle
DE202004009677U1 (de) * 2004-06-14 2004-11-04 Hoseit, Winrich, Dr. Photovoltaik-System zur Dachintegration
EP2322738A1 (fr) * 2008-09-10 2011-05-18 Kaneka Corporation Module de cellules solaires et réseaux de cellules solaires
DE202010016159U1 (de) * 2010-03-03 2011-03-31 Grosse, Bernd L., Guardamar Solardach- oder Solarfassaden-Konstruktion
EP2442371A1 (fr) * 2010-10-15 2012-04-18 Wegaplast S.p.A. Structure de toiture pour bâtiments, en particulier des maisons, des pâtés de maisons et/ou des logements

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021048310A1 (fr) 2019-09-10 2021-03-18 Maguire Desmond Michael Tuile de toit

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HU5030U (hu) 2019-07-29
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