BE1018016A3 - Solar panel for fixing on roof of building, has fastening elements including magnetic fastener to fix solar panel by magnetic attraction on roof, where solar panel is integrated into framework shaped support - Google Patents

Abstract

The panel has a fastening system for fixing the panel on a roof (2), where the fastening elements include a magnetic fastener (3b) to fix the solar panel by magnetic attraction on the roof, and the solar panel is integrated into a framework shaped support. An independent claim is also included for a roof comprising a row of tiles.

Description

SOLAR PANEL AND ROOF COVERING SUCH A SOLAR PANEL

INCLUDES

This invention relates to a solar panel provided with a mounting system with which it can be mounted on a roof construction.

This invention also relates to a roof covering comprising at least one solar panel according to the present invention.

At present, there are already several types of solar panels that are provided for mounting on roof constructions.

Generally, when mounting solar panels, play must be provided to prevent excessive voltages being built up in the solar panel.

On the one hand, there is a risk that the solar panel, when mounted, will be subject to excessive mechanical stress and may be damaged.

After mounting, on the other hand, there is a risk that due to a difference in expansion or contraction between the solar panel and the underlying structure to which the solar panel is attached, too large tensions occur in the solar panel.

For the different types of solar panels, there are firstly superstructure solar panels that are installed on top of an existing roof covering with a superstructure construction.

Such solar panels are usually installed with the help of special hooks, frames made of metal profiles and screws on top of existing roof coverings.

In a frequently used method of fixing, a frame made of metal profiles is attached to the existing roof covering using screws, after which the solar panel is attached to the frame with special hooks. By screwing the frame onto the existing roof covering, however, the watertightness of this existing roof covering is broken, so that there is a risk that water can penetrate through this roof covering. In addition, the clamps will often also not allow the desired play that is assumed when fixing solar panels, but instead clamp the solar panel and, in the event of tensions in the solar panel, actually cause damage to this solar panel.

In addition, there are also solar panels that are built into the roof surface. These are so-called BIPV systems (Building Integrated Photovoltaic Systems).

A first type of solar panels that are installed in the roof surface at least locally replaces the traditional roof covering and, for example, is mounted on top of a polypropylene substrate on tile battens of a roof construction using a frame made of metal profiles. This solar panel does not normally have the dimensions of a complete roof, so that the roof covering in addition to this solar panel with the underlying frame and the polypropylene substrate is further supplemented with traditional roof coverings. The fixing of the solar panel with the aid of a frame made of metal profiles has the same disadvantages as indicated above for a solar panel that is installed on top of an existing roof covering.

For a second type of solar panels that are installed in the roof surface, they are fitted with roof tiles in sunken sections.

For example, US 5,768,831, EP 0 547 285, CH 682 831 and DE 33 14 637 roof tiles are described in which at least one solar cell is integrated in a roof tile.

The disadvantage of such roof tiles with integrated solar cells, however, is that, even if solar cells of different roof tiles are interconnected to form a larger whole, a favorable energy efficiency can never be obtained, given the limited useful surface area of the solar cells per roof tile.

With the currently known solar cells, it is necessary to provide solar panels that at least extend over the surface of several roof tiles, in order to obtain a favorable energy efficiency.

DE 198 23 356 describes concrete roof tiles that are adapted to support solar panels that are larger than one roof tile. To this end, adapted left, right and middle roof tiles were developed to which solar panels can be attached.

Both of the mounting methods proposed in this patent document allow some play, so that the voltages occurring in the solar panel can be absorbed.

For fixing the solar panels, on the one hand fastening elements are proposed consisting of a first part that is attached to the solar panels and extends through the roof tiles and of a second part that is attached to this first part on the underside of the roof tiles.

During installation, however, the underside of the roof tiles is not readily accessible, making this fixing method very labor-intensive and time-consuming. In addition, the watertightness of the roof tiles is again broken, so that there is a risk that water can penetrate this roof covering.

On the other hand, for fixing the solar panels, it is proposed to stick holding elements to the roof tiles, in which the solar panels can be fixed. For example, retaining elements are suggested clip elements made of stainless spring steel.

Given the size of the solar panel, where several fixing points are required, and since a roof can never be made completely flat, this fixing with the help of clip elements from spring steel is also not easy to carry out.

The object of the present invention is therefore to provide solar panels which, both when mounted on top of existing roof coverings and when mounted as a BIPV system, are quicker and easier to attach and where excessive stresses cannot occur in this solar panel due to expansion or contraction.

This object of the present invention is achieved with a solar panel provided with a mounting system with which it can be mounted on a roof construction, wherein the mounting system comprises magnetic mounting means for fixing the solar panel to the roof construction through a magnetic attraction.

The magnetic fasteners provide a sufficient magnetic attraction between the solar panel and the roof surface to effect the fastening. These fastening means allow a displacement of the solar panel relative to the roof surface, so that a clearance is possible at the height of the fastening, whereby the changing dimensions of the solar panel can be absorbed somewhat upon expansion and contraction. This makes it possible to prevent excessive stresses in the solar panel due to expansion and contraction. The solar panel cannot get stuck by these fasteners either.

In places where the solar panel does not touch the roof surface, because the roof surface is not completely flat, such a fixing system can furthermore ensure a fixation as a result of the magnetic attraction between the solar panel and the roof surface.

Preferably, the fixing system according to the present invention comprises at least one set of two magnetically cooperating fixing elements, each set comprising a first fixing element, which is part of, or is attached to, the solar panel and a second fixing element which is provided to be mounted on the roof construction , while the first and the second mounting element are provided to be coupled as a result of a magnetic attraction.

In an advantageous embodiment of a solar panel according to the present invention, the fixing system also comprises mechanical fixing means for fixing the solar panel on a roof construction.

By providing the solar panel with a combination of mechanical fasteners and magnetic fasteners, on the one hand excessive stresses during expansion and contraction can be avoided with the aid of the magnetic fasteners, while on the other hand with the help of the mechanical fasteners a good and very reliable mechanical anchoring of the solar panel on the roof construction. Namely, if, for example, under extreme weather conditions, a strong gust of wind could briefly overcome the magnetic attraction, the solar panel could not come loose from the roof structure, thanks to the mechanical connection.

In a special embodiment of a solar panel according to the present invention, the solar panel is provided on the roof construction on the one hand by magnetic fastening means and on the other hand by an adhesive connection. A combination of adhesive connection, mechanical connection and magnetic connection can also be applied.

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This glue connection can also allow a relative displacement of the solar panel relative to the roof construction, so that this connection also helps to avoid stresses in the solar panel.

Such a fastening of the solar panel with magnetic fastening means on the one hand and a glue connection on the other that also allows a relative displacement of the solar panel relative to the roof construction, can be particularly advantageous where the solar panel is mounted on a roof construction where expansion or shrinkage occurs in all directions. the solar panel voltages can occur. This is, for example, the case when a solar panel is mounted on a roof covering comprising strips of zinc, the solar panel being mounted on top of one strip of zinc.

In a very advantageous and particularly handy embodiment of a solar panel according to the present invention, the magnetic fastening means on the one hand, and the mechanical fastening means and / or the glue joint on the other hand are provided on opposite edges of the solar panel.

The mechanical fastening means can be provided along an edge in which relatively little or no stresses will occur in the solar panel due to expansion or contraction. This can for instance be an edge which is provided for extending on the roof covering in a direction along which a mutual displacement of the roof covering units relative to each other is possible. An example of a roof covering which in this way allows a play in a certain direction is a roof covering made up of several rows of roof tiles, wherein the roof tiles of the same format are partially overlapping laterally, on a roof construction, but where these roof tiles can still be somewhat move relative to each other according to the direction of the row.

In this way, furthermore, when mounting the solar panel on a roof construction, first the mechanical fastening means can be fastened, after which, possibly after the provision of a second fastening element to the roof construction, the magnetic fastening can furthermore be effected automatically at the moment that the solar panel is placed in the position of use.

In a specific embodiment of a solar panel according to the present invention, the magnetic fastening means comprise a permanent magnet and a fastening element which is at least partially made of metal and which is provided for being mounted on the roof construction.

In a further preferred embodiment of a solar panel according to the present invention, it is integrated in a frame-shaped frame, wherein at least one element of the fixing means is incorporated in this frame of the solar panel.

This frame protects the solar panel and in particular its edges against weather influences, making it less likely to be damaged or damaged.

Fasteners provided in the frame are immediately available when installing the solar panels and cannot be lost.

In addition to fasteners, at least one of the electrical and / or electronic components of the solar panel can also be incorporated into the frame.

Such built-in electrical and / or electronic components will be damaged less quickly than if they have to be mounted separately from the solar panel. Moreover, the mounting of the solar panels is again simplified if as many parts as possible are provided in one frame and no longer have to be mounted separately.

When the diode of the solar panel is incorporated into this frame in a judicious manner, it is also avoided that the diode is placed too close to the wooden structural elements of a roof covering. This is desirable because of the risk of fire, since it was already possible to establish several times that a fire started in the wooden roof construction elements as a result of the heat from the diode of a solar panel.

Preferably, said frame is a PU frame. At least one element of the fastening system is furthermore preferably incorporated into the PU frame via reaction injection molding.

Solar panels have the disadvantage that they are highly subject to weather influences, so that they can easily be damaged. It often happens that existing solar panels have too short a lifespan, so that they cannot achieve the desired energy efficiency.

A PU frame that is provided via reaction injection molding connects directly to the various components and will therefore be able to optimally shield them from possible weather influences.

A particularly advantageous embodiment of a solar panel according to the present invention is provided for being included in a roof covering comprising roof covering. This solar panel is herein preferably provided for connecting via one or more transition elements to one or more roof tiles of the roof covering.

A further practical embodiment of a solar panel according to the present invention has a substantially rectangular or square shape with a height that substantially corresponds to the height of a row of roof tiles of the roof covering.

With such solar panels, stresses occurring in the solar panel in the longitudinal direction of the row of roof tiles will be absorbed by displacement of these roof tiles relative to each other. Namely, the arrangement of roof tiles on a roof, whereby they partially overlap each other, permits a displacement of the roof tiles relative to each other along the longitudinal direction of the row. In the transverse direction of the row, the fastening means of the solar panels according to the present invention can allow the required clearance to absorb these stresses.

The object of the invention is further achieved with a roof covering comprising at least one solar panel according to the present invention.

When a solar panel is hereby placed on top of an existing roof covering in order to arrive at a roof covering according to the invention, a roof covering is obtained in which the existing roof covering further ensures good watertightness of the house and good energetic properties for the house, so that the solar panel for this purpose not have to be adjusted. When attaching the solar panel, care should only be taken that the existing roof covering is not damaged, as a result of which the functions mentioned are no longer assured.

This existing roof covering also forms a buffer between wooden structural elements of a roof and the diode of the solar panel, whereby ignition of these wooden structural elements, as a result of the heat released by the diode, is avoided.

A roof covering according to the present invention comprises in particular roof tiles.

This roof covering preferably comprises at least one row of roof tiles, between which at least two support elements with the same height and width as these roof tiles are arranged, which together define a sunken zone relative to the roof tiles, and in which the solar panel is accommodated.

In this way, the solar panels can be integrated into the roof surface itself as a BIPV system, making them less susceptible to weather influences and therefore less vulnerable.

In addition, such a roof covering, with solar panels lying in the roof surface, is often considered more aesthetic. In the case of solar panels which are mounted on top of an existing roof covering with a superstructure construction, such a superstructure construction can lead to a refusal of a building application, because the aesthetic appearance of a superstructure construction on top of an existing roof covering is not desired from an urban point of view.

Even more preferably, the sunken zone is defined by support elements of a first thickness, which are arranged in a row of roof tiles with a second thickness, wherein at least one end of the sunken zone in the same row of roof tiles a transition element with substantially the same height and width as said roof tiles is provided between a support element with a first thickness and a roof tile with a second thickness, wherein the side of the transition element facing the support element has substantially the first thickness, while the side facing the roof tile has a second thickness.

These support elements and transition elements are preferably also made of the same material as the said roof tiles.

In this way a BIPV system can be obtained with a solar panel provided with a fastening system according to the present invention, wherein the roof towards the inside of the building is covered with one material. With existing BIPV systems that are used in practice, the roof is covered with different materials (traditional roof covering next to the PP substrate). Different materials ensure a less durable roof covering, since the different materials have a different lifespan. These different materials usually also have different physical properties and take on different functions for roof coverings. For example, a PP substrate in addition to a roof covering made of clay roof tiles will not locally absorb and return condensation under the roof covering, while the adjacent clay roof tiles do. Such differences in materials for a roof covering are highly undesirable, since in principle the further finishing of the building must be tackled differently for a PP substrate as for a roof covering with clay roof tiles in order to arrive at a healthy home.

With such roof tiles, transition elements and support elements that can connect to each other, a roofer can furthermore cover a complete roof according to the known way of covering a roof with roof tiles, whereafter a solar panel according to the present invention is simply attached to the support elements with its fixing system according to the invention.

The thickness of the said transition element preferably increases uniformly from the side facing the supporting element with the first thickness to the opposite side with the second thickness.

In this way a roof covering with smooth transitions is obtained, so that a roof covering that is perceived as particularly aesthetic by most people is obtained.

In order to further clarify the properties of this invention and to indicate additional advantages and details thereof, a more detailed description of an embodiment of a solar panel according to the present invention and of a roof covering according to the present invention comprising such a solar panel follows. It is clear that nothing in the following description can be interpreted as a limitation of the protection demanded in the claims for the solar panel and the roof covering according to the present invention.

Furthermore, these embodiments, of a solar panel according to the present invention and of a roof covering according to the present invention, which comprises such a solar panel, are discussed in the accompanying figures, with reference numerals referring to these figures, wherein in figure 1 a part of the roof construction provided for mounting an embodiment of a solar panel according to the present invention is shown in top view; figure 2 shows the embodiment of a solar panel according to the present invention, provided for mounting on the part of the roof construction as shown in figure 1, in top view; figure 3 shows a detail of the embodiment of the solar panel from figure 2, mounted on the part of the roof construction from figure 1 in perspective, together with a perspective view of a fixing element for attaching the solar panel to the roof construction; Figure 4 is a diagrammatic sectional view of how a solar panel from Figure 2 can be attached to a roof construction from Figure 1.

The solar panel (1) as shown in Figure 2 is provided for being incorporated in a roof covering consisting of roof tiles and other roof covering elements. For this purpose, this solar panel (1) has a rectangular shape with a height that substantially corresponds to the height of a row of roof tiles of the roof covering. It is provided that this solar panel (1) connects via two transition elements (6) to the roof tiles of this roof covering from the row in which this solar panel (1) is received and supported by support elements (7). However, this solar panel (1) could just as well be applied to another roof covering, such as, for example, a roof covering made of zinc, corrugated sheets, etc. It will be clear to a person skilled in the art how such a solar panel (1) described here to roofing consisting of roof tiles and other roofing elements can also be included in other forms of roofing. We therefore do not elaborate on this. This solar panel (1) can furthermore be installed either as a BIPV system or on top of an existing roof construction. The following describes how the solar panel (1) is attached as a BIPV system. The fixation on top of an existing roof construction also speaks for itself.

Figure 1 shows a part of a roof construction (2) with the said support elements (7) and transition elements (6), provided for mounting the embodiment of a solar panel (1) as shown in Figure 2. The supporting elements (7) and transition elements (6) here have the same height and the same width as the roof tiles of the said roof covering. The edges of these support elements (7) and transition elements (6) are herein provided in a similar way as the roof tiles to have these support elements (7) and transition elements (6) connect to each other and to these roof tiles by partially overlapping each other.

Arranged between the row of roof tiles of this roof covering are the support elements (7) shown in Figure 1, which together form a sunken zone with respect to the roof tiles. This sunken zone is provided for receiving the solar panel (1). To form a sunken zone, these support elements (7) have a first thickness, which is smaller than a second thickness, which is the thickness of the roof tiles between which these support elements (7) are arranged. In the same row of roof tiles, transition elements (6) are provided between the support elements (7) and the roof tiles, such transition element (6) having the first thickness on the side facing the sunken zone and having the second thickness on the opposite side. The difference between this first thickness and this second thickness is calculated in such a way that after installing the solar panel (1) in the sunken zone, this solar panel (1) is included in the roof surface itself as a BIPV system and the function of the roof covering at least partially.

The fastening elements (3a, 3b, 3c, 3d) with which this solar panel (1) can be mounted on the roof construction were shown partly in figure 1 and partly in figure 2. These fastening elements (3a, 3b, 3c, 3d) comprise on the one hand magnetic fasteners (3a, 3b) and on the other hand mechanical fasteners (3c, 3d). In addition, or as an alternative to the mechanical fasteners (3c, 3d), the solar panel (1) can also be attached to the roof construction by means of an adhesive connection.

The magnetic fastening means (3a, 3b) comprise on the one hand some permanent magnets (3b) which are provided on a metal clamping element, with which they can be arranged in a cavity (8) provided for this purpose in the lower left corner of a supporting element (7). In figure 3 this metal clamping element, provided with a permanent magnet (3b), is shown separately in perspective and shown after mounting in the provided cavity (8) in the lower left corner of a supporting element (7).

On the other hand, the magnetic fastening means (3a, 3b) comprise metal elements (3a) on the rear side of the solar panel (1) on the underside of this solar panel (1).

Due to the magnetic attraction between these permanent magnets (3b) and these metal elements (3a), the solar panel (1) can be mounted on the roof construction.

The said mechanical fastening means (3c, 3d) of this solar panel (1) comprise on the one hand metal hooks (3c), provided with slots for fitting screws through. These metal hooks (3c) are provided on the top of the solar panel (1).

On the other hand, these mechanical fastening means (3c, 3d) of this solar panel (1) comprise openings (3d) at the top in the supporting elements (7) and screws which pass through the slots in the metal hooks (3c) and through the openings (3d) of the support elements (7) can be arranged to attach the solar panel to the support elements (7).

These openings (3d) correspond to the openings that are usually provided in roof tiles to attach them to an underlying roof construction. These openings (3d) are therefore situated in a zone of the supporting elements (7) which is provided for passing through a part of the roof tiles of an upper row of roof tiles, or by a part of the supporting elements (7) which are in an upper row of roof tiles be overlapped. The water permeability of the roof covering obtained with this is therefore that of a standard roof covering made of roof tiles and other roof covering elements.

These metal clamping elements, provided with permanent magnets (3b), metal elements (3a), metal hooks (3c) and screws form as fastening means (3a, 3b, 3c, 3d) for solar panels (1) a considerable saving of fastening material compared to the existing systems.

Said magnetic fasteners (3a, 3b) and said mechanical fasteners (3c, 3d) are, as indicated, provided on opposite edges of the solar panel (1). The magnetic fasteners (3a, 3b) are on the bottom of the solar panel (1), while the mechanical fasteners (3c, 3d) are on the top.

The mechanical fastening means (3c, 3d) are in each case provided at such a distance / distance from each other that any stresses in the longitudinal direction of the solar panel (1) can be absorbed, because the underlying supporting elements (7) can shift relative to each other . The metal elements (3a) are also wider than the permanent magnets (3b), so that with voltages in the solar panel (1) the magnetic connecting means (3a, 3b) can shift relative to each other, without the magnetic contact between the two being broken is becoming. Any stresses in the width direction of the solar panel (1) are absorbed by means of the magnetic connecting means (3a, 3b).

The solar panel (1) as shown in figures 2, 3 and 4 is integrated in a frame-shaped frame (4) made of PU. This frame (4) protects the solar panel (1) and in particular the edges thereof against weather influences, so that it is damaged less quickly or becomes defective. Both the said metal elements (3a) of the magnetic fasteners (3a, 3b) and the metals (3c) of the mechanical fasteners (3c, 3d) are herein incorporated into the PU frame (4) via reaction injection molding, so that these fasteners ( 3a, 3c) are immediately available when installing the solar panel (1) and cannot be lost. In addition to these fasteners (3a, 3c), electrical and / or electronic components (5) can also be incorporated into this frame (4).

The support elements (7) are furthermore, as shown in Figure 1, also provided with the necessary cavities (10) for receiving, for example, electrical and / or electronic components (5) of this solar panel (1).

A roofer can have the transition elements (6) and support elements (7) described above join together with the roof tiles in a known way to cover a complete roof with these roof tiles, transition elements (6) and support elements (7). In order to subsequently install the solar panel (1) in the sunken zone that forms the support elements (7), the roofer, as shown in figure 4, preferably provides a fixing aid (9) between the magnetic fixing means (3a, 3b). In this way the roofer can position the mechanical fasteners (3c, 3d) relative to each other as shown in figure 3, without the magnetic attraction between the magnetic fasteners (3a, 3b) making this positioning difficult. The roofer can then install screws through the slots of the metal hooks (3c) and through the openings (3d) of the support elements (7), to mechanically fix the solar panel (1) to these support elements (7). When the roofer then removes the fixing aid (9) in the direction according to arrow (A), and lowers the solar panel (1) according to arrow (B), the magnetic connection between the magnetic fixing means (3a, 3b) will cause the magnetic connection automatically come about.

A roofer therefore does not need special tools to realize this roof covering, but can mount this roof covering with tools that he has with him as standard.

With a roof covering obtained in this way, no visible fasteners are present anymore. The magnetic fastening means (3a, 3b) are on the one hand completely located at the rear of the solar panel (1), while the mechanical fastening means (3c, 3d) are situated in a zone of the supporting elements (7) which is provided to pass through a portion of the roof tiles of an upper row of roof tiles, or by being overlapped by a portion of the supporting elements (7) included in an upper row of roof tiles.

Claims (18)

Solar panel (1) provided with a mounting system (3a, 3b, 3c, 3d) with which it can be mounted on a roof construction (2), characterized in that the mounting system (3a, 3b, 3c, 3d) magnetic mounting means (3a , 3b) for securing the solar panel (1) to the roof structure (2) through a magnetic attraction. Solar panel (1) according to claim 1, characterized in that the fixing system (3a, 3b, 3c, 3d) comprises at least one set of two magnetically cooperating fixing elements (3a, 3b), each set comprising a first fixing element (3a) which forms part of or is attached to the solar panel and comprises a second fixing element (3b) which is provided to be mounted on the roof construction, and that the first and the second fixing element (3a, 3b) are provided to attractiveness. Solar panel (1) according to claim 1 or 2, characterized in that the fixing system (3a, 3b, 3c, 3d) also comprises mechanical fixing means (3c, 3d) around the solar panel (1) by a mechanical connection on the roof construction ( 2) to confirm. Solar panel (1) according to one of the preceding claims, characterized in that the solar panel (1) is also provided for being attached to the roof construction (2) by an adhesive connection. Solar panel (1) according to claim 3 or 4, characterized in that the magnetic fastening means (3a, 3b) on the one hand, and the mechanical fastening means (3c, 3d) and / or the adhesive connection on the other are provided on opposite edges of the solar panel ( 1). Solar panel (1) according to one of the preceding claims, characterized in that the magnetic fastening means (3a, 3b) comprise a permanent magnet and comprise a fastening element which is at least partially made of metal and which is provided on the roof construction (2) ) to be confirmed. Solar panel (1) according to one of claims 1 to 6, characterized in that the solar panel (1) is integrated in a frame-shaped frame (4), and in that at least one element of the fastening means (3a) is in the frame (4) of the solar panel (1) has been incorporated. Solar panel (1) according to claim 7, characterized in that at least one of the electrical and / or electronic components (5) of the solar panel (1) is incorporated in the frame (4). Solar panel (1) according to claim 7 or 8, characterized in that this frame (4) is a PU frame. Solar panel (1) according to claim 9, characterized in that the at least one element of the fastening system (3a) is incorporated into the PU frame via reaction injection molding. Solar panel (1) according to one of the preceding claims, characterized in that it is provided to be incorporated in a roof covering comprising roof tiles. 12. Solar panel (1) according to claim 11, characterized in that it is provided to connect via one or more transition elements (6) to one or more roof tiles of the roof covering. Solar panel (1) according to claim 11 or 12, characterized in that it has a substantially rectangular or square shape with a height that substantially corresponds to the height of a row of roof tiles of the roof covering. Roof covering, characterized in that it comprises at least one solar panel (1) according to one of the preceding claims. Roof covering according to claim 14, characterized in that it comprises roof tiles. Roof covering according to claim 15, characterized in that it comprises at least one row of roof tiles, between which at least two supporting elements (7) with the same height and width as these roof tiles are arranged, which together form a sunken zone with respect to the roof tiles, and in which the solar panel (1) is included. Roof covering according to claim 15, characterized in that the sunken zone is defined by supporting elements (7) with a first thickness which are arranged in a row of roof tiles with a second thickness and which at least one end of the sunken zone in the same row of roof tiles a transition element (6) with substantially the same height and width as these roof tiles is provided between a support element (7) with a first thickness and a roof tile with a second thickness, the side of the transition element (6) facing the support element (7) has substantially the first thickness, while the side facing the roof tile has substantially the second thickness. Roof covering according to claim 16, characterized in that the thickness of said transition element (6) increases uniformly from the side with the first thickness to the opposite side with the second thickness.