BE1031483A1 - ROOF CONSTRUCTION WITH FUNCTIONAL UNITS - Google Patents

Abstract

Roof construction with a roof truss comprising a set of first battens to which a roof covering is attached, a zone of the roof construction being free of roof covering, characterised in that this zone comprises cross battens extending perpendicularly to the first set of battens, and that functional units are attached to these cross battens using one or more mounting profiles.

Description

ROOF CONSTRUCTION WITH FUNCTIONAL UNITS

Subject matter of the invention

The present invention relates to a roof construction in which functional units such as panels with photovoltaic cells (photovoltaic modules) are arranged between the roof covering, preferably a roof construction of which at least a part is sloping. In other words, the functional units are integrated into the roof.

State of the Art

Functional units and panels with photovoltaic cells integrated in roofs are known. EP2216829 for example describes a photovoltaic cell built into a roof tile.

With increasing energy needs and the growing importance of providing one’s own energy, the functional surface and the efficiency of photovoltaic modules are becoming increasingly important. On the other hand, not every roof is suitable for the construction of photovoltaic modules or such construction is considered unsuitable for aesthetic reasons.

In that case, photovoltaic modules integrated into a roof structure are preferred.

A particular problem with photovoltaic modules integrated into a roof structure is the substructure. In order to ensure that no water seepage occurs in the zone where the photovoltaic modules are located and that the modules are sufficiently ventilated from behind, a fully covering substructure is often provided. However, such a fully covering substructure is difficult to combine with a merely zonal installation of photovoltaic cells where this zone is delimited by a traditional roof covering. In addition, a fully covering substructure is in many cases not easy to apply to existing roof structures where part of the roof covering has to be removed to free up a zone for photovoltaic modules.

Especially in the case of existing roof structures in which photovoltaic modules must be integrated afterwards, the use of a complex substructure is practically unfeasible because the multitude of types of roofing means that an equally large number of specific substructures must be provided to allow the photovoltaic cells to lie in the plane or almost in the plane of the roofing after installation. This is because existing roofing differs in dimensions and especially in thickness. This difference in thickness must be absorbed by the substructure. In addition, the existing types of roofing also differ in inclination with respect to the roof truss because they overlap from ridge to roof edge. This difference in inclination must also be compensated for by the substructure.

It follows from the above that there is a market demand for functional units and photovoltaic modules in particular that can be integrated into a roof structure in a simple, fast and reliable manner.

Summary of the invention

The present invention provides an answer to this market demand and provides a roof construction with a roof truss comprising a set of first battens to which a roof covering is attached, a zone of the roof construction being free of roof covering, characterised in that cross battens are provided in this zone which extend perpendicularly to the first set of battens and that functional units are attached to these cross battens using one or more mounting profiles.

The present invention also relates to a method for applying functional units for obtaining a roof construction as defined in any of the preceding claims, characterised by the following steps: (a) applying cross-battens to the first set of battens of the roof construction, the thickness of the cross-battens being chosen as a function of the thickness of the roof covering and the thickness of the functional units, so that the thickness of the functional units and of the cross-battens together substantially corresponds to the thickness of the; (b) fixing the functional units to the cross-battens using one or more mounting profiles.

Furthermore, the invention also provides a kit in parts of cross-bars and a plurality of mounting profiles for attaching functional units to a roof structure, whereby mounting profiles with support feet of different sizes are provided to allow the inclination of the functional units with respect to the roof structure to be varied as a function of a selected or existing roof covering.

The functional units are preferably panels with photovoltaic cells, the panels having a glass surface covering the photovoltaic cells, and this glass surface being situated substantially in the plane of the roof covering. According to a preferred embodiment, the panels have a layered structure with at least two layers of glass between which the photovoltaic cells are arranged.

The functional units preferably have a width that is an integral multiple of the width of a single element of the roof covering. The functional units preferably have a height that is an integral multiple of the height of a single element of the roof covering.

In this case, the mounting profiles comprise a first part in which an opening is provided and through which a screw is fitted which attaches the mounting profile in question to one of the cross-bars, and a second part which defines a U-shape in which it grips around an edge of one of the panels.

The roof structure preferably contains at least one sloping section, with some or all of the functional units positioned on this sloping section.

Brief description of the attached figures

Figure 1 schematically shows a roof construction according to the invention;

Figure 2 shows a cross-section along line l-I in Figure 1;

Figures 3a, b & c show some examples of mounting profiles of a roof construction according to the invention;

Fig. 4 shows an alternative cross-section of Figure 2.

Detailed description of a preferred embodiment

A roof construction 1 according to the invention and as shown in figure 1 consists essentially of a roof truss with rafters on which a first set of battens 2 is attached, which in this case extend horizontally at a mutually free distance from each other. This first set of battens 2, in this case roof battens, form the supporting structure for the roof covering 3, in this case roof tiles which hook behind the roof battens in a known manner and are attached to them.

According to the invention, the roof structure in a zone Z is free of roofing. In this zone Z, cross laths 4 are fitted to the roof battens. These cross laths 4 extend perpendicular to the roof battens and are provided at a mutual distance from each other. The mutual distance between two cross laths is preferably between 30 cm and 120 cm.

Functional units such as photovoltaic modules 6 are attached to the cross-bars 4 using one or more mounting profiles 5. The cross-bars are preferably made of wood, but can in principle be made of any structural material such as aluminium or plastic.

As shown in Figures 2 and 3, the mounting profiles 5 are preferably constructed in one piece and comprise a support foot 7 in which one or more openings 8 are provided allowing the mounting profiles to be fixed to the cross-bars with one or more screws 8a; and a U-shaped part 9 intended to engage around an edge 10 of the functional elements 6. The support foot 7 and the U-shaped part 9 are interconnected by a shoulder 11. According to the present invention, several mounting profiles 5 are preferably provided, whereby the height of the shoulder 11 varies and as such the distance (measured perpendicular to a plane S in which the support foot extends) between the plane S of the support foot and the U-shaped part varies from O (Fig. 3c) to a few centimetres (Fig. 3a).

The one or more openings 8 are preferably oval or elongated (cf. Fig. 3c) to allow for any difference in expansion between the material of the mounting profiles and the cross-bars after fixing the mounting profiles without the mounting profiles or cross-bars being subjected to excessive pressure.

The shoulder 11 of the mounting profiles can optionally be designed as a second U-profile 12 (Fig. 3a), whereby this second U-profile opens in an opposite direction than the U-shaped part 9 of the same mounting profile 5.

The U-shaped part 9 of the mounting profile and the possible second U-profile 12 may, depending on their design, contain sealing slots in which a sealing strip 14 can be fitted to protect the glass plate of the functional elements (cf. Fig. 2 & 3a).

Alternatively, as shown in Fig. 4, the pedestal can define the second U-profile, with the screw for fixing the mounting profile to the cross-bars being fitted through an opening in the glass plate of the photovoltaic panels, thereby anchoring them to the cross-bars.

In the case of a sloping roof structure as shown in Figure 2, with a roof edge (gutter) and a roof ridge, the cross battens extend perpendicular to the roof edge and roof ridge in that zone of the roof structure that is free of roofing.

If this zone on the roof edge side is delimited by an element of the roof covering; one or more end mounting profiles 13 are provided on this element of the roof covering with a U-shaped section that opens in the direction of the roof ridge. A side edge of a first functional element rests in this U-shaped section.

The opposite side edge of this functional element rests on the cross laths or in the second U-profile in the shoulder of a mounting profile that is attached to a cross lath. In the U-shaped part of this mounting profile rests the side edge of an upper functional element that in this case partly overlaps the lower functional element.

The functional elements are arranged in a line above each other from the roof edge side of the aforementioned zone to the ridge edge of this zone.

At the transverse side edges of each functional element, a (not shown) can be provided that is configured to connect to the roof covering of the roof structure so that water infiltration at the side edges of the functional elements is prevented.

Optionally, a water-repellent strip or drip edge (not shown) can be provided on the transverse side edges of the functional elements to prevent water droplets from moving along the underside of the functional elements.

Due to the large variation in dimensions of existing types of roofing, also in thickness, it is necessary to be able to vary the thickness of the substructure in the zone of the functional elements in order to position the functional elements in the plane of the roofing or almost in the plane of the roofing. This is not only important for the aesthetic appearance of the roof but also to prevent cracks or gaps at the transition between functional elements and the roofing. Gaps in which wind can play, which can damage the roof structure and in which water can seep in.

According to the invention, the adjustment of the thickness of the substructure is solved in a simple and reliable way. In this way, the difference in thickness of the roof covering (measured perpendicular to the plane of the roof battens) and the functional elements is compensated by varying the thickness of the cross-battens and by choosing a suitable mounting profile with a sufficiently high shoulder (Fig. 3). By providing mounting profiles with different shoulder heights, the inclination of the functional elements with respect to the cross-battens can also be varied as a function of the selected or existing roof covering.

In other words, the current invention offers a very flexible solution for all types of roofing, ranging from tiles of all sizes to roofing with very little thickness such as slates, bitumen or shingles and this without the need for a complex substructure and without the need for different expensive frames for the functional elements. These roof tiles or slates can also be laid according to different patterns such as overlapping from roof edge to ridge in line or staggered.

The functional elements are preferably panels with photovoltaic cells (photovoltaic modules), but can be of all kinds, such as solar boilers and/or combinations of both.

In the case of photovoltaic modules, the invention does not require a fixed frame around the modules.

These modules or panels contain, as is known, a back plate on which a layer of photovoltaic cells is positioned, which in turn are covered by a glass plate. The back plate can be made of all kinds of materials or combinations of materials, such as Tedlar, glass or plastic. If the back plate is made of glass, this is preferably multi-layer safety glass. According to the invention, the glass plate on the top of the panels is preferably in or roof covering. The modules preferably contain a layer structure with at least two glass plates between which photovoltaic cells are arranged. The glass plates are preferably (multi-layer) safety glass. If desired, the glass plate and back plate can have a larger surface area than the photovoltaic cells, so that the modules or panels contain a zone that is free of photovoltaic cells. Providing such a zone is particularly applicable when two photovoltaic modules partially overlap, whereby the zone of the lower panel that is positioned under an edge of the upper panel does not see sunlight and therefore does not have to contain photovoltaic cells. Also for the embodiment shown in Fig. 4, in which the modules are fixed directly to the crossbars by means of a screw, the openings in the module for receiving the screw are preferably provided in an area of the module that is free of photovoltaic cells.

The method of manufacturing the roof structure is simple and reliable and comprises (a) fitting cross-battens to the first set of battens of the roof structure, the thickness of the cross-battens being chosen as a function of the thickness of the roof covering and of the thickness of the functional units, so that the thickness of the functional units and of the cross-battens together approximately corresponds to the thickness of the; (b) fixing the functional units to the cross-battens using one or more mounting profiles, starting from a roof edge side of the zone in which the functional elements are fitted to a ridge side of this zone.

This method according to the invention can be applied to new roofs as well as to existing roofs in which the existing roof covering is changed in a zone.

By selecting a suitable thickness of cross-bars and mounting profiles with a suitable shoulder height, a zone with functional elements can be quickly and reliably installed that extends in the plane or almost in the plane of the roof covering.

A roof construction according to the present invention defines a dry space behind the functional elements, which heats up in the sun. The discharge of warm air from this space as a feed for a heat pump can yield a considerable energy yield.

Claims (15)

CONCLUSIONS 1. Roof construction with a roof truss comprising a set of first battens to which a roof covering is attached, a zone of the roof construction being free of roof covering, characterised in that this zone contains cross battens extending perpendicularly to the first set of battens, and functional units are attached to these cross battens using one or more mounting profiles. 2. Roof structure according to claim 1, wherein the functional units are panels with photovoltaic cells. 3. Roof structure according to claim 2, wherein the panels have a glass surface covering the photovoltaic cells, this glass surface being situated substantially in the plane of the roof covering. 4. Roof structure according to claim 3, wherein the panels have a layered structure with at least two layers of glass between which the photovoltaic cells are placed. 5. A roof structure according to any one of the preceding claims, wherein the functional units have a width that is an integral multiple of the width of a single element of the roof covering. 6. Roof structure according to any one of the preceding claims, wherein the functional units have a height which is an integral multiple of the height of a single element of the roof covering. 7. Roof construction according to any of the preceding claims, wherein the mounting profiles comprise a foot part in which an opening is provided and through which a screw is fitted which fastens the mounting profile in question to one of the cross-bars, and a U-shaped part which grips around an edge of one of the panels. 8. Roof structure according to any of the preceding claims, wherein the roof structure comprises at least one sloping section and at least some of the functional units are positioned on this sloping section. 9. Method for applying functional units to obtain a roof structure as defined in any one of the preceding claims, characterised by the following steps: (a) applying cross-battens to the first set of battens of the roof structure, the thickness of the cross-battens being chosen as a function of the thickness of the roof covering and the thickness of the functional units, so that the thickness of the functional units and of the cross-battens together substantially corresponds to the thickness of the; (b) fixing the functional units to the cross-battens using one or more mounting profiles. 10. Method according to claim 9, wherein the cross-bars extend from a roof edge towards a roof ridge and the functional units are installed from the roof edge towards the roof ridge, whereby the functional units partially overlap each other. 11. Method according to claim 10, wherein the functional units rest with their edge facing the roof edge in a U-shaped part of one or more mounting profiles. 12. Method according to claim 10 or 11, wherein the one or more mounting profiles are selected as a function of the height of a shoulder of the mounting profile in question, which extends perpendicular to the support foot and connects the support foot to the U-shape, with which the inclination of the functional units with respect to the crossbars is determined. 13. Method according to claim 12, wherein the functional units rest with their edge facing the roof ridge on one or more cross-bars or on a supporting surface of a second mounting profile which is attached to one of the cross-bars. 14. A method according to any one of claims 9 to 13, comprising the step of removing a portion of the roof covering to create a clear area for placing the functional units. 15. Kit in parts of cross-bars and a plurality of mounting profiles as defined in any one of the preceding claims for fixing functional units to a roof structure, wherein mounting profiles with shoulders of different sizes are provided to allow the inclination of the functional units with respect to the roof structure to be varied as a function of a selected or existing roof covering.