Patent Application
20240328162
The present invention relates to a flashing assembly for a roof element, such as a roof window, configured for mounting in a sloped roof structure defining a slope direction and comprising a frame having a top frame member and a bottom frame member both extending horizontally in the mounted state of the roof element in a width direction, and two side frame members extending in the slope direction in the mounted state of the roof element, said flashing assembly comprising a top flashing arrangement configured for extending along the top frame member in the mounted state of the flashing assembly. The invention furthermore relates to a roof element system and to a method of manufacturing a flashing assembly.
When roof elements such as roof windows are mounted in a sloped roof, an opening is cut in the roof structure, and the roofing, which may be made from tiles or like roofing material, is interrupted. After mounting of the roof elements in the opening, a flashing assembly is used for sealing the joint between the roof window and the roof and thus ensuring a waterproof transition between the roof elements and the surrounding roofing. Each flashing element typically comprises an inner portion, which is arranged to extend up along the frame of the roof window, and an outer portion, which is arranged to extend away from frame.
When roof elements are to be mounted in larger or more complex groups, such as in a matrix constellation with roof elements mounted both side by side and above each other in the slope direction, flashing assemblies may be made on special order. In turn, the number of different components that need to be manufactured, stored and delivered is relatively high.
Applicant's earlier EP 3 480 388 A1 and WO 95/28535 A1 are examples of well-performing flashing assemblies that to some extent alleviate the challenges of varying installation configurations of such roof elements. However, there is still room for improvement.
With this background, it is therefore an object of the invention to provide a flashing assembly which is able to accommodate a larger number of varying configurations in the installation of roof elements.
In a first aspect, this and further objects are met by a flashing assembly of the kind mentioned in the introduction which is furthermore characterised in that the top flashing arrangement comprises at least one pair of an inner top flashing element and an outer top flashing element, and that each inner top flashing element and the associated outer top flashing element are interconnected in a telescopic joint.
By this design, one and the same top flashing arrangement may be utilised when installing two roof elements side by side, in which the top frame member is located at different heights in the direction of the slope of the roof. By telescopic joint is to be understood as any connection between two components allowing adjustment of their positions relative to each other. This is particularly advantageous in view of the growing focus on sustainability, partly because the number of different components that need to be manufactured and kept in stock is reduced, partly because the invention makes it possible to install traditional roof windows adjacent for instance solar panels and/or solar collectors, but also roof windows of a smaller or larger height in the slope direction. While it has hitherto been quite a challenge to provide suitable flashing for roof elements having different positions in the slope direction, the present invention provides for a well-functioning, adaptable and reliable adjustment.
In one embodiment, each inner top flashing element comprises a first leg configured for extending up along an outer side of the top frame member, and a second leg configured for extending substantially in plane with the roof structure and comprising engagement means configured to form part of the telescopic joint. In this way, the outer top flashing member may be placed on top of the second leg of the inner top flashing member, thus covering the engagement means. In this way, optimum flexibility in the adaptability of the top flashing arrangement is achieved.
In another embodiment, each outer top flashing element comprises a substantially plane base provided with top engagement means at an inner edge portion configured to form part of the telescopic joint. In particular in combination with a configuration of the inner top flashing member as comprising a substantially plane second leg, the telescopic joint achieved is particularly easily established during installation of the flashing assembly on the roof element.
In a further development of these embodiments, an outer edge portion of the second leg is bent to form the engagement means of the inner top flashing element to engage with the engagement means formed by a bent inner edge portion of the outer top flashing element. This provides for a mechanically simple and reliable connection.
In another embodiment, each inner top flashing element comprises a corner section at each side, the corner section being separated from the second leg by a ridge portion. Incorporating such a corner section into the top flashing arrangement provides adequate weatherproofing at the corner of the frame element and also provides the opportunity to connect to flashings at the sides of the frame.
In order to ensure easy and reliable connection between the outer top flashing element and a corner section, each outer top flashing element may comprise side engagement means at opposite side edge portions of the base to engage with side engagement means of the corner section of the inner top flashing element, said side engagement means of the corner section being preferably formed by an edge portion of the corner section.
In a preferred further development of the latter embodiment, the outer top flashing element may be provided with a cut-out with an extension in the width direction substantially corresponding to or exceeding a width of the corner section.
Alternatively or additionally, the width of the cut-out may substantially correspond to a spacing between an end of the top engagement means and the side engagement means. In this way, optimum engagement and adaptability conditions are achieved.
In a presently preferred embodiment, the inner top flashing element is configured to cooperate with a side flashing element, optionally at a corner section.
In one particularly advantageous further development of this preferred embodiment, the inner top flashing element, the outer top flashing element and the side flashing element are configured to cooperate with an extension flashing element, preferably by engagement of a side edge of the extension flashing element with a slit-shaped pocket formed between a lower outer edge and the edge portion of the corner section. The extension flashing element may constitute a gutter element to be positioned between neighbouring roof elements, or a transition element to the surrounding roofing. Additionally, it may function as a locking element for fixing the outer and inner top flashing elements in their selected relative position.
The degree of adaptability of the top flashing arrangement may be chosen according to specific requirements. It is preferred that the inner top flashing element and the outer flashing element define a maximum measure (Dmax) in the slope direction, corresponding to a position in which the outer flashing element overlaps the inner flashing element to a minor extent and the telescopic joint is fully established.
While the dimensions of the inner and outer top flashing elements may in principle be chosen independently of each other, it is preferred that the inner top flashing element and the outer flashing element define a minimum measure in the slope direction, corresponding to a position in which the outer flashing element overlaps the inner flashing element to a major extent and the telescopic joint is inactive. In particular, it is preferred that the dimensions in the slope direction lie in the same size range.
Examples of suitable values are given in embodiments in which the maximum measure lies in the range 200 to 250 mm, and wherein the minimum measure preferably lies in the range 100 to 125 mm and/or a measure of the joint lies in the range 20 to 80 mm.
In a second aspect, a roof element system is devised.
In a third aspect, a method of manufacturing is devised.
Other presently preferred embodiments and further advantages will be apparent from the subsequent detailed description and drawings.
A feature described in relation to one of the aspects may also be incorporated in the other aspect, and the advantage of the feature is applicable to all aspects in which it is incorporated.
In the following description embodiments of the invention will be described with reference to the schematic drawings, in which
In the following detailed description, preferred embodiments of the present invention will be described. However, it is to be understood that features of the different embodiments are exchangeable between the embodiments and may be combined in different ways, unless anything else is specifically indicated. It may also be noted that, for the sake of clarity, the dimensions of certain components illustrated in the drawings may differ from the corresponding dimensions in real-life implementations.
It is noted that terms such as “up”, “down”, “left-hand”, “right-hand”, “exterior”, “interior”, “outer”, “inner” are relative and refers to the viewpoint in question.
In
The roof structure 3 is represented by only a few rafters 31, laths 32 and a header 33. The roof structure 3 may be configured differently and/or comprise other components such as boarding etc.
As shown in
As will be described in further detail below, a flashing assembly is provided for use in the roof element system shown in
Referring now to
Depending on the number of roof elements in the system, the top flashing arrangement comprises a suitable number of pairs of an inner top flashing element 111 and an outer top flashing element 112. In the following, reference will be made to one top flashing arrangement. It is noted that the top flashing arrangement adapted to be associated with a neighbouring roof element may comprise fewer or more components.
The inner top flashing element 111 and the associated outer top flashing element 112 are configured to be interconnected in a telescopic joint 115.
In the embodiment shown, each inner top flashing element 111 comprises a first leg 1111 configured for extending up along an outer side of the top frame member 2.11 or 2.21, and a second leg 1112 configured for extending substantially in plane with the roof structure 3 and comprising engagement means 1112a configured to form part of the telescopic joint 115. The first and second legs 1111 and 1112 extend substantially perpendicularly to each other and are connected in a slightly curved transition portion such that a concave side is formed, facing outwards.
The outer top flashing element 112 comprises a substantially plane base 1120 provided with top engagement means 1120a at an inner edge portion configured to form part of the telescopic joint 115.
An outer edge portion of the second leg 1112 is bent, upwards and inwards towards the concavity, to form the engagement means 1112a of the inner top flashing element 111 that are adapted to engage with the engagement means 1120a formed by a bent inner edge portion of the outer top flashing element 112. The inner edge portion is bent downwards and upwards as indicated in the drawn position. The length of the bent portions and thus of the respective engagement means may vary according to the specific field of application and will be described in further detail below. By the term “bent” is to be understood any manufacturing process adapted to form a portion having a different direction than the main part of the component. The bending process could result in a relatively sharp structure, or a curved structure.
In the embodiments shown in the figures, the inner top flashing element 111 further comprises a corner section 1113 at each side, the corner section 1113 being separated from the second leg 1112 by a ridge portion 1114 as indicated in
Referring specifically to
To accommodate the corner section 1113 in the sliding engagement, in particular where a ridge portion 1114 as described in the above is provided and where the edge portion 1113b protrudes above the plane of the corner section 1113, the outer top flashing element 112 is provided with a cut-out 1120e with an extension in the width direction W substantially corresponding to or exceeding a width of the corner section 1113. This is shown in particular detail in
The extension of the top engagement means 1120a of the outer top flashing element 112 may be chosen such that the engagement means extend over a length corresponding to the major part of the second leg 1112 of the inner top flashing element 111. In this case, the width of the cut-out 1120e substantially corresponds to a spacing between an end of the top engagement means 1120a and the side engagement means 1120b.
Turning now to
The inner top flashing element 111 is configured to cooperate with a side flashing element 113. In a manner known per se, the side flashing element is provided with an upstanding portion and a protruding leg portion. Here, the side flashing element 113 is configured to be overlapped in part at the corner section 1113 of the inner top flashing element 111.
In a still further embodiment, shown in
The flashing assembly may comprise a bottom flashing arrangement as well (not shown) connected to the side flashing elements and any extension flashing elements.
Turning now to
The inner top flashing element 111 and the outer flashing element 112 define a minimum measure Dmin in the slope direction D, corresponding to a position in which the outer flashing element 112 overlaps the inner flashing element 111 to a major extent and the telescopic joint 115 is inactive.
The maximum measure Dmax typically lies in the range 200 to 250 mm, and wherein the minimum measure Dmin preferably lies in the range 100 to 125 mm and/or a measure Dj of the joint 115 lies in the range 20 to 80 mm.
All in all, the particular configuration of the flashing assembly 11 entails that the inner top flashing element 111 and the outer top flashing element 112 of the top flashing arrangement associated with one roof element 1.1 are positioned at a different telescopic relationship than in the top flashing arrangement associated with the other roof element 1.2. For instance, the top flashing arrangement of the flashing assembly 11 in the position shown in
In the following, a method of manufacturing a flashing assembly as described in the above will be described in some detail.
The inner top flashing element 111 and optionally the corner sections 1113 are formed as an integral piece of a sheet metal material, and the outer top flashing element 112 as a separate piece of sheet metal material, the inner top flashing element 111 and the outer top flashing element 112 being supplied in a detached state and configured to be connected in the mounted state by overlapping the inner top flashing element 111 by the outer and outer top flashing element 112 and optionally engagement of the telescopic joint 115.
The invention is not limited to the embodiments shown and described in the above, but various modifications and combinations may be carried out.
| Number | Date | Country | Kind |
|---|---|---|---|
| PA 2023 70170 | Apr 2023 | DK | national |
| Number | Date | Country | |
|---|---|---|---|
| 63456560 | Apr 2023 | US |
