EP0730068A1 - Skylight - Google Patents

Abstract

The window has a casement which is mounted in a frame, so that it can swing about an axis. The frame has at least one moulding (6) with a drainage surface (18) which leads out at an angle from the region of the groove (12) between the casement and the frame. When the window is installed, the drainage surface on the lower moulding of the frame may fall away outwards with respect to the horizontal (h). The angle of fall may be at least 1 degree, and may be preferably between 2 and 5 degrees. It may also make an angle of 45 degrees or less with the plane of the closed window, and this may be preferably less than 30 degrees.

Description

The invention relates to a roof window with a window sash, which is mounted on a window block pivotable about an axis of rotation.

Roof windows are usually placed a few centimeters above the roof level to enable safe drainage. The opening of the roof window is usually made possible by a bulky mechanism that is normal to the glass surface in the room. It is often not desirable to pull the window up over the roof surface because the overall picture of the roof structure can be disturbed. The known opening mechanisms are also very voluminous and unfavorable for aesthetic reasons. In addition, they are difficult to assemble due to the often limited space inside the roof.

In the case of roof windows, there is not only the problem of draining water (particularly rainwater) that penetrates from the outside. Rather, it must also be possible to reliably remove condensed water, in particular from the rebate area between the window frame and the window sash.

The object of the invention is to provide an improved window, in particular a roof window.

According to the invention, this is achieved in that at least one window frame profile has a drainage surface leading obliquely outwards from the rebate area lying between the window frame and window sash.

Via this sloping drainage surface, condensed water can be led out of the rebate area and discharged, for example, via the mullion construction or some other way. Above all, the sloping drainage surface of the lower window frame profile plays a decisive role, since the condensed water ultimately collects in this lower rebate area. By suitable inclination of the inclined surface it can be achieved that this has a slight slope to the outside in the lower window profile with the roof window installed.

A preferred laying of the axis of rotation of the window sash below the roof level makes it possible; to form a roof window in which the outer surface of the window sash and, if applicable, the window frame is flush with the roof plane spanned by the other fixed parts of the roof (for example a mullion construction with fixed glass panes inserted between them). The hinge joint having the axis of rotation can be arranged in a chamber in the window block, which is sealed by seals and optionally has a drainage channel to the outside. A drainage channel with a gradient can lead outwards from the chamber in order to be able to safely discharge water that enters the chamber despite the seals.

In order to avoid the previously disruptive drive units for opening the window sash, a further preferred variant of the invention provides that the drive unit is arranged in the rebate area between the window frame and window sash and / or is at least partially arranged inside the window frame profile. It is thus possible to save space on the drive unit and to be arranged essentially invisible, especially in the bottom view of a roof window. The drive unit can have an elongated housing which extends in the longitudinal direction of the window frame profile. The window sash can be driven, for example, by a scissor mechanism. However, other types of drives are also conceivable and possible, for example via cable pulls or the like.

In order to enable easy assembly and, if necessary, disassembly of the window with good thermal insulation, according to a further preferred variant of the invention it is provided that the window frame and / or the window sash is composed of two profile parts which are connected to one another via thermally insulating spacers. These spacers thus function as structural components and on the other hand as thermal insulators. By separating the window frame and the window sash into outer and inner components, it is easily possible to coat them separately and, if necessary, in different colors. In addition, the spacers allow easy adaptation to different glass thicknesses. They allow easy assembly and disassembly on site and, if necessary, quick replacement of the glass from the outside. In order to ensure a good hold of the spacers, which are preferably made of reinforced plastic, they are preferably held in a clamping manner in the grooves of the metallic profile parts. The spacers preferably extend over the entire length of the profile parts and advantageously have drainage holes.

• Die Fig. 1 zeigt in einer schematischen perspektivischen Ansicht ein herkömmliches Dachflächenfenster,
• die Fig. 2 zeigt ein erfindungsgemäßes flächenbündiges Dachflächenfenster in einer schematischen perspektivischen Ansicht,
• die Fig. 3 zeigt ein erstes Ausführungsbeispiel eines erfindungsgemäßen Dachflächenfensters im teilweisen Querschnitt bei geschlossenem Fensterflügel,
• die Fig. 4 zeigt dasselbe Fenster bei geöffnetem Fensterflügel,
• die Fig. 5 zeigt ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Dachflächenfensters im teilweisen Querschnitt quer zur Drehachse des Fensterflügels,
• die Fig. 6 zeigt einen Querschnitt durch den Fensterstock und den Fensterflügel desselben Dachflächenfensters parallel zur Drehachse des Fensterflügels,
• die Fig. 7 zeigt eine schematische teilweise geschnittene Ansicht auf ein geöffnetes Dachflächenfenster gemäß der Erfindung.

Further advantages and details of the invention are explained in more detail with reference to the following description of the figures.

• 1 shows a schematic perspective view of a conventional roof window,
• 2 shows a flush roof window according to the invention in a schematic perspective view,
• 3 shows a first embodiment of a roof window according to the invention in partial cross section with the window sash closed,
• 4 shows the same window with the window sash open,
• 5 shows a further exemplary embodiment of a roof window according to the invention in partial cross section transverse to the axis of rotation of the window sash,
• 6 shows a cross section through the window frame and the window sash of the same roof window parallel to the axis of rotation of the window sash,
• 7 shows a schematic, partially sectioned view of an open roof window according to the invention.

In the exemplary embodiment shown in FIG. 1, the load-bearing roof construction consists of transversely running transoms 2 and posts 1 running in the falling line. The roof window 3 protrudes opposite the roof plane spanned by the transoms and posts.

In contrast, the roof window 3 according to the invention is arranged essentially flush with the roof plane spanned by the transoms and posts.

This is made possible in that, according to the invention, the axis of rotation 4, about which the window sash 5 can be pivoted with respect to the window frame 6, lies at a normal distance d below the roof plane E shown in broken lines, as is shown in FIG. 3. The normal distance d of the axis of rotation from the roof surface E is advantageously more than 1 cm in order to be able to accommodate a sufficiently dimensioned hinge joint 7. Typically this normal distance will be between 1 and 3 cm. The hinge joint 7 is connected to the window frame 6 via a web 8 and to the window sash 5 via a web 9. This allows the window sash 5 to be opened about the axis of rotation 4, as indicated in FIG. 4. The hinge 7 is arranged in a chamber 10 in the window frame 6 and is covered on the outside on the one hand by a part 5a of the window sash and on the other hand by a seal 11 fixed to the window frame. This prevents rain from entering the chamber 10, in which the hinge joint 7 is protected, both in the closed and in the open state of the window sash 5. Compared to the rebate area 12 between the window sash 5 and the window frame 6, the chamber 10 is sealed by a seal 13 when the window sash 5 is closed.

Should water penetrate into the chamber 10 in spite of the countermeasures described, this can escape to the outside via a drainage channel 14, preferably at the bottom of the seal 11, from the lower window block section. The following should be noted:

The roof windows according to the invention can open in a wide variety of directions, depending on the position of the axis of rotation. With a normal roof window to arrange the axis of rotation 4 horizontally in the upper area of the roof window so that the window sash opens at the bottom. But it is also often the case that the window sash 5 should open at the top to enable ventilation in the event of a fire (fire smoke sash). Then the axis of rotation 4 lies in the horizontal lower window frame profile 6, as shown in FIGS. 3 and 4. Of course, it is also possible that the roof window opens like an ordinary window about an axis of rotation that runs in the fall line of the roof. In any case, it is favorable if the window frame profile 6 and the window sash profile 5 are profiled the same everywhere around the window, in which case the chamber 10 opposite the hinge joint 7 is simply empty. Water that penetrates into the chamber 10 of the upper window frame profile or the side window frame profiles ultimately collects in the lower chamber 10 of the lower window frame profile 6 that communicates with it and can get out there via the drainage channel 14, provided, of course, that the roof window is so sloping is installed that the drainage channel 14 has a slope to the outside.

In addition to the drainage of the chamber 10, it is also important to reliably drain the chamber 15 and the rebate area 12 between the window sash 5 and the window frame 6. For this purpose, according to the invention, the window frame profile according to FIG. 4 has a drainage surface 19 leading outwards from the fold area 12 (more precisely from the fold base 12a). The inclined drainage surface 19 of the lower window frame profile must drop outwards with a built-in roof window with a slight slope relative to the horizontal, so that the water from the rebate 12 through the water passage openings 17, 20 can flow outwards according to the arrows shown. It is sufficient if this gradient is at least 1 °, preferably between 2 and 5 °. The inclined drainage surface 18 advantageously extends over the entire length of the window frame profile 6 and is essentially flat. If the angle (see later angle β in FIG. 5) that the inclined drainage surface 18 includes with the window plane spanned by the window block 6 is below 45 °, preferably below 30 °, roof surface windows with a slight inclination can also be used, the rebate 12a of which is nevertheless can be safely drained. If this angle is 23 °, for example, a flush window in a roof with a roof pitch of 25 ° is possible. The oblique drainage surface 18 then drops outwards over the difference angle of 2 ° and drains the fold base.

In the exemplary embodiment shown in FIG. 4, the drainage surface 18 forms the bottom of a channel 19 in the interior of the window frame profile, which communicates via water passage openings 17, 20 on the one hand with the rebate area 12 and on the other hand with the outside of the window frame profile 6. The passage openings 17 are distributed at certain intervals from one another over the length of the window frame profile and do not impair the static stability.

Water can also be removed from the rebate base 12a via the said inclined surface 19, which originates from the glass rebate area 15 between the end face 16 of the window glass and the window sash 5 and can flow from there into the rebate area 12 via connecting openings 16.

5, the angle β of the inclined drainage surface 18 is smaller than in the embodiment according to FIG. 4. In order to have a slope of this inclined drainage surface to the outside in the installed state, the angle β must be smaller than that in the installed state Roof pitch angle α at which angle to the horizontal h the entire roof window is installed. The chamber 15 or the fold area 12 can then be drained in accordance with the double arrows shown. 5 is also a section transverse to the axis of rotation 4 of the lower window frame profile 6 or of the window sash 5 articulated thereon. The roof window according to FIG. 5 therefore opens at the top. If the roof window opens at the bottom, i.e. the axis of rotation is at the top, the cut looks essentially the same. Only the hinge joint 7 in the chamber 10 is missing. Aeration of the drained areas is also possible via the drainage paths mentioned.

In the embodiment shown in FIG. 5, the fold base 12a is already formed by an inclined section 18a of the drainage surface 18, which lies outside the drainage channel running in the floor profile 6. This means that the fold width can already be used to drain water to the outside.

The section according to FIG. 6 is a section parallel to the axis of rotation through the right of the two side window frame or window sash areas. It can be seen that the window frame profile 6 and the window casement profile 5 look essentially the same as in the lower region of the roof window according to FIG. 5. This is also advantageous for manufacturing reasons. Only the drainage channels 17, 20 and 14 and 16 need not be provided here. Here you can see the glass pane 22 held over seals 21, the rebate base seal is designated by 12b.

6 and 7 show the drive unit 23 which is arranged according to the invention in the rebate area between the window frame 6 and the window sash 5 and which opens and closes the window sash via a scissor mechanism 24. As FIG. 6 shows, the drive unit 23 is partially arranged with its part 23a inside the window frame profile 6. Specifically, the drive unit 23 is inserted into a recess in the surface 18a. In the lateral areas of the roof window, these surfaces 18a are not used for drainage, so that the insertion of the drive unit 23a is not a problem. The drive unit 23 preferably has an elongated housing and can therefore be accommodated well and invisibly in the fold area from below and from the outside. In principle, it would also be possible to integrate such an elongated drive unit entirely inside the stick profile 6. In order to enable a safe opening of the window, it is advantageous if two drive units 23 are provided, namely on opposite sides of the roof window.

In Fig. 6 you can see, as also in Figs. 3, 4 and 5, that both the window frame 6 and the window sash are composed of two profile parts, the outer profile part in each case via thermally insulating spacers 25 with the inner profile part connected is. This allows the outer and inner profile parts to be painted separately and also allows simple and quick assembly.

The spacers 25 can have drainage bores 17 or 20 (FIG. 5).

6 also shows that the window frame and sash profiles have rectangular chambers 26 in cross section. These allow the above-mentioned profile parts to be quickly connected to one another via simple extruded corner connectors (not shown), the channels 19 and the fold region 12 advantageously communicating with one another. The same applies to chamber 15.

A further variant of the invention provides that at least one glass retaining strip 27 which can be detachably connected to the window sash 5 is arranged on the outside of the window glass 22.

It is thus possible to simply mount the glass pane 22 into the glass wing 5 from the outside. A support 30, which can be designed as a seal, initially allows the window glass 22 to be simply placed on it without additional holding being necessary. The glass retaining strip 27 can then be inserted into the groove 29. This glass retaining strip, which is initially held loosely in the groove, can then be fixed in a clamped manner by introducing the window rubber 28 together with the glass pane 22.

Claims (19)

Roof window with a window sash that is pivotally mounted on a window frame about an axis of rotation, characterized in that at least one window frame profile (6) has a drainage area (18) leading obliquely outwards from the rebate area (12) between the window frame and window sash. Roof window according to claim 1, characterized in that the inclined drainage surface (18) of the lower window frame profile (6) with an installed roof window (3) slopes outwards with a slope relative to the horizontal. Roof window according to claim 2, characterized in that the gradient is at least 1 °, preferably between 2 ° and 5 °. Roof window according to one of claims 1 to 3, characterized in that the angle (β) which the inclined drainage surface (18) forms with the window plane spanned by the window block (6) is 45 ° and below, preferably below 30 °. Roof window according to one of claims 1 to 4, characterized in that the oblique drainage surface (18) extends over the entire length of the window frame profile (6). Roof window according to one of claims 1 to 5, characterized in that the oblique drainage surface (18) leads obliquely outwards from the base (12a) of the rebate area (12). Roof window, in particular according to one of claims 1 to 6, characterized in that the axis of rotation (4) is arranged at a normal distance (d) of preferably more than 1 cm below the roof plane (E). Roof window according to claim 7, characterized in that the hinge joint (7) having the axis of rotation (4) is covered towards the outside by a part (5a) of the window sash (5). Roof window according to one of claims 1 to 8, characterized in that in the lower window frame section when the roof window (3) is installed, at least one drainage channel leads from a chamber (10) in the window frame profile (6) with a slope to the outside. Roof window according to one of claims 1 to 9, characterized in that the outer surface of the window sash (5) and possibly the window frame (6) is flush with the roof plane (E) spanned by the other fixed parts of the roof. Roof window with a window sash that is pivotally mounted on a window frame about an axis of rotation, at least one preferably electrical drive unit being provided for opening and closing the window sash, In particular according to one of claims 1 to 19, characterized in that the drive unit (23) is arranged in the rebate area (12) between the window frame (6) and window sash (5) and / or is arranged at least partially in the interior of the window frame profile (6). Roof window according to claim 11, characterized in that a preferably inclined surface in the rebate area of the window frame profile (6) has a recess into which the drive unit (23) is inserted. Roof window according to claim 11 or 12, characterized in that the drive unit (23) is arranged in an elongated housing which extends in the longitudinal direction of the window frame profile. Roof window according to one of claims 11 to 13, characterized in that a drive unit (23) is arranged on opposite sides of the window. Roof windows, in particular roof windows, with a window frame and a window sash, in particular according to one of claims 1 to 24, characterized in that the window frame and / or the window sash is composed of two profile parts, which are connected to one another via thermally insulating spacers (25). Roof window according to claim 15, characterized in that profile parts made of metal and the Spacers (25) consist of reinforced plastic. Roof window according to one of claims 15 to 17, characterized in that the spacers (25) have drainage bores (17, 20). Roof window according to one of claims 1 to 17, characterized in that at least one glass holding strip (27) which can be detachably connected to the window sash (5) is arranged on the outside of the window glass (22). Roof window according to claim 18, characterized in that the mounted window sash (5) has a support (30) on which the window glass (22) can be placed from the outside before the glass retaining strip (27) is mounted.

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