The present invention is concerned with windows, particularly (but not exclusively) rooflights. Rooflights are windows suitable for installation into roofs. Roofs are often angled (so that rain can run off into guttering) and thus rooflights are typically installed into an angled roof.
The uppermost end (i.e. the end nearest the apex of an inclined roof) of a rooflight is typically referred to as the head end. The sides of a rooflight are typically referred to as jambs. The lowermost end (i.e. the end nearest the gutter of an inclined roof) of a rooflight is typically referred to as the cill (sometimes spelled sill) end.
A rooflight comprises a casement and a baseplate. The casement is glazed and is moveable relative to the baseplate. The baseplate is secured to the roof in which the rooflight is mounted.
A first aspect of the present invention provides a casement with a protective perimeter lip or flange.
A second aspect of the present invention provides a combined lining and guide rail for a blind.
A third aspect of the present invention provides a flashing system for a rooflight.
Another aspect of the present invention provides a water deflector for preventing rain water from impinging directly onto a weather seal between a casement and baseplate. Another aspect provides removable linings which can be mounted an interior face of the casement and/or baseplate. Another aspect provides a slot, for securing flashing, which extends around the perimeter of the baseplate. Another aspect of the present invention provides a blind which is recessed within cavities and a blind runner, thus reducing unwanted transmission of light when the blind is pulled. Some or all of the various aspects may be used in conjunction with each other.
DESCRIPTION OF DRAWINGS
Embodiments of the invention will be described with reference to the following Figures. For clarity, some features are not illustrated in all Figures. For clarity, in cross section views, only features in the plane are shown (unless stated otherwise).
FIG. 1 shows an isometric view of a rooflight and also shows two rafters, one rafter on each side of the rooflight.
FIGS. 2-5 are primarily concerned with illustrating a water deflector.
FIG. 2 shows a cross section of the rooflight of FIG. 1 in a vertical plane II-II of FIG. 1, along a longitudinal centre line of the rooflight. FIG. 2 also shows trimmers which span the rafters of FIG. 1.
FIG. 3 shows a cross section of the rooflight of FIG. 1 in the vertical plane II-II, and shows a casement of the rooflight opened and spaced apart from a baseplate.
FIG. 4 shows a zoomed view of a region IV at the head end of FIG. 2, and shows primary and secondary water seals and a deflector plate.
FIG. 5 shows an alternative embodiment of the region V of FIG. 4.
FIGS. 6 and 7 are primarily concerned with illustrating the way in which a head casement lining and a head baseplate lining are attached to the head end of the casement and baseplate, respectively.
FIG. 6 shows a zoomed view of a region VI at the head end of FIG. 2, and shows a head casement lining and a head baseplate lining.
FIG. 7 shows an exploded view of FIG. 6, in which the head casement lining has been separated from the head end of the casement, and in which the head baseplate lining has been separated from the head end of the baseplate.
FIGS. 8-10 are primarily concerned with illustrating the way in which a jamb flashing and a cill apron are attached to the rooflight.
FIG. 8 shows a plan view of the rooflight of FIG. 1 (in a direction normal to the plane of the rooflight), and shows a jamb flashing, and also shows a cill apron at the cill end of the rooflight (the rafters of FIG. 1 are not shown).
FIG. 9 shows a cross section of FIG. 8 in a vertical plane IX-IX of FIG. 8.
FIG. 10 shows a zoomed view of a region X at the cill end of FIG. 9.
FIGS. 11-13 are primarily concerned with illustrating the way in which a roller blind is incorporated within the rooflight.
FIG. 11 shows a cross section of the rooflight of FIG. 1 in the vertical plane II-II, and shows a roller blind, a blind and a hem bar.
FIG. 12 shows a cross section of the rooflight of FIG. 1 in a generally vertical plane XII-XII (the plane XII-XII is inclined from true vertical by the same angle as the inclination of the rafters) along a transverse centre line of the rooflight, and shows jamb casement linings and jamb baseplate linings, together with the blind.
FIG. 13 shows a zoomed view of a region XIII of FIG. 13, and shows a blind runner and retention studs.
FIG. 14 shows a zoomed view of a portion of an embodiment of a rooflight having a protective lip; the zoomed view of FIG. 14 corresponds to a region XIV of FIG. 7.
FIG. 15 shows a zoomed view of a portion of an embodiment of a rooflight having a recessed protective lip.
FIG. 16
a shows a zoomed view of a portion of an embodiment in which a guide rail for a blind is provided by two linings; the zoomed view of FIG. 16 corresponds generally to FIG. 6 and to the region XIII of FIG. 12. FIG. 16b shows a more detailed view of a portion of FIG. 16a.
FIG. 17 shows a view of a flashing system that may be used, instead of the jamb flashing of FIG. 8, in an embodiment.
FIG. 18 shows a cross sectional through a jamb piece of the flashing system of FIG. 17 and also through the baseplate of the rooflight; the view of FIG. 18 corresponds generally to region XVIII of FIG. 8.
DESCRIPTION OF PREFERRED EMBODIMENTS
FIG. 1 shows a rooflight 100 comprising a baseplate 110 and a casement 120. The baseplate 120 comprises a baseplate flange 130 which extends around the perimeter of the baseplate 120 and facilitates mounting of the baseplate 120 to rafters. The rooflight 100 is shown mounted to two rafters 140; the rafters 140 are not part of the rooflight 100 but show how the rooflight 100 is supported by the rafters 140. The rafters 140 are inclined from horizontal by the pitch angle, α, of the roof and thus the rooflight 100 is also inclined from horizontal by α.
In this embodiment, the rooflight 100 is formed from profiles produced by a pultrusion moulding process. The baseplate 110 comprises four lengths of a profile which are joined together by a mitre joint at each corner. The casement 120 also comprises four length of a profile (different from the profile of the baseplate 110) which are joined together by a mitre joint at each corner. In a pultrusion process, glass fibre and thermosetting resin are pulled through a passage in heated metal die to produce a glass-reinforced plastic profile having a substantially constant cross section. The pultruded profile has the same cross section as the passage in the metal die. In alternative embodiments, materials such as aluminium (whether formed by extrusion or by machining) or PVC (polyvinyl chloride) may be used instead or in addition.
As those skilled in the art will appreciate, tiling battens (not shown) typically extend across the rafters. Tiles/slates are mounted above the tiling battens by nailing the tiles/slates to the tiling battens. The tiling battens are also used to attach roofing felt underneath the tiling battens. Those skilled in the art will also appreciate that the rooflight 100 requires an aperture in the roofing felt and that the roofing felt is sealed to the rooflight 100 (around the perimeter of the rooflight 100) to prevent entry of rainwater through to the interior side of the roofing felt in the region of the rooflight 100.
In this embodiment, the rooflight 100 is double glazed. An alternative embodiment is single glazed. In this embodiment the rooflight 100 is generally rectangular. In alternative embodiments the rooflight is polygonal.
Water Deflector
FIG. 2 shows a cross section of the rooflight of FIG. 1 in a vertical plane II-II of FIG. 1. As shown, the head end and casement end of the rooflight are generally symmetric about the transverse plane XII-XII. FIG. 2 also shows trimmers 200 which span the rafters 140 of FIG. 1. The baseplate flange 130 rests on the trimmers 200 (and on the rafters 140). In this embodiment the casement is double glazed and has an upper pane of glass 210 and a lower pane 220. The panes 210, 220 are bonded to the four profiles which make up the casement 120.
FIG. 3 shows a view similar to that of FIG. 2 but in which the casement 120 has been separated from the baseplate 110. As those skilled in the art will appreciate, the cill end 300 of the casement 120 may be moved upwards relative to the cill end 310 of the baseplate 310 by using a handle (not shown) or an electric motor mechanism (not shown), optionally in conjunction with one or more gas springs (not shown). Also not shown is a linkage which connects the casement 120 to the baseplate. Suitable handles, electric motor mechanisms and linkages are known to those skilled in the art. In alternative embodiments, the linkage may be replaced with a hinge at the head end between the casement 120 and baseplate 110.
FIG. 4 shows a zoomed view of a region IV at the head end of FIG. 2. In this embodiment the casement 120 is provided with two recesses 430, 440. The recess 430 extends around the exterior perimeter of the pultrusion profile 420 of the casement 120; the recess 440 extends around the interior perimeter of the profile 420. Each recess 430, 440 is provided with a respective rubber gasket 431, 441 that is captively retained within its respective recess 430, 440. When the rooflight 100 is closed (so that the casement 120 is flush with the baseplate 110), the rubber gaskets 431, 441 form a substantially watertight seal against mating surfaces 432, 442 of the baseplate pultrusion profile 440. The recess 430, rubber gasket 431 and mating surface 432 form a primary water seal. The recess 440, rubber gasket 441 and mating surface 442 form a secondary water seal.
In this embodiment, when the casement 120 is closed, the casement 120 is spaced apart from the baseplate 110 by 2 mm. The rubber gaskets 431, 441 bridge the 2 mm gap. The 2 mm gap forms, in effect a channel at the split line (the split line is, strictly speaking, planar but at the head end of the rooflight 100 the split plane can be regarded as a split line) which could convey impinging rain drops directly towards the primary water seal.
A deflector plate 450 is mounted to the baseplate 110 (in other embodiments the deflector plate 450 is instead mounted to the casement 120). The deflector plate 450 prevents rain drops from impinging directly on the split line between the casement 120 and baseplate 110, and thus improves the ability of the primary water seal 430, 431, 432 to prevent entry of water into the rooflight 100. In other words, the deflector plate 450 ensures that the kinetic energy of falling raindrops is substantially dissipated before the water encounters the primary water seal. The deflector plate 450 also reduces water entry through the head end of the rooflight 100 when the casement 120 is partially opened.
In this embodiment the defector plate extends the entire width of the casement 120 and overlaps the casement 120 (when the casement 120 is closed) by an overlap distance 460. In this embodiment the overlap distance is 5 mm but in alternative embodiments the overlap distance may be any integer in the range 1 mm to 40 mm inclusive. In this embodiment the deflector plate 450 is made of stainless steel and is attached to the baseplate using adhesive (not shown) and screws 470.
In this embodiment, the deflector plate 450 is positioned on the baseplate 110 so that when the casement 120 is closed, there is a substantially zero gap between the deflector plate 450 and the casement 120. In alternative embodiments, the deflector plate 450 is positioned so that when the casement 120 is closed, the deflector plate 450 is spaced apart (in a direction perpendicular to the distance 460) from the casement 120, for example by 2 mm.
FIG. 5 shows an alternative embodiment of the region V of FIG. 4. In this alternative embodiment, instead of using a deflector plate 450, the baseplate 110 is provided with a lip 550 along the head end. In yet other embodiments, the casement 110 is provided with a deflector plate or a lip. In yet other embodiments, the entire exterior periphery of the casement 120 or baseplate 110 is provided with a deflector plate or a lip.
Casement Lining and Baseplate Lining
FIG. 6 shows a zoomed view of a region VI at the head end of FIG. 2, and shows a head baseplate lining 610 mounted to the head end of the baseplate 110 also shows a head casement lining 620 mounted to the head end of the casement 120.
FIG. 7 shows an exploded view of FIG. 6. The head baseplate lining 610 comprises a generally “L” shaped bracket 611. A lug 612 of the bracket 611 projects substantially normal to the plane of the head baseplate lining 610. The baseplate profile 410 has a groove 613; the width of the groove is dimensioned to retain the lug 612 by a friction fit. Similarly, the head casement lining 620 comprises a generally “L” shaped bracket 621 having a lug 622; the casement profile 420 has a groove 623.
Although not shown by FIGS. 6 and 7, in this embodiment the cill end and two jambs of the baseplate 110 and casement 120 are also provided with linings. The head and cill linings are mounted first and then the jamb linings are mounted. The dimensions of the linings are such that the jamb linings lock the head and cill linings in position so that the head and cill linings cannot be removed without first removing the jamb linings.
The various linings close off what would otherwise be open cavities of the baseplate profile 410 and casement profile 420, and therefore prevent access to the cavities. It will be recalled that, for clarity, a handle (having a handle mechanism), an electric motor mechanism, optional gas springs, and linkages have not been shown. In this embodiment, the handle mechanism, electric motor mechanism and linkages are mounted in the cavities of the baseplate profile 410 and casement profile 420. The various linings therefore prevent inadvertent access to the handle mechanism, electric motor mechanism, optional gas springs, and linkages. Access to the handle mechanism, electric motor mechanism and linkages may be obtained by pulling the appropriate lining to overcome the friction fit between the lug and groove.
The arrangement shown by FIG. 7 also allows the linings to be detached for decoration. For example, if a householder redecorates the room into which the rooflight 100 is mounted, the householder may remove the linings and paint the linings so that the painted linings match the colour of the redecorated room.
The embodiment shown by FIGS. 6 and 7 has separate brackets 611, 612 such that a bracket 611, 612 is provided, in this embodiment, every 20 cm along the lining. In this embodiment the grooves 613, 623 are continuous as they are moulded into the baseplate profile 410 and casement profile 420. In alternative embodiments, each lining may be provided with a single bracket that extends substantially the entire length of the bracket.
In yet other embodiments, different methods may be used to detachably mount the linings. For example, magnets may be mounted in the linings and profiles. Alternatively, a hook and loop type fasteners may be used.
In alternative embodiments, either only the baseplate or only the casement is provided with removable linings. In other embodiments, the rooflight comprises a glazed baseplate but does not comprise a casement that is movable relative to the baseplate.
FIG. 7 also shows the way in which the upper pane 210 and lower pane 220 of glass are bonded to the casement profile 420. In this embodiment, the upper pane 210 is bonded to the casement profile 420 around the exterior perimeter 700 of the casement profile 420. The lower pane 220 is bonded to the casement profile 420 around the interior perimeter 710 of the casement profile. Thus the upper pane 210 is larger than the lower pane 220.
In an alternative embodiment, the panes 210 and 220 are the same size. In this alternative embodiment, the profile 420 has a perimeter lip which surrounds both the panes 210, 220 and is spaced apart from the panes 210, 220 by a 3 mm perimeter gap. The lower pane 220 is bonded to the profile. A weatherproof seal is formed between the upper pane 210 and the perimeter lip using silicone sealant to bridge the 3 mm gap.
Jamb Flashing and Cill Apron
FIG. 8 shows a plan view of the rooflight 100 of FIG. 1 (in a direction normal to the plane of the rooflight 100), and shows a jamb and head flashing 800 and a cill apron 810 (the rafters of FIG. 1 are not shown). The jamb flashing 800 generally has the shape of an upside down “U” and provides, in this embodiment, 30 cm of flashing around the two jambs and head of the baseplate 110. The cill apron 810 provides, in this embodiment, 30 cm of flashing around the cill of the baseplate 110. In this embodiment the jamb flashing 800 and the cill apron 810 are formed of metal, for example aluminium.
As those skilled in the art will appreciate, lead flashing is conventionally used to integrate a rooflight with, for example, tiles or slates of the roof. The lead flashing guides rain water over the first or so row of tiles downstream of the rooflight. The installation of lead flashing is a skilled operation which increases the cost of installing conventional rooflights.
The cill ends of the jamb portions of the jamb flashing 800 overlap the ends of the cill apron 810 but do not overlap a central portion 820 of the cill apron 810. Once the rooflight 100, jamb flashing 800 and cill apron 810 have been installed into a roof, the jamb flashing 800 is covered by roof tiles/slates and is thus hidden; the central portion 820 of the cill apron 810 is visible as the cill apron 810 overlies a row (or several rows, depending on the size of the tiles/slates) of tiles/slates.
As shown in more detail by FIGS. 9 and 10, the exterior perimeter of the baseplate flange 130 is provided with a slot into which the jamb flashing 800 and cill apron 810 are received. FIG. 8 shows that there are two regions 830 where the jamb flashing 800 overlaps the cill apron 810 within the slot. FIG. 8 shows in phantom lines the edges of the jamb flashing 800 and the cill apron 810 within the slot.
FIG. 9 shows a cross section of FIG. 8 in a vertical plane IX-IX of FIG. 8, and shows the rooflight 100 inclined by the angle (i.
FIG. 10 shows a zoomed view of a region X at the cill end of FIG. 9. FIG. 10 shows a slot 1000. The slot 1000 is the cill end of the slot which, as mentioned above, extends around the exterior perimeter of the baseplate flange 130. The slot 1000 receives the uppermost end of the cill apron 810. Grub screws 1010 (only a single grub screw 1010 is visible in the vertical plane IX-IX shown zoomed by FIG. 10) retain the cill apron 810.
To mount the cill apron 810 to the slot 1000, the slot 1000 is first filled with a sealant such as silicone sealant. The cill apron 810 is then inserted into the slot 1000 and the grub screws 1010 are tightened to secure the cill apron 810. Excess sealant on the top surface 810t of the cill apron 810 is then removed (excess sealant on the bottom surface 810b of the cill apron 810 need not be removed).
The jamb flashing 800 is mounted to the baseplate flange 130 in the same way as the cill apron 810, using sealant and grub screws. The jamb flashing 800 may be mounted to the baseplate flange 130 before or after the cill apron 810 has been mounted (provided that the cill ends of the jamb portions of the jamb flashing 800 overlap the ends of the cill apron 810).
As shown by FIG. 10, the opening of the slot 1000 is located at a corner junction of the baseplate flange 130. In an alternative embodiment, the opening of the slot 1000 is moved onto a face 1020 of the baseplate flange 130 (i.e. onto the face from which the grub screws 910 are inserted). In a less preferred alternative embodiment, the opening of the slot 1000 is moved onto a face 1030 of the baseplate flange (i.e. onto the uppermost face of the baseplate flange 130).
In this embodiment, the slot (i.e. including the slot 1000 at the cill end of the baseplate flange 130) is formed in the baseplate flange 130 during the pultrusion moulding process used to manufacture the baseplate profile 410.
As shown by FIG. 10, the slot 1000 at the cill end of the baseplate 110 is orientated (that is, when the rooflight 100 is mounted to a sufficiently inclined roof) so that even if the sealant in the slot 1000 degrades, rain water will still be prevented from reaching the bottom surface 810b of the cill apron 810 as the water would have to flow uphill in the slot in order to reach the bottom surface 810b. In an alternative embodiment, the slot 1000 is in the same plane as the baseplate flange 130; in this alternative embodiment the grub screws are inserted from a face 1040 on the underside of the baseplate flange 130.
Roller Blind
FIG. 11 shows a cross section of the rooflight of FIG. 1 in the vertical plane II-II, and shows a roller blind 1100, blind material 1101 and a hem bar 1102. As shown, the roller blind 1100 is mounted at the head end of the rooflight 100, inside a cavity in the baseplate profile 410. The hem bar 1102 allows a user to readily extend the blind by pulling the blind material 1101 out of the cavity in the baseplate profile 410. As those skilled in the art will appreciate, in alternative embodiments an electric motor may be provided in the cavity in the cill end of the baseplate profile in order to electrically extend and retract the blind.
FIG. 11 also shows the head baseplate lining 610, the cill baseplate lining 1110 and cill casement lining 1120 (the cill baseplate lining 1110 and cill casement lining 1120 were not previously shown). As shown by FIG. 11 (but for clarity, not shown by FIGS. 6 and 7), the head baseplate lining 610 and the cill baseplate lining 1120 do not extend to the lower plane of the baseplate 110. A slot shaped aperture 1130 is defined between the head baseplate lining 610 and the bottom plane of the baseplate 110; the aperture 1130 allows the blind material 101 to leave the cavity in the baseplate profile 410. Similarly, a slot shaped aperture 1131 is defined between the cill baseplate lining 1110 and the bottom plane of the baseplate 110; the aperture 1131 allows the hem bar 1102 to enter the cavity in the cill end of the baseplate profile 410.
An advantage of the rooflight 100 over prior art rooflights is the use of profiles having cavities; the cavities allow components (such as the roller blind 1100) to be mounted inside the frame of the rooflight 100. This avoids obscuring the glazed aperture of the casement 110. Conventional rooflights are manufactured from solid materials such as timber and thus if a roller blind is fitted, the roller blind is mounted to the head end of the baseplate. Ignoring the matter that conventional rooflights do not have baseplate linings, a conventional rooflight would, in effect, mount the roller blind 1100 to the head baseplate lining 610, thus obscuring a portion of the glazed area of the casement and thus reducing the amount of light transmitted through the rooflight.
FIG. 12 shows a cross section of the rooflight of FIG. 1 in a generally vertical plane XII-XII (the plane XII-XII is inclined from true vertical by the same angle as the inclination of the rafters), and shows jamb baseplate linings 1210 and jamb casement linings 1220, together with the blind. As shown, the jambs of the rooflight are generally symmetric about the longitudinal plane II-II.
FIG. 13 shows a zoomed view of a region XIII of FIG. 12, and shows a blind runner 1300 and a retention stud 1310. A blind runner 1300 is mounted (using, in this embodiment, a suitable adhesive 1301) to the baseplate 110 on each jamb. A plurality of retention studs 1310 are fitted at intervals along each edge of the blind 1011. The blind runners 1330 each have a constriction 1330 that is smaller than the retention studs 1310. The edges of the blind 1101 are therefore captively retained within the blind runners 1300.
As shown by FIG. 13, the jamb baseplate linings 1210 do not extend to the bottom plane of the baseplate 110. For each jamb, a slot shaped aperture 1340 (analogous to the slot shaped apertures 1110 and 1111) is defined between the jamb baseplate lining 1210 and the bottom plane of the baseplate 110, thus allowing the edges of the blind 1101 to enter the blind runners 1300.
Again, conventional rooflights are made from solid materials such as timber and thus, ignoring the matter that conventional rooflights do not have baseplate linings, for a conventional rooflight the blind runners would be mounted to, in effect, the jamb baseplate linings, thus obscuring a portion of the glazed area of the casement and thus reducing the amount of light transmitted through the rooflight.
A further advantage of having the roller blind 1100 and blind runners 1300 mounted within a cavity of the profile 420 is that unwanted transmission of light around the edges and ends of the blind 1101 is reduced. As shown by FIGS. 11, 12 and 13, unwanted light cannot pass around the edges or ends of the blind 1101 as the profile 420 (in conjunction with the head baseplate lining 610, cill baseplate lining 1120 and jamb baseplate linings 1210) and also the blind runners 1300 form, in effect, a light box. The light box attenuates transmission of light as any light would have to reflect off multiple surfaces in order to escape around the edges or ends of the blind 1101. In some embodiments, a blackout blind is fitted as the blind 1101 and the combination of rooflight 100 and blackout blind is effective in preventing unwanted transmission of light.
Perimeter Lip
As was mentioned above in connection with FIG. 7, in an alternate embodiment of the rooflight, the profile 420 is provided with a perimeter lip or flange. The perimeter lip/flange provides protection to what would otherwise be the exposed edge of the pane 210. Thus the perimeter lip reduces the risk of accidental damage, such as chipping or cracking, to the pane 210 during manufacture, transport or installation of the rooflight.
Prior art rooflights include a frame which encases the perimeter region of the glazing 210, 220. Such prior art rooflights do not therefore suffer the problem of damage to the edge of the glazing. The rooflight described herein has the advantage of simplified manufacture as it is not necessary to encase the perimeter of the glazing in a frame (i.e. the glazing of the present rooflight is frameless). Instead of using a frame, the glazing is bonded (as described below in more detail) to the casement 120 and then a weatherproof seal is applied between the glazing and the casement 120. Without a protective lip, the advantage of easier manufacturing would be offset by the risk of damage to the edge of the glazing.
FIG. 14 shows an embodiment 1400 of a perimeter lip 1401. In this embodiment, the panes 210, 220 are not the same size; the outer pane 210 overlaps the inner pane 220 by 8 mm at each edge and thus the outer pane 210 is 16 mm wider and 16 mm longer than the inner pane 220. The perimeter lip 1401 is the uppermost portion of an outer upstanding member 1420. An inner upstanding member 1421 is formed 4 mm away from the outer upstanding member 1420; the inner 1421 and outer 1420 upstanding members are each 5 mm thick. The outer 1420 and inner 1421 upstanding members stand up in a plane substantially perpendicular to the panes 210, 220.
FIG. 14 shows a portion of a cleat 1430. The cleat 1430 is formed of galvanized steel and in this embodiment has formed in it a 90° bend which is used to hold the mitre joints of the casement 120 secure during manufacture of the casement 120. Screws (not shown) are inserted through the inner upstanding member 1421, through the cleat 1430 and partially through the outer upstanding member 1420 in order to secure the cleats 1430 (although only one cleat in shown by FIG. 14, there are a total of four cleats 1430 per casement 120) to the pultrusion profile 420 of the casement 120. Note that in some embodiments, a total of 12 cleats are used. FIG. 16a shows an embodiment in which as well as the four cleats 1430, there are also four cleats 1631 and four cleats 1632. As shown, the cleats 1631 and 1632 are received by respective recesses in the profile of the casement Silicone 1440 is applied, between the pane 210 and the perimeter lip 1401, as the primary weather seal between the glazing and the profile 420. In this embodiment, the distance from the edge of the pane 210 to an inside face 1402 of the perimeter lip 1401 is 5 mm. The distance from the bottom of the pane 210 to the top of the inner upstanding member 1421 is 2 mm. The silicone 1440 is applied in a liquid form and covers the cleat 1430 and in this embodiment at least partially fills a cavity 1450.
FIG. 14 also shows the configuration of the glazing in more detail. The panes 210, 220 are each 4 mm thick and are spaced apart by a spacer bar 1460. As is known to those familiar with double glazing, in this embodiment the spacer bar 1460 has a cross-section of approximately 12 mm×12 mm and is attached to the panes 210, 220 by a hot melt adhesive. As is also known to those familiar with double glazing, glazing tape 1470 is used to attach the inner pane 220 to the profile 420. Glazing tape is a type of double sided adhesive tape and, as well as mechanically securing the glazing 210, 220, 1460, provides a secondary weather seal.
FIG. 14 shows that the top of the perimeter lip 1401 is flush with the top of the pane 210. In alternative embodiments, the top of the perimeter lip 1401 may be project above the top (i.e. outermost surface) of the pane 210 or may be recessed below the top of the pane 210. For example, the top of the perimeter lip 1401 may either project or be recessed by 1, 2, 3, 4 or 5 mm. A disadvantage of a recessed perimeter lip compared to the flush perimeter lip 1401 is that the risk of accidental damage to the edge of the pane 210 is increased. In effect, with a recessed perimeter lip there is a range of angles which could allow an object to impinge on the edge of the pane 210 and crack or chip the pane 210.
In FIG. 14, the glazing tape 1470 has a thickness of 9 mm which, in conjunction with the 4 mm thickness of the panes 210, 220 and the 12 mm height of the spacer bar 1460, provides a total height of 29 mm. In embodiments which use 6 mm thick glass for the panes 210, 220, the thickness/height of the glazing tape 1470 may be reduced to, say, 5 mm to compensate for the increased thickness of the glass, thus ensuring that the top of pane 210 is flush with the top of the perimeter lip 1401.
FIG. 15 shows a simplified version of FIG. 14 but in an embodiment in which a perimeter lip 1501 is recessed. As shown, there is a range of angles β which allow an object to impinge on the edge of the pane 210. In FIG. 15, the outermost portion of the top of the perimeter lip 1501 is laterally 12 mm (5 mm silicone gap together with, in this embodiment, 7 mm (instead of 5 mm as was the case for FIG. 14) of outer upstanding member 1420) away from the edge of the pane 210. The outermost portion of the top of the perimeter lip 1501 is 3 mm lower than the pane 210. Thus there is an angular range of arctan (3/12)=17° from below and 90° from above which together gives a 17°±90°=107° angular range of vulnerability. In an alternative embodiment, the perimeter lip may be spaced 1 mm (i.e. 1 mm of silicone 1440) from the edge of the pane 210 and may be raised 1 mm above the top of the panel 210. In such an alternative embodiment, the edge of the pane 210 is protected from below and thus the total angular range of vulnerability is reduced to arctan (1/1)=45°. In other embodiments the perimeter lip 1501 and the edge of pane 1501 may be positioned relative to each other so that the total angular range of vulnerability is reduced (from 180°, which is unprotected) to one of: 0°, 15°, 30°, 45, . . . , 75°, 90°, 105°, . . . , 165°.
In alternative embodiments, the cleats 1430 may be dispensed with and a single upstanding member (not shown) may be used to replace the inner 1421 and outer 1420 upstanding members.
In alternative embodiments, the panes 210, 220 may be the same size. However, an advantage of panes 210, 220 of different size is that the cleats 1430 and inner upstanding members 1421 may be recessed under the pane 210.
The protective lip/flange 1401, 1501 is preferably provided on all four sides of the casement 120 (of course, the casement 120 need not be rectangular). In some embodiments, the protective lip 1401 may be provided on some, but not all, side/surfaces of the casement 120.
Integrated Linings and Guide Rail for Blind
FIGS. 16
a and 16b show a zoomed view of a portion of an embodiment in which a guide rail for a blind is formed between two channel sections 1601, 1602. In contrast, in FIG. 13 a blind runner 1300 was shown which was attached to the baseplate 110.
The channel sections 1601, 1602 cooperate to form a blind runner which captively retains the retention studs 1310 of blind material 101. Channel section 1602 is mounted on the baseplate 110 whereas channel section 1601 is mounted to the baseplate lining 610. A roller blind 1100 (not shown in FIG. 16) may be mounted inside a cavity of the baseplate profile 410 (not shown in FIG. 16). As shown by FIG. 16, the two channel sections 1601, 1602 may be identical; in FIG. 16 both channel sections are “U” shaped. In alternative embodiments, the channel sections may have different shapes and/or dimensions relative to each other, as long as the channel sections cooperate to captively retain the retention studs 1310. In yet other embodiments, the channel section 1602 may be formed as an integral part of the baseplate profile 410, and/or the channel section 1601 may be formed as an integral part of the baseplate lining 610.
An advantage of FIG. 16 over the embodiment shown at FIG. 13 is that it is not necessary to string the retention studs 1310 one-by-one into a blind runner 1300. In other words, FIG. 16 allows the blind material 101 to be detached from the baseplate 110, even when the blind material 1101 is partially or completely extended across the panes 210, 220, by opening up the channel that is formed by the cooperation of the two channel sections 1601, 1602. In contrast, with FIG. 13 the blind material 101 must be retracted onto the roller blind 1100.
Flashing System
FIG. 17 shows a flashing system 1700 that may be used instead of the jamb flashing 800 shown at FIG. 8. The flashing system may be used in conjunction with the cill apron 810 (not shown). The flashing system 1700 guides water along the jambs of the rooflight 100 (not shown) and then diverts this water substantially along paths 1799 towards the centre of the cill apron 810.
The flashing system 1700 comprises two corner pieces 1701, 1702 which, when in use, are mounted at the head end of the rooflight. The corner pieces 1701, 1702 are substantially mirror images of each other. The flashing system 1700 also comprises two diverter pieces 1711, 1712 which, when in use, are mounted at the cill end 300 of the rooflight. The diverter pieces 1711, 1712 are also substantially mirror images of each other. The corner pieces 1701, 1702 are interconnected by a head piece 1720. The corner piece 1701 is connected to the diverter piece 1711 by a jamb piece 1731; the corner piece 1702 is connected to the diverter piece 1712 by a jamb piece 1732. The jamb pieces 1731, 1732 are substantially mirror images of each other.
FIG. 18 shows a cross section through the jamb piece 1732 and through the baseplate flange 130; the view of FIG. 18 corresponds generally to region XVIII of FIG. 8. Also shown is the slot 1000 which extends around the exterior perimeter of the baseplate flange 130.
The jamb piece 1732 is similar to a “U” shaped channel but rotated through 90°. A jamb slot portion 1801, of the jamb piece 1732, fits inside the slot 1000. Silicone sealant (not shown) may be used to seal the jamb slot portion 1801, and hence the jamb piece 1732, to the baseplate flange 130. Also shown by FIG. 18 is roofing felt 1810 (not shown by FIG. 17) that is clipped onto the jamb piece 1732. One end of the roofing felt is secured by clips 1820, the other end runs underneath the tiles (not shown), or other roofing material, of the roof into which the rooflight 100 is installed.
Above the roofing felt 1810 is a piece of foam 1830 (not shown by FIG. 17). The foam 1810 reduces wind noise by bearing against the underside of the tiles to prevent wind from blowing underneath the tiles. In this embodiment the foam is substantially triangular, with a flat surface positioned on the roofing felt 1810.
Referring back to FIG. 17, three pieces (not shown by FIG. 17) of roofing felt 1810 are used, one along each jamb and one at the head end of the rooflight. In this embodiment, each diverter piece 1711, 1712 has an angled portion 1720 which acts to divert rainwater flowing down along the jambs towards the centre of the cill apron. In this embodiment, the angled portions 1720 are angled at 45°.
The two diverter pieces 1711, 1712 each have a respective portion 1720 for diverting water onto a cill apron 810 (see FIG. 8, nor shown by FIG. 17). In this embodiment, the portions 1720 are regions of the diverter pieces 1711, 1712 that are angled at 45° to the jambs of the rooflight 100. In other embodiments, the portions 1720 may have a different angle or alternatively the diverter pieces 1711, 1712 may omit the portions 1720 and so may be similar in shape to the two corner pieces 1701, 1702.
In this embodiment the head piece 1720 and the jamb pieces 1731, 1732 are plastic extrusions; the corner pieces 1701, 1702 and the diverter pieces 1711, 1712 are vacuum formed. At the interfaces between (i) the head 1720 and jamb 1731, 1732 pieces and (ii) the corner pieces 1701, 1702 and diverter pieces 1711, 1712, the corner pieces 1701, 1702 and diverter pieces 1711, 1712 are swollen during the vacuum forming process so that the extrusions of the head 1720 and jamb 131, 1732 pieces may be received inside the corner pieces 1701, 1702 and diverter pieces 1711, 1712.
The flashing system 1700 is modular which allows it to be installed to rooflights 100 of a variety of different sizes. Firstly, an extrusion is cut to the appropriate length to form the head piece 1720 and the jamb pieces 1731, 1732. Secondly, silicone sealant, in the form of a viscous liquid, is inserted into the slot 1000 around the perimeter of the baseplate flange 130. Thirdly, the ends of the head piece 1720 and the jamb pieces 1731, 1732 are then coated with an adhesive or a plastic cement.
Fourthly, the head piece 1720 and the jamb pieces 1731, 1732 are then assembled together with the corner pieces 1701, 1702 and diverter pieces 1711, 1712, by pushing them into the silicone and bonding the head piece 1720 and the jamb pieces 1731, 1732 to the corner pieces 1701, 1702 and diverter pieces 1711, 1712.
In an alternative embodiment of the rooflight, the slot 1000 may, instead of being angled as shown by FIG. 10, be in a plane parallel to the panes 210, 220. In such an embodiment, the flashing system 1700 may be pre-assembled and then slid, along the slot 1000, from the head end to the cill end 300 of the rooflight.
In an alternative embodiment of the flashing system 1700, the head piece 1720 and the jamb pieces 1731, 1732 are dispensed with, and the corner pieces 1701, 1702 and the diverter pieces 1711, 1712 are made overlong. The overlong corner pieces 1701, 1702 and the overlong diverter pieces 1711, 1712 are arranged to cooperate with each other without requiring the head piece 1720 and the jamb pieces 1731, 1732. Instead, the overlong corner pieces 1701, 1702 and the overlong diverter pieces 1711, 1712 are cut to the appropriate length and glued (or fastened) together. In yet other embodiments, the corner pieces (1701, 1702) and the head piece (1720) are provided as an integrated assembly, for example formed by vacuum forming; such embodiments are suitable for situations where rooflights will tend to have a standard width.