EP4269715A1 - Dachfenster mit einer isolierglaseinheit mit nutzraum - Google Patents

Dachfenster mit einer isolierglaseinheit mit nutzraum Download PDF

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Publication number
EP4269715A1
EP4269715A1 EP22169649.5A EP22169649A EP4269715A1 EP 4269715 A1 EP4269715 A1 EP 4269715A1 EP 22169649 A EP22169649 A EP 22169649A EP 4269715 A1 EP4269715 A1 EP 4269715A1
Authority
EP
European Patent Office
Prior art keywords
glass sheet
roof window
edge seal
present disclosure
arrangement
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP22169649.5A
Other languages
English (en)
French (fr)
Inventor
Martin Schwartz WIIG
David Damm MØNSTED
Jens Troels Plesner Kristensen
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
VKR Holding AS
Original Assignee
VKR Holding AS
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by VKR Holding AS filed Critical VKR Holding AS
Priority to EP22169649.5A priority Critical patent/EP4269715A1/de
Publication of EP4269715A1 publication Critical patent/EP4269715A1/de
Pending legal-status Critical Current

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Classifications

    • EFIXED CONSTRUCTIONS
    • E06DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
    • E06BFIXED OR MOVABLE CLOSURES FOR OPENINGS IN BUILDINGS, VEHICLES, FENCES OR LIKE ENCLOSURES IN GENERAL, e.g. DOORS, WINDOWS, BLINDS, GATES
    • E06B3/00Window sashes, door leaves, or like elements for closing wall or like openings; Layout of fixed or moving closures, e.g. windows in wall or like openings; Features of rigidly-mounted outer frames relating to the mounting of wing frames
    • E06B3/66Units comprising two or more parallel glass or like panes permanently secured together
    • E06B3/6617Units comprising two or more parallel glass or like panes permanently secured together one of the panes being larger than another
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04DROOF COVERINGS; SKY-LIGHTS; GUTTERS; ROOF-WORKING TOOLS
    • E04D13/00Special arrangements or devices in connection with roof coverings; Protection against birds; Roof drainage ; Sky-lights
    • E04D13/03Sky-lights; Domes; Ventilating sky-lights
    • E04D13/0305Supports or connecting means for sky-lights of flat or domed shape
    • E04D13/031Supports or connecting means for sky-lights of flat or domed shape characterised by a frame for connection to an inclined roof
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04DROOF COVERINGS; SKY-LIGHTS; GUTTERS; ROOF-WORKING TOOLS
    • E04D13/00Special arrangements or devices in connection with roof coverings; Protection against birds; Roof drainage ; Sky-lights
    • E04D13/03Sky-lights; Domes; Ventilating sky-lights
    • E04D13/035Sky-lights; Domes; Ventilating sky-lights characterised by having movable parts
    • E04D13/0351Sky-lights; Domes; Ventilating sky-lights characterised by having movable parts the parts pivoting about a fixed axis
    • E04D13/0354Sky-lights; Domes; Ventilating sky-lights characterised by having movable parts the parts pivoting about a fixed axis the parts being flat

Definitions

  • the present disclosure relates to a roof window for installation in a roof structure of a building.
  • roof windows for installation in a roof structure of a building are popular, since such roof windows may provide e.g. increased inflow of natural light/sunlight, help to provide heating, provide ventilation options and/or the like.
  • roof windows may require a more complex window design in order to assure sufficient water tightening and/or to facilitate installation of equipment such as electrical equipment. This may result in more space consuming window designs.
  • Patent document EP 2 843 151 B1 An example of a roof window design is disclosed in patent document EP 2 843 151 B1 .
  • This document discloses a roof window of the centre pivot type and comprising an insulated glass unit with four glass sheets and three heat-insulating spaces.
  • EP 2 947 253 B1 discloses a space in the form of a water drainage channel for receiving condensed water that originates at the underside of a cover.
  • the above solutions may provide drawbacks in relation to at least space consumption and/or sufficient water tightening/handling of water.
  • Some prior art solutions also comprises a water drainage channel placed at an upwardly facing outer surface of a movable frame of a roof window, where the channel is placed next to an insulated glass unit, and placed below a cover.
  • This channel is configured to receive/collect rainwater entering in between the cover and the insulated glass unit during e.g. windy weather conditions.
  • the present disclosure may e.g. provide a space saving solution that may e.g. facilitate aesthetic advantages and at the same time provide an advantageous space at the roof window.
  • advantages with regard to handling of water and/or improving heat insulation performance may additionally or alternatively be obtained.
  • the present disclosure relates to a roof window for installation in a roof structure of a building.
  • the roof window comprises a frame arrangement, wherein said frame arrangement comprises a top profile, a bottom profile and two side profiles.
  • the frame arrangement moreover comprises an insulating glass unit that is supported by the frame arrangement.
  • the insulating glass unit comprises at least a first glass sheet, a third glass sheet, and a second intermediate glass sheet placed between the first glass sheet and the third glass sheet.
  • the first glass sheet is configured to face the exterior of the building when the roof window is installed in said roof structure.
  • a first insulating gap is provided between a major surface of the first, outer glass sheet and a major surface of the second, intermediate glass sheet, where said first insulating gap is sealed by means of a first edge seal.
  • a second insulating gap is provided between another major surface of the second, intermediate glass sheet and a major surface of the third glass sheet.
  • the second insulating gap is sealed by means of a second edge seal.
  • a side portion of a major surface of the second, intermediate glass sheet extends with a first distance past a side edge of the first glass sheet and past an outer side surface of the first edge seal that faces away from the first insulating gap, so as to provide an elongated utility space.
  • the elongated utility space overlaps the side portion and may be placed opposite to the outer side surface of the first edge seal.
  • the present disclosure provides a roof window with a space saving utility space solution, which may help to enable implementation of desirable aesthetic options such as enabling a more space saving frame design and/or a more space saving covering solution.
  • the utility space is so to say integrated in the side structure of the insulating glass unit, for example at/along side parts of the insulating glass unit extending between a top and bottom of the of the glass unit, and/or at/along the top and/or bottom of the insulating glass unit.
  • the elongated utility space overlaps the said side portion of the major outer surface of the second, intermediate glass sheet, and thereby it is placed opposite to the side portion and next to the first edge seal. This provides a stepped edge configuration proximate the outer edge of the insulating glass unit, where the elongated utility space is integrated in the structure of the insulating glass unit.
  • the elongated utility space extends in a longitudinal direction that is parallel to the longitudinal direction of the side edge of the second, intermediate glass sheet that is located proximate to the side portion of the major surface of the of the second, intermediate glass sheet.
  • the major surfaces of said glass sheets are arranged parallel to each other.
  • the utility space may comprise an elongated opening at a position opposite to the said side portion of the major outer surface of the second, intermediate glass sheet, thereby providing that e.g. rain water may enter the utility space and/or providing that equipment may be placed in the utility space.
  • the elongated utility space may comprise of be a water drainage channel.
  • an outer side surface of the first edge seal that faces away from the first insulating gap may be placed opposite to the major surface of the second intermediate glass sheet, so as to provide the elongated utility space, which overlaps the side portion and is placed opposite to said outer side surface of the first edge seal.
  • the surface area of the major surfaces of the exterior glass sheet is smaller than the surface area of the major surfaces of the second intermediate glass sheet and the third glass sheet. This provides room for one or more utility spaces according to embodiments of the present disclosure.
  • the second edge seal may be located opposite to, such as below, the elongated utility space.
  • This may help to provide an improved heat insulating solution as the second edge seal and the first edge seal are physically displaced/offset, "sideways" relative to each other. This may provide a reduced cold bridge when compared to solutions where the edge seals are placed substantially above each other. Hence, the risk of condensation at the interior surface of the insulated glass unit near the frame may be reduced.
  • the first distance may be larger than the width of the second edge seal.
  • the second insulating gap may overlap the width of the first edge seal.
  • This may provide improved heat insulating performance at the edge region of the insulated glass unit, as e.g. a cold bridge that may be provided through the first and second edge seals that may provide decreased heat insulation performance may be reduced.
  • the second insulating gap may fully overlap the width of the first edge seal.
  • the first edge seal and the second edge seal may thus be arranged un-overlapping (in their width direction) at opposing sides of the second, intermediate glass sheet. This provides advantages in relation to improving heat insulation capabilities at the edge region of the insulated glass unit.
  • the first and second edge seals may generally be elongated, extend parallel to each other, and be configured to seal insulating gaps at the same edge region of the insulating glass unit.
  • the second insulating gap may extend to a position below the said side portion of the major surface of the second, intermediate glass sheet.
  • the second edge seal is the one of the first and second edge seal that is proximate the interior of the building when the roof window is installed, and this second edge seal may be arranged further away from a centre plane of the insulated glass unit that extends perpendicular to the major glass sheet surfaces of the insulated glass unit than the first edge seal.
  • Both the first and second edge seal may preferably be placed at a part of the insulated glass unit that overlaps the frame arrangement, such as a movable frame, that supports the insulated glass unit.
  • the edge of the intermediate glass sheet and the exterior surface of the second edge seal may be placed opposite to the half, such as the third of the profile's width that is distal to the frame opening of the frame.
  • the overlapping distance with which the edge of the intermediate glass sheet and the exterior surface of the second edge seal overlaps the maximum width of the profile may be at least 40%, such as at least 55%, such as at least 80% of the maximum width of the frame profile.
  • the second insulating gap that is sealed by the second edge seal may overlap at least 30%. Such as at least 40%, such as at least 50%, such as at least 60% of the maximum width of the frame profile.
  • an elongated side cover may extends over and cover a part of the elongated utility space.
  • the elongated side cover may extend over at least a part of the width of said side portion of the major surface of the second, intermediate glass sheet.
  • Providing the cover to overlap the elongated utility space may provide improved water tightening/handling of rainwater and/or aesthetic advantages.
  • roof windows for example of the centre hung type
  • the cover may extend over the entire width the elongated utility space.
  • the elongated cover may overlap a part of the outer major surface of the first outer glass sheet. In other embodiments of the present disclosure, the elongated cover may be arranged to not overlap the outer major surface of the first outer glass sheet.
  • the cover may in embodiments of the present disclosure be a rainwater cover configured to guide rainwater towards e.g. the exterior of the insulated glass unit from a position above the frame arrangement that is not covered by the insulated glass unit.
  • the distance, such as the maximum distance, between a first plane defined by an outer surface of the side cover and a second plane defined by the outer major surface of the first, outer glass sheet may be less than 30 mm, such as less than 20 mm. In some, embodiments, the distance, such as the maximum distance, between a first plane defined by an outer surface of the side cover and a second plane defined by the outer major surface of the first, outer glass sheet may be less than 10 mm, such as less than 5 mm.
  • This provides a more space saving solution and may be enabled due to the utility space being located as defined above, to be integrated in the side structure of the insulated/insulating glass unit.
  • Said first and second planes may in embodiments of the present disclosure be substantially parallel.
  • the distance, such as the maximum distance, between an outer surface of the cover and a plane defined by the outer major surface of the first, outer glass sheet may be less than 50 mm, such as less than 20 mm, preferably less than 10 mm, such as 6 mm or less than 6 mm. This distance may be determined perpendicular to the outer major surface of the first, outer glass sheet.
  • the first plane defined by an outer surface of the cover may be defined from a point of the cover surface providing the maximum distance between that plane and the second plane defined by the major outer surface of the outer glass sheet, where these planes are substantially parallel.
  • the outer surface of the side cover may in embodiments of the present disclosure face away from the first plane.
  • said first and second planes may be substantially coinciding.
  • the outer surface of the cover and the outer major surface of the first, outer glass sheet or a pane overlapping part as defined in more details below, may be substantially flush.
  • said first plane may extend between the outer major surface of the first, outer glass sheet and a major surface of the second, intermediate glass sheet.
  • the elongated utility space may provide/be an elongated water drainage channel configured to guide rainwater along the longitudinal direction of the water drainage channel.
  • This provides a space saving and yet mechanically simple and efficient way of handing/guiding rainwater in a space saving manner.
  • the said rainwater may in embodiments of the present disclosure comprise wind driven water that enters the water drainage channel from a space between a cover and the insulating glass unit.
  • the rainwater may generally not enter the water drainage channel.
  • high winds e.g. at least partly transverse to the longitudinal direction of said side edge of the of the first glass sheet
  • some rain water or in some situations, snow may enter in between the cover and the insulated glass unit.
  • This water will be collected by the water drainage channel and guided to a desired location, such as towards the bottom of the roof window where it may be guided further by means of a roofing and/or a gutter.
  • the drainage channel may guide the water along the drainage channel due to/by means of gravity.
  • the elongated utility space may additionally or alternatively be used as a wiring routing for electric systems such as power supply wires or control system wires and/or the like and/or be used for placement of equipment during e.g. retrofitting of equipment at the roof window.
  • the cover may comprise one or more elongated elevations, such as a ridge comprising a drip edge, that is placed opposite to the water drainage channel and/or or extends into the water drainage channel. This provides that water running on the underside of the cover may be forced to be released from the cover and drip into the water drainage channel.
  • the one or more elevations comprising the drip edge may in some embodiments of the present disclosure comprise a crest extending in a direction towards the water drainage channel.
  • the ridge may in some embodiments of the present disclosure extend in the longitudinal direction of the cover and parallel to the longitudinal direction of the water drainage channel.
  • a guiding arrangement may be placed at the elongated utility space, and a guiding wall of the guiding arrangement may be placed opposite to the first edge seal so that the utility space is placed/located between the guiding wall and the first edge seal.
  • the guiding wall may hence provide one of the side surfaces facing towards the utility space.
  • the guiding arrangement may comprise a bottom part, such as a bottom wall, extending over said side portion of the major surface of the second, intermediate glass sheet.
  • the bottom wall in some embodiments of the present disclosure may provide water protection for protecting the side regions of the insulating glass from rainwater.
  • the bottom wall may provide a cannel bed of the utility space.
  • the guiding arrangement may comprise a pane overlapping part which extends in over the outer/exterior major surface of the first, outer glass sheet.
  • This pane overlapping part may e.g. help to enable an improved water sealing solution.
  • the outer/exterior major surface of the first, outer glass sheet is preferably the surface that faces away from the first insulating gap.
  • the guiding arrangement may comprise a side part extending along the first edge seal, and the utility space may here be located between the side part and the guiding wall.
  • This side part may help to provide improved resistance against water, for example as the side part may prevent for example water or parts in the utility channel from damaging the first edge seal and/or interconnections between the edge seal and the glass sheets.
  • the side part and bottom part of the guiding arrangement may e.g. in some embodiments be structurally interconnected, such as integrated in the same arrangement such as the same profile.
  • the said side part extending along the first edge seal may preferably be placed along and opposite to said outer side surface of the first edge seal.
  • a guiding wall, a bottom part and a side part may together provide a U-shaped utility space which overlaps said side portion and which is placed next to the first edge seal.
  • This may provide a utility space enclosed by the guiding arrangement, where an elongated opening is provided at a position opposite to said side portion of the major outer surface of the second, intermediate glass sheet.
  • said guiding wall, bottom part and side part together providing the U-shaped utility space may comprise or be the above mentioned guiding wall, bottom part and side part of the above mentioned guiding arrangement.
  • said pane overlapping part may provide a fixation, such as a mechanical fixation, of the insulating glass unit.
  • said bottom part may provide a fixation, such as a mechanical fixation, of the insulating glass unit.
  • said pane overlapping part may be fixated to the insulated glass unit. This may in further embodiments of the present disclosure be provided by means of a water tightening seal and/or adhesive.
  • said bottom part may be fixated to the insulated glass unit.
  • This may in further embodiments of the present disclosure be provided by means of a water tightening seal and/or adhesive.
  • This may e.g. provide water tightening advantages and/or structural advantages. Additionally or alternatively, it may provide a space saving, mechanically advantageous and simple solution for fixating the insulated glass unit to the frame arrangement.
  • the fixation of the pane overlapping part and/or said bottom part may e.g. be provided by means of an sealant or adhesive such as a structural adhesive or over-moulding, and/or by means of mechanical fastening means e.g. connected to a connection arrangement at the insulation glass unit.
  • the pane overlapping part and/or said bottom part may be fixated directly or indirectly to the insulated glass unit so as to provide a holding/fixation of the insulating glass unit at the frame.
  • said pane overlapping part and/or said bottom part may provide a fixation, such as a mechanical fixation, of the insulating glass unit by means of a clamping force.
  • said pane overlapping part and said bottom part may provide a fixation, such as a mechanical fixation, of the insulating glass unit. In further embodiments of the present disclosure, said pane overlapping part and said bottom part may be fixated to the insulated/insulating glass unit.
  • both the pane overlapping part and bottom part are fixated to the insulated glass unit at each their glass surface , this may provide an enhanced fixation, also since fixation is provided at two different, outwardly facing surfaces of the insulated glass unit instead of e.g. fixation at a single exterior surface of for example the first, outer glass sheet.
  • said bottom part may be the one that provides a holding of the insulated glass unit at the frame, such as is fixated to the insulated glass unit.
  • said guiding arrangement may be integrated in a holding arrangement.
  • the holding arrangement may be configured to fixate the insulated glass unit at the frame arrangement.
  • the holding arrangement may comprises a fixation part for fixating the holding arrangement to the frame arrangement by means of fixation means such as mechanical fixation means.
  • fixation means/ fastening means may in embodiments of the present disclosure comprise mechanical fastening means such as one or more of screws, pop rivets or nails. Additionally or alternatively the fixation means/ fastening means may comprise chemical fastening means such as an adhesive, such as a glue, or welding of the material.
  • the frame and the holding arrangement and the guiding arrangement can be one part i.e. unitary.
  • the holding arrangement may for example, in some embodiments of the present disclosure, comprise a holding profile.
  • the holding arrangement may be integrated in/be unitary with, the frame profile.
  • the insulated glass unit comprises a plurality of said utility space extending along different sides of the insulated glass unit.
  • opposing, parallel utility spaces may be arranged at opposing parallel sides of the insulated glass unit. These sides may in some embodiments be at sides that extends between the top and bottom of the insulated glass unit.
  • one of said guiding space may in some embodiments be arranged to extend along a top edge of the insulated glass unit.
  • the top of the insulated glass unit (or for that matter the top of the roof window) is the part that is configured to face upwards when the window is installed in a roof with a roof pitch, such as a roof pitch above 15° or 17° such as above 30°. If the frame arrangement comprises a movable frame, this naturally is in the scenario where the movable frame is in a closed position.
  • the utility space may have a width of at least 5 mm, such as at least 9 mm, such as at least 14 mm, such as at least 20 mm.
  • the utility space has a width between 4 mm and 100 mm, such as between 5 mm and 50 mm, for example between 5 mm and 20 mm.
  • the utility space may have a height of at least 5 mm, such as at least 8 mm, such as at least 10 mm, such as at least 15 mm
  • said width of the utility space may be determined in a direction parallel to a major surface of the second, intermediate glass sheet, and perpendicular to the side edge of the second.
  • said width of the utility space may be a maximum width if the utility space.
  • the frame arrangement may comprise a fixation frame and a movable frame.
  • the movable frame provides said support of the insulating glass unit and the movable frame is movably attached to the fixation frame by means of a hinge arrangement.
  • the roof window may be of the centre-hung type.
  • the hinge arrangement provides an axis of rotation for the movable frame that is placed between the top and the bottom of the sash. This provides that the movable frame is configured to be opened by the lower part/bottom part of the sash moving outwards, and the upper part/top part of the movable frame moves inwards into the building upon opening of the sash from a closed position.
  • the axis of rotation may be arranged around the centre of side profiles of the movable frame. However, in some centre-hung configurations, the movable axis of rotation may also be displaced, towards the top or bottom part of the movable frame in order to pride a balancing of the weight of the movable frame.
  • the fixation frame may surround movable frame.
  • the maximum width of the movable frame may be less than the interior, minimum width of the frame opening of the fixation frame in order to allow top and bottom parts of the movable frame to move into the frame opening of the fixation frame when moving the movable frame to a closed position.
  • the movable frame may be rotated so that the exterior surface of the insulating glass unit faces at least partly inwards towards the building, thereby enabling cleaning of that surface from the inside of the building.
  • the movable frame may be top hung.
  • said hinge arrangement may be connected to the fixation frame and moreover structurally connected to, such as directly connected to, the holding arrangement.
  • a major surface of the first, outer glass sheet may in some embodiments of the present disclosure face (and in some embodiments preferably abut) the first insulating gap. This may be a major surface located opposite to the exterior major surface of the first glass sheet that may be configured to face away from the interior of the building and may be subjected to wind and weather.
  • a major surface of the second, intermediate glass sheet may face (and preferably abut) the first insulating gap.
  • a major surface of the second, intermediate glass sheet may face (and preferably abut) the second insulating gap.
  • the third glass sheet may face (and preferably abut) the second insulating gap.
  • the other major surface of the third glass sheet may in embodiments of the present disclosure face and abut a lamination layer /lamination inter layer or may face and abut the interior room of the building if the lamination layer and lamination glass is omitted, when the window is installed.
  • Fig. 1 illustrates a roof window 1 according to embodiments of the present disclosure.
  • the roof window 1 may also be known as a skylight.
  • the roof window 1 comprises a frame arrangement 2, 20.
  • the frame arrangement comprises a fixation frame 20 and a movable frame 2.
  • the movable frame 2 provides a support of an insulating glass unit 3.
  • the movable frame 2 is movably attached to the fixation frame 20 by means of a hinge arrangement 30.
  • the roof window 1 is of the centre-hung type.
  • the hinge arrangement 30 provides an axis of rotation RAX for the movable frame 2 that is placed between the top T and the bottom B of the sash/movable frame 2. This provides that the movable frame 2 is configured to be opened by the lower part/bottom part B of the movable frame moving outwards, away from the interior of the building in which the roof window 1 is installed, and the upper part/top part T of the movable frame 2 moves inwards into the building upon opening of the movable frame 2 from a closed position.
  • the axis of rotation RAX may be arranged around the centre of the lengths of the side profiles 2d, 2c of the movable frame. However, in some centre-hung configurations, the axis of rotation RAX may also be displaced towards the top or bottom part of the movable frame in order to e.g. provide a balancing of the weight of the movable frame 1. This is also understood as a centre hung roof window according to the present disclosure. Centre-hung windows may also be referred to pivot roof windows.
  • the fixation frame 20 may surround movable frame 2.
  • the maximum width of the movable frame 2 may be less than the interior, minimum width of the frame opening of the fixation frame 20 in order to allow top T and bottom B parts of the movable frame 2 to move into the frame opening of the fixation frame 20 when moving the movable frame 2 to a closed position.
  • the movable frame 2 may be hinged in another way, for example top hung (not illustrated).
  • the roof window may be of the type where the insulated glass unit is unmovable attached to a fixation frame.
  • the fixation frame 20 comprises parallel side profiles 20c, 20d, a top profile 20a and a bottom profile 20b placed parallel to the top profile. These profiles 20a-20d are elongated and together they provides a rectangular fixation frame opening 21.
  • the movable frame 2 comprises frame profiles comprising a top profile 2a, and a bottom profile 2b. These are placed parallel to each other.
  • the movable frame 2 also comprises parallel side profiles 2c, 2d. These profiles 2a-2d are elongated and together they provide a rectangular frame opening in the movable frame 2, and light passes through this frame opening.
  • the movable frame 2 supports an insulated glass unit. The insulated glass unit is fixated to the movable frame 2, and covers the frame opening of the movable frame 2 that is placed between the profiles 2a-2d of the movable frame.
  • the roof window 1 also comprises covers 9a, 9b.
  • a roof window of the centre hung type 1 may comprise fixed covers 9a that is fixed to the fixation frame, preferably proximate the top TF of the fixation frame 20.
  • the window comprises movable covers 9b that are fixed to the movable frame 2 and moves together with the movable frame 2. These movable covers are often placed proximate the lower part/bottom part B of the movable frame 2.
  • the width of the covers 9a, 9b overlaps profiles at the fixation frame 20 and also the movable frame 2 (see e.g. fig. 3 ) in order to improve water tightening.
  • the fixed covers 9a and the movable covers 9b may be placed in continuation of each other.
  • the covers 9a, 9b extends along the sides of the roof window 1, between the top and bottom of the roof window 1.
  • the covers 20 9a, 9b are exterior covers that are subjected to the weather
  • the roof window 1 may also comprise a top cover 9c that is arranged at the top TF of the fixation frame 20. This top cover 9c also overlaps the top T of the movable frame when the movable frame 2 is placed in a closed position. In fig. 1 , the movable frame 2 is in an open position.
  • Fig. 2 illustrates schematically a cross sectional view of a side part of an insulated glass unit 3 according to embodiments of the present disclosure, for installation in a roof window 1 (not illustrated in fig. 1 ) according to embodiments of the present disclosure.
  • the insulated glass unit 3 of fig. 2 comprises three glass sheets 3a-3c that have major surfaces 3a2, 3a1, 3b2, 3b1, 3c2, 3c1 placed parallel to each other.
  • the insulating glass unit 3 comprises at least a first, outer glass sheet 3a, a third glass sheet 3c, and a second intermediate glass sheet 3b.
  • the second intermediate glass sheet 3b is placed between the first glass sheet 3a and the third glass sheet 3c,
  • the first glass sheet 3a may be configured to face the exterior EXT of the building (see fig. 3 ) when the roof window 1 is installed in a roof structure of the building and the insulated glass unit 3 is fixed to a fixed frame, or fixed to a movable frame 2 as in fig. 1 (when the movable frame 2 is in a closed position).
  • a first insulating gap 4a is provided between an inner, major surface 3a1 of the first, outer glass sheet 3a, and a major surface 3b2 of the second, intermediate glass sheet 3b.
  • the first insulating gap 4a is sealed by means of a first edge seal 6a.
  • the major surface 3b2 of the second, intermediate glass sheet 3b may as illustrated face and preferably abut the first insulating gap 4a.
  • the major surface 3a1 of the first, outer glass sheet may as illustrated face and preferably abut the first insulating gap 4a.
  • a second insulating gap 4b is provided between another major surface 3b1 of the second, intermediate glass sheet 3b, and a major surface 3c2, of the third glass sheet 3c.
  • the second insulating gap 4b is sealed by means of a second edge seal 6b.
  • the major surface 3b1 of the second, intermediate glass sheet 3b may face and preferably abut the second insulating gap 4b.
  • the edge seals 6a, 6b of the insulated glass unit 3 may in embodiments of the present disclosure comprise spacer bars. Such spacer bars, that may be common, comprises a metal profile, a composite profile, a structural foam or TPS (thermoplastic) and/or the like. Other spacer bars may be used. Spacer bar may in some embodiments comprise a desiccant for absorbing moisture.
  • the edge seal 6a, 6b functions as a gas barrier sealant to keep an insulating gas (commonly agron) in the insulating gap 4a, 4b for the lifetime of the insulated glass unit.
  • the edge seal(s) 6a, 6b may also structurally hold the glass panes 3a-3c joined as a single, insulating glass unit 3. As illustrated in figures described in more details below, the insulated glass unit may also comprise more than two insulated spaces, and hence more glass sheets.
  • One or more of the glass sheets 3a-3c may be thermally tempered or may be annealed glass sheets.
  • the insulating glass unit 3 is a laminated glass unit, and hence, a further lamination glass sheet 3L is attached to the third glass sheet 3c surface 3c1 by means of a lamination layer LL, such as an adhesive.
  • the lamination layer LL may for example comprise EVA (Ethylene Vinyl Acetate) or PVB (Polyvinyl butyral) and should be transparent to visible light so that sunlight can pass through the insulated glass unit.
  • EVA Ethylene Vinyl Acetate
  • PVB Polyvinyl butyral
  • the lamination of the insulated glass unit provides safety, and may e.g. be advantageous in roof windows.
  • the lamination glass sheet 3L is often arranged as the innermost glass sheet of the window (when the movable frame, if present, is in a closed position), and may provide the major surface 3Li for facing, such as abutting, the interior of the building. This surface Li is placed opposite to the surface of the glass sheet 3L that is attached to the glass sheet 3c by means of the lamination lay LL.
  • the major surface 3c2 of the third glass sheet 3c may as illustrated face and preferably abut the second insulating gap 4a.
  • the other major surface 3c1 of the third glass sheet may face and abut a lamination layer LL or may face and abut the interior room of the building if the lamination layer LL and lamination glass 3L is omitted.
  • the first glass sheet 3a comprises the major surface 3a2 that faces away from the first insulating gap 4a.
  • This surface 3a2 may in some embodiments of the present disclosure be the major outer surface configured to face the exterior of the building (see fig. 3 ) when the movable frame 2 (see fig 1 ) is in a closed position, and may hence be subjected to weather such as rain, snow, hail and/or the like.
  • a side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b extends with a first distance DIS1 past the side edge 7a of the first glass sheet 3a.
  • the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b may as illustrated extend past the outer side surface 6ae of the first edge seal 6a that faces away from the first insulating gap 4a.
  • the first edge seal 6a also comprises an interior side surface 6ai that faces towards and abuts the gap 4a.
  • the side surfaces surface 6ae, 6ai are opposing and extends between the glass sheet surfaces 3a1, 3b2.
  • This provides an elongated space 10 which overlaps the side portion 8 and is placed next to the first edge seal 6a.
  • the first edge seal 6a is placed with the distance DIS2 (measured from surface 6ae) to the side edge 7b of the second, intermediate glass sheet 3b, thereby providing the elongated space 10 which overlaps the side portion 8 and is placed next to the first edge seal 6a.
  • the first distance DIS1 and the second distance DIS2 are in fig. 2 substantially equal, and the edge seal 6a surface 6ae of the first edge seal 6a that faces the space 10 is thus in fig. 2 substantially flush with the side edge 7a.
  • edge seal 6a surface 6ae may be displaced relative to the side edge 7a.
  • the distances DIS1 and DIS2 may be defined from a plane PL4 that touches and extends in the longitudinal direction of the side edge 7b (see e.g. "LD" of fig. 10 or 11 ) of the second intermediate glass sheet 3b, and which extends perpendicular to a plane PL3 defined by/comprising the major surface 3b2 of the second intermediate glass sheet 3b.
  • a plane PL4 that touches and extends in the longitudinal direction of the side edge 7b (see e.g. "LD" of fig. 10 or 11 ) of the second intermediate glass sheet 3b, and which extends perpendicular to a plane PL3 defined by/comprising the major surface 3b2 of the second intermediate glass sheet 3b.
  • the space 10 may be used for various purposes, and may hence be refered to as utility space 10.
  • the elongated space/ utility space 10 may be used as a wiring routing for electric systems such as power supply wires or control system wires and/or the like and/or may be used for placement of equipment during e.g. retrofitting of equipment at the roof window. In some situation, retrofitting of equipment at roof windows, or installing equipment before installation of the window, may be desired. Electrical wires such as power supply wires, control signal wires and/or the like may be needed. The elongated space 10 may be used for this, and hence enable a space saving solution.
  • the second edge seal 6b is located opposite to, (in the illustrated example below) the elongated utility space 10.
  • the second edge seal 6b and the first edge seal are thus physically displaced/offset, "sideways" relative to each other. This may provide a reduced cold bridge and hence an improved heat insulation performance at the edge region of the insulated glass unit 3 when compared to solutions where the edge seals are placed substantially above each other.
  • the first distance DIS 1 is larger than the width W2 of the second edge seal 6b.
  • the second distance DIS 2 may be larger than the width W2 of the second edge seal 6b.
  • the width W2 of the edge seal are determined/measured parallel to the plane PL3 and perpendicular to the plane P4.
  • the second insulating gap 4b overlaps the first edge seal 6a.
  • the second insulated gap 4b may at least partly overlap the first edge seal 6b.
  • the magnitude of the overlap may be defined by the position of the inner side surface 6bi of the second edge seal 6b, that faces the gap 4b relative to the inner side surface 3ai position of the first edge seal 6a.
  • the first edge seal 6a and the second edge seal 6b are arranged un-overlapping (as illustrated in fig. 2 ) in their width direction at opposing sides 3b 1, 3b2 of the second, intermediate glass sheet 3b to seal the respective gaps 4a, 4b. This provides that the second insulating gap 4b fully overlap the width W4 of the first edge seal 6a. This is illustrated in fig. 2 . It is naturally understood that the edge seals 6a, 6b are elongated and extends parallel to each other.
  • this may provide a reduced cold bridge between the interior and the exterior of the window when the insulated glass unit 3 is installed at the roof window. This may be caused by a longer "traveling path" for the heat (or cold) through the edge seals and/or a smaller area for direct heat transfer between the interior of the building and the exterior of the building through the edge seals 6a, 6b.
  • the edge seals 6a, 6b may be of substantially equal widths or different widths W2, W4.
  • the utility space 10 may be designed to be a water drainage channel.
  • the utility space 10 is designed as a water drainage channel of a roof window 1 is described more details below, for example in relation to among others fig. 3 .
  • Fig. 3 illustrates schematically a cross sectional view of a side part of a roof window 1, where an insulated glass unit 3 as described above in relation to fig. 2 is installed at a frame arrangement 2, in accordance with embodiments of the present disclosure.
  • the insulated glass unit 3 is attached to the frame arrangement 2, that either may be a movable frame 2 or a fixed frame.
  • the side portion of the insulated/insulating glass unit 3 overlaps the elongated frame profile 2c so that both the edge seals 6a, 6b are placed opposite to the elongated frame profile 2c.
  • the illustrated side part 8 in fig. 2 (and other figures of the present disclosure) is selected to be the right side, and hence it is here the elongated frame profile 2c that is illustrated. In other embodiments, it may be the other left side of the window (seen from the exterior) comprising the profile 2d, or the top part comprising the profile 2d. See e.g. fig. 1 .
  • a gasket 35 provides a tightening between the interior surface of the insulated glass unit 3 and the frame profile 2c.
  • the roof window 1 here comprises a guiding arrangement 11 placed at the elongated utility space 10 to guide water such as rain water along the drainage channel by means of gravity.
  • a guiding wall 11a of the guiding arrangement 11 is placed opposite to the first edge seal 6a so that the utility space 10 is placed between the guiding wall 11a and the first edge seal 6a surface 6ae, thereby providing the drainage channel.
  • the guiding wall 11a may additionally or alternatively, in other or further embodiments of the present disclosure, be used for containing equipment, wires and/or the like (not illustrated) at the desired location in the utility space 10.
  • the guiding arrangement 11 may also comprise a bottom part 11b, such as a bottom wall, as illustrated in fig. 3 .
  • This bottom part 11b extends over the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b.
  • the bottom part may provide a cannel bed of the utility space 10.
  • the guiding arrangement 11 may in embodiments of the present disclosure, as illustrated in fig. 3 , comprise a pane overlapping part 11d which extends in over the outer major surface 3a2 of the first, outer glass sheet 3a that is placed proximate the exterior EXT of the building.
  • the guiding arrangement 11 may in some embodiments of the present disclosure, comprise a side wall part 11c extending along the first edge seal 6a surface 6ae.
  • the utility space 10 is located between the side part 11c and the guiding wall 11a.
  • the parts 11b, 11c occupies a part of the space 10 along/proximate the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b, and next to the edge seal 6b, respectively.
  • the parts 11b, 11c, and/or 11d may provide mechanical protection of the insulated glass unit and/or provide water protection.
  • the width W1 of the utility space 10 may in embodiments of the present disclosure be less/smaller than the distance DIS2 and/or DIS1 (DIS1 is however not indicated in fig. 3 to improve figure simplicity, see e.g. fig. 2 ). This may be due to the thicknesses of the parts 11c and the position of the interior surface of the part 11a that faces the utility space.
  • the utility space 10 may in embodiments of the present disclosure have a width W1 of at least 5 mm, such as at least 9 mm, such as at least 14 mm, such as at least 20 mm. In some embodiments of the present disclosure, the utility space 10 may have a width W1 between 4 mm and 100 mm, such as between 5 mm and 50 mm, for example between 5 mm and 20 mm.
  • the width W1 of the utility space 10 may be determined in a direction parallel to a major surface 3b2 of the second, intermediate glass sheet 3b and perpendicular to a plane PL4 (See fig. 2 ) that touches and extends in the longitudinal direction of the side edge 7b of the second intermediate glass sheet 3b.
  • the utility space 10 may have a height of at least 5 mm, such as at least 8 mm, such as at least 10 mm, such as at least 15 mm.
  • the height may in embodiments of the present disclosure be defined perpendicular to a plane PL3 defined by/comprising the major surface 3b2 of the second intermediate glass sheet 3b (see fig. 2 ) from the surface of the bottom wall 11b (if present) or alternatively from the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b.
  • the height may be determined partly by the height of the edge seal 6a and the thickness of the glass sheet 3a, possibly with the thickness of the part 11b subtracted therefrom if present. This may be a minimum height of the utility space. by providing a larger/higher guiding wall 11a and a higher part 11c, the capacity of the utility space 11 may be increased.
  • the guiding wall 11a, bottom part 11b and side part 11c together provides a U-shaped utility space 10, which overlaps said side portion 8 and is placed next to the first edge seal 6a. Naturally, if the side part 11c is omitted, the utility space 10 will still be U-shaped.
  • the utility space 10 comprises an elongated opening 13 at a position opposite to the said side portion 8 of the major outer surface of the second, intermediate glass sheet 3b, thereby providing that e.g. rain water may enter the utility space and/or providing that equipment may be placed in the utility space 10.
  • An elongated cover 9b (and/or 9c or 9a dependent on design) extends over and covers a part of the elongated utility space 10. See also fig. 1 . This provides water tightening and/or advantageous handling of rainwater. In the example of fig. 3 , the width of the cover 9b extends over and covers the entire width W1 the elongated utility space.
  • Wind driven water or snow RW that is illustrated by the dashed-dotted arrow may enter the water drainage channel 10 from a space 30 between the cover 9b and the insulating glass unit 3.
  • the wind driven water or snow enters in between the cover and the insulated glass unit 3 in a direction transverse to the longitudinal direction of the drain channel 10, into the drain channel and flows therefrom towards the bottom of the window 1 due to gravity.
  • the guiding arrangement 11 as described above may in embodiments of the present disclosure be integrated in a holding arrangement 12, such as a holding profile.
  • the holding arrangement 12 is configured to fixate the insulating glass unit 3 at the frame arrangement 2, and the holding arrangement 12 comprises a fixation part 11e for fixating the holding arrangement 12 to the frame arrangement 2 by means of fixation means.
  • the fixation part 11e of the holding arrangement 12 is fixated to or at e.g. the exterior side of the frame profile 2c that is placed opposite to the frame opening provided by among others the frame profile 2c.
  • This fixation may be provided by means of fastening means such as mechanical fastening means, for example screws, pop rivets, nails or clips (not illustrated), additionally or alternatively, an adhesive may be used.
  • the holding arrangement 12 comprising the guiding arrangement 11 may in embodiments of the present disclosure comprise or be, such as consist of, an extruded, pultruded or moulded profile, that is fixated to the insulating glass unit 3 after it has been manufactured (see e.g. fig. 4 ), or it may comprise a holding arrangement 12 that is moulded directly onto the insulated glass unit (as e.g. illustrated in fig. 3 ).
  • the holding arrangement 12 may be made from a metal such as aluminium or steel, or a polymer such as a fibre reinforced polymer or the like.
  • the pane overlapping part 11d and/or the bottom part 11b may be fixated to the insulated glass unit 3. This may e.g. be provided by means of an adhesive connection.
  • the pane overlapping part 11d and/or the bottom part 11b may be configured so as to provide a fixation, such as a mechanical fixation, of the insulating glass unit 3, so as to fixate the insulating glass unit to the frame arrangement 2.
  • a fixation such as a mechanical fixation
  • said pane overlapping part 11d and/or said bottom part 11b may provide a fixation, such as a mechanical fixation, of the insulating glass unit 3, for example by means of a clamping force.
  • the utility space 10 solution according to the present disclosure may help to provide a space saving solution.
  • the distance DIS3 such as the maximum distance, between a first plane PL1 defined by an outer surface 9x of the side cover 9b and a second plane PL2 defined by/comprising the outer major surface 3a2 of the first, outer glass sheet 3a may be less than 30 mm, such as less than 20 mm, preferably less than 10 mm, such as less than 5 mm.
  • the first and second planes PL1, PL2 are considered substantially parallel.
  • the distance DIS3 such as the maximum distance, between the outer surface 9x of the cover 9b and a plane PL2 defined by the outer major surface of the first, outer glass sheet may be less than 50 mm, such as less than 20 mm, preferably less than 10 mm, such as 6 mm or less than 6 mm. This distance DIS3 may be determined perpendicular to the outer major surface 3a2 of the first, outer glass sheet.
  • the outer surface 9x of the cover is substantially plane.
  • the first plane PL1 defined by the outer surface 9x of the cover may be defined from a point of the cover surface providing the maximum distance between that plane PL1 and the second plane PL2 defined by the major outer surface of the outer glass sheet, where these planes are substantially parallel.
  • the outer surface 9x of the cover 9b may face away from the first plane PL1.
  • the utility space 10 solution according to the present disclosure enables a more space saving frame solution.
  • the utility space 10 is so to say integrated in the side part(s) of the insulated/insulating glass unit 3, there may not be a need for placing e.g. a water drainage channel at the frame arrangement, next to the outermost side of the insulated glass unit for handing e.g. wind driven rain and/or snow. Or at least the space consumption of such a drainage channel next to the outermost side of the insulated glass unit may be reduced.
  • This enables providing a more narrow frame arrangement. For example, the width/thickness of the frame part 14, placed next to the second edge sealing 6b may be reduced.
  • This frame part 14 may hence have a width(Thickness that is less than 10 mm, such as less than 7 mm, for example less than 5 mm, such as around or less than 3mm. As can be seen, this may e.g. provide a more space saving, movable frame 2 solution, see for example fig. 8 .
  • the width/thickness W3 of the frame part 14 opposite to the second edge seal 6b may in embodiments of the present disclosure be between 1 mm and 10 mm, such as between 1 mm and 7 mm, for example between 1 mm and 4 mm.
  • This width/thickness W3 may be defined in a direction parallel to a major surface 3b1 of a glass sheet if the insulating glass unit 3.
  • the holding arrangement 12 may be unitary with the overlapped profile 2c.
  • the holding arrangement 12, that may also comprise the guiding arrangement 11, may be an integrated part of the frame profile 2c.
  • the fixation part 11e and preferably also one or more of the parts 11b, 11a, 11c and/or 11d may here be integrated in/be unitary with, the frame profile 2c. This may be obtained by means of a moulding process and/or a welding/fusing process.
  • At least the guiding wall 11a, bottom part 11b and side part 11c that together provides a U-shaped utility space 10 opposite to the portion 8 may be integrated with/unitary with the fixation part 11e and the frame profile 2c, such as integrated with/unitary with an exterior wall of the frame profile 2c.
  • Fig. 4 illustrates schematically a cross sectional view of a side part of a roof window 1, according to further embodiments of the present disclosure.
  • the guiding arrangement 11 is here integrated in a profile that is fixated to the insulating glass unit 3 after it has been manufactured (see e.g. fig. 4 ).
  • the profile may here be a loose "stand-alone" profile that is attached to the insulating glass unit 3 by means of a sealant and/or an adhesive.
  • This profile may comprise the same parts 11a, 11b, 11c, 11d as described above, but tolerance spaces 40 may be provided between one or more parts 11a, 11b, 11c, 11d of the profile and the insulated glass unit 3.
  • the pane overlapping part 11d is fixated to the exterior major surface 3a2 of the insulating glass unit 3 by means of a sealing arrangement 25 additionally or alternatively, an adhesive such as an adhesive tape may be used (not illustrated).
  • Fig. 4 illustrates a further embodiment of the present disclosure where a drip edge 60 is provided at the cover 9b.
  • the drip edge is provided by means of an elongated elevation, such as a ridge comprising/providing the drip edge 60.
  • the drip edge is placed opposite to the water drainage channel 10 and may in further embodiments of the present disclosure (as illustrated) even extend into the water drainage channel.
  • the elevation comprising the drip edge 60 comprises a crest extending in a direction towards the water drainage channel 10.
  • the ridge extends in the longitudinal direction of the cover 9 and parallel to the longitudinal direction of the water drainage channel 10.
  • Fig. 5 illustrates an embodiment of the present disclosure where the bottom wall 11b is fixated to the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b by means of a sealant and/or an adhesive 36 such as an adhesive tape (not illustrated). This may provide the primary structural fixation of the insulating glass unit 3 to the profile comprising the guiding arrangement 11.
  • Fig. 5 moreover illustrates an embodiment of the present disclosure where the pane overlapping part 11d (se figs 3 or 4 ) is omitted from the guiding arrangement 11.
  • a sealant 37 such as a resilient, adhesive joint, may be provided between the side part 11c, such as a sidewall, of the guiding arrangement 11 and the insulating glass unit 3.
  • Fig. 6 illustrates schematically a cross sectional view of a side part of a roof window 1 comprising an insulating glass unit 3 with three insulating gaps 4a-4c, according to further embodiments of the present disclosure.
  • the side portion 8 of the major surface 3b2 of the intermediate glass sheet 3b extends with a distance DIS1 past both the side edge 7a of the a first, outer glass sheet 3a, and moreover past a side edge 7d of a further glass sheet 3d that is placed between the outer glass sheet 3a and the intermediate glass sheet 3b.
  • the side portion 8 of the major surface 3b2 of the second, intermediate glass sheet 3b also extends with a distance DIS2 past outer sides 6ae, 6ce of the first edge seal 6a and third edge seal 6c respectively that faces away from the respective insulating gap 4a, 4c, so as to provide the elongated utility space 10 that which overlaps the side portion 8 and is placed opposite to the outer side surfaces 6ae, 6ce of the edge seals 6c, 6a and the glass sheet edges 7d, 7a.
  • the third edge seal 6c is also, as edge seal 6a, displaced with a distance DIS2 to the plane PL4 as previously described.
  • the height of the utility space 10 (if the guiding arrangement 11 was omitted) is at least the sum of the height of the two edge seals 6a, 6b, and the sum of the thickness of the glass sheets 3a, 3d.
  • Fig. 7 illustrates schematically a cross sectional view of a side part of a roof window 1 comprising an insulating glass unit 3 with three insulating gaps 4a-4c, according to embodiments of the present disclosure.
  • a further insulating gap 4c is placed proximate the frame profile 2c and overlaps the profile.
  • the lamination glass sheet 3L is attached to the inwardly facing, major surface 3c1 as previously described, see e.g. fig. 2 .
  • the second insulating gap 4b is hence placed between the between the glass sheets 3b, 3d, between the gap 4a and the gap 4c.
  • the utility space 10 may be substantially corresponding to the utility space 10 described above in relation to the various embodiments of figs. 2-5 .
  • the further insulating gap 4c in fig 7 also overlaps the first edge seal 6a, and the edge seal 6c the further gap 4c is placed opposite to the second edge seal 6b so that the further edge seal 6c is located opposite to, such as below, the elongated utility space 10.
  • heat insulation performance may e.g. be improved in the embodiments of figs. 6 or 7 .
  • the capacity of the utility space is increased compared to the embodiments of for example figs. 2 , 3 , 4 and 7 .
  • Fig. 8 illustrates an embodiment of the present disclosure, where the cover 9b only extends partly over the width W1 of the elongated utility space.
  • the cover 9b extends over the entire width the elongated utility space, and preferably also overlaps the outer major surface of the insulated glass unit.
  • the side edge of the cover 9b is bended towards the utility space 10 to provide a drip edge 60 so water drips into the utility space that in fig. 8 is a water drainage channel.
  • the drip edge may also provide protection from wind driven water.
  • the outer surface 9x of the cover 8 and the outer major surface 9a2 may be substantially flush.
  • the first and second planes PL1, PL2 as illustrated in fig. 3 may be substantially coinciding, which would be the case in fig. 8 .
  • the outer surface 9x of the cover 8 and the outer surface of the pane overlapping part 11d may be substantially flush.
  • the insulated/insulating glass unit 3 comprises a plurality of said utility space 10 extending along different sides of the insulated glass unit 3.
  • opposing, parallel utility spaces 10 may be arranged at opposing parallel sides of the insulated glass unit. These sides may in some embodiments be at sides, such as hinged 30 sides, that extends between the top and bottom of the insulated glass unit.
  • fig. 9 is a cross sectional, schematic view of a roof window 1 of the centre hung type, according to embodiments of the present disclosure.
  • the outer glass sheet 3a has a width (see W5 in fig.
  • covers 9 extends over and covers a part of the fixation frame 20 and the insulated glass unit, in this case to fully overlap the width W1 (see e.g. fig. 3 ) of the respective utility space 10.
  • the hinge arrangement 30 movably connects the movable frame 2 and the fixation frame 20, and as can be seen, the fixation frame 20 surround movable frame 2 as the window 1 is of the centre-hung type.
  • Fig. 10 illustrates an insulating glass unit 3 according to an embodiment of the present disclosure.
  • elongated, parallel utility spaces are placed at opposing sides of the insulating glass unit 3.
  • the outer glass sheet 3a (see e.g. fig. 9 ) providing the major surface 3a2 has a width W5 that is smaller than the width W6 of the intermediate glass sheet 3b, thereby providing the utility space 10 above the respective surface portions 8.
  • the glass sheets of the insulating glass unit 3 have substantially the same length/height.
  • Fig. 11 illustrates a further embodiment of the present disclosure, substantially corresponding to the embodiment of fig. 10 , but where a utility space 10 is moreover provided at a top part of the insulated glass unit 3.
  • This top part is to be placed at the T of the window, such as the top T of a movable frame (See fig. 1 .
  • the longitudinal direction of the elongated utility space 10 at the top extends in a direction perpendicular to the longitudinal direction of the parallel utility spaces 10 at the opposing sides.
  • a transition between the utility space 10 at the top and the parallel utility spaces 10 is provided, and water from the upper utility space may enter into one or both parallel utility spaces providing the surface 3a2 at this transition at the corner areas 80.
  • the utility space 10 at the top may be placed so that a top cover (see fig 1 , ref. 9c) overlaps it, as previously described , and hence, wind driven water entering in between the insulated glass unit 3 and the top cover will be collected by the utility space 10 at the top.
  • wires may be bended around one or both upper corners of the outer glass sheet providing the outer surface 3a2.
  • the height/length of the outer glass unit providing the major surface 3a2 is less than the height/length of the intermediate glass sheet (providing the edge 7b), so as to provide the upper/top utility space.
  • the side edges 7a, 7b extends in a longitudinal direction LD, and that longitudinal direction LD is parallel to the longitudinal direction of the respective elongated utility space(s) 10.
  • Figs. 10 and 11 have the feature in common that surface area of the major surfaces 3a2, 3a1 of the exterior glass sheet 3a (see also these references in previous figures) is smaller than the surface area of the major surfaces 3b2, 3b1, 3c, 3c1 of the second intermediate glass sheet 3b, and the third glass sheet.
  • Fig. 12 illustrates schematically a roof window 1 according to embodiments of the present disclosure that is installed in the roof structure 110 of a building 100.
  • the roof window 1 installed in the roof structure 110 where the roof structure 110 has a roof pitch above 15°, such as above 25°, such as above 35°.
  • the outer glass sheet surface 3a2 will hence be placed with an angle relative to horizontal, that may be above above 15°, such as above 25°, such as above 35°.
  • Fig. 13 illustrates schematically an insulating/insulated glass unit 3 according to embodiments of the present disclosure.
  • the exterior surface 6ae of the first edge seal 6a that faces away from the insulating gap 4a, and the interior surface 6bi of the second edge seal 6b that faces towards the insulating gap 4b are substantially flush.
  • the interior surface 6bi of the second edge seal 6b may be placed below and extend away from the first edge seal 6a.
  • the insulating gap 4b fully overlaps the first edge seal 6a and extends beyond the exterior surface 6ae of the first edge seal to a position below the utility space 10 where it ends/is terminated at the interior surface 6bi of the second edge seal 6b.
  • Fig. 14 illustrates schematically an embodiment of the present disclosure, where the edge 7b of the intermediate glass sheet 3b and the exterior surface 6be of the second edge seal 6b that seals the gap 4b overlaps OD1 a part, such as the major part, of the maximum width MW1 of the frame profile 2c.
  • the line of sight LS is where the transition between the visible part of the interior major surface 3Li of the insulating glass unit and the part of the surface that is hidden by the frame arrangement or gasket 2c, 2, 35 is provided. This may help to reduce condensation at the visible part of the interior major surface 3Li near the frame profile.
  • the interior major surface is provided by the major interior surface 3Li of a lamination glass.
  • the edge 7b of the intermediate glass sheet and the exterior surface 6be of the second edge seal 6b may be placed opposite to the half, such as the third of the profile's 2c width MW1 that is distal to the frame opening FO of the frame.
  • the overlapping distance OD1 with which the edge 7b of the intermediate glass sheet 3b and/or the exterior surface 6be of the second edge seal 6b overlaps the maximum width MW1 of the profile 2c may be at least 40%, such as at least 55%, such as at least 80% of the maximum width MW1 of the frame profile 2c.
  • the second insulating gap 4b that is sealed by the second edge seal 6b may overlap OD2 at least 30%. Such as at least 40%, such as at least 50%, such as at least 60% of the maximum width MW1 of the frame profile 2c. In fig. 14 , the second insulating gap 4b that is sealed by the second edge seal 6b overlaps approximately 50% of the maximum width MW1 of the frame profile 2c. Generally, OD1 may be larger than OD2, due to the width of the second edge seal 6b.
  • the edge 7b of the intermediate glass sheet 3b and the exterior surface 6be of the second edge seal 6b overlaps the maximum width MW1 of the profile 2c with a larger overlapping distance OD1 than the distance with which the edge 7a of the glass sheet 3a and the exterior surface 6ae of the first edge seal 6a overlaps the maximum width MW1 of the profile 2c.
  • Fig. 14 illustrates a further embodiment of the present disclosure, where the surface 90 of the frame profile 2c that faces the frame opening FO is arranged inclining towards the interior surface 3Li of the insulating glass unit 3.
  • the surface 90 is arranged substantially perpendicular to the surface 3Li.
  • the frame profiles 2a-2d, 20a-20d may be hollow and comprise one or more interior spaces 95 that are enclosed by walls of the profile.
  • This/these spaces 95 may be filled with a heat insulating material (not illustrated), and/or may comprise one or more air spaces for insulation purposes.
  • the interior 95 of the frame profiles may be massive, e.g. provided by a massive wood profile.
  • the holding arrangement 12 and/or guiding arrangement 11 may be made from the same material as the overlapped profile 2a-2d wall(s), and e.g. be integrated therewith (as previously described) or be separate thereto (as previously described) and attached by means of mechanical fastening means.

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EP22169649.5A 2022-04-25 2022-04-25 Dachfenster mit einer isolierglaseinheit mit nutzraum Pending EP4269715A1 (de)

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EP22169649.5A EP4269715A1 (de) 2022-04-25 2022-04-25 Dachfenster mit einer isolierglaseinheit mit nutzraum

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2947253A1 (de) * 2014-05-22 2015-11-25 Roto Frank Ag Fenster, insbesondere wohndachfenster, mit einer dämmung und mindestens einem abdeckblech
EP2843151B1 (de) 2013-08-28 2019-07-31 FAKRO PP Sp. z o.o. Dachfenster, mindestens kippfenster
EP3795770A1 (de) * 2020-02-03 2021-03-24 VKR Holding A/S Dachfenster
CN214117278U (zh) * 2020-09-21 2021-09-03 深圳时代装饰股份有限公司 一种装配式防水玻璃采光顶

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2843151B1 (de) 2013-08-28 2019-07-31 FAKRO PP Sp. z o.o. Dachfenster, mindestens kippfenster
EP2947253A1 (de) * 2014-05-22 2015-11-25 Roto Frank Ag Fenster, insbesondere wohndachfenster, mit einer dämmung und mindestens einem abdeckblech
EP2947253B1 (de) 2014-05-22 2017-07-12 Roto Frank Ag Fenster, insbesondere wohndachfenster, mit einer dämmung und mindestens einem abdeckblech
EP3795770A1 (de) * 2020-02-03 2021-03-24 VKR Holding A/S Dachfenster
CN214117278U (zh) * 2020-09-21 2021-09-03 深圳时代装饰股份有限公司 一种装配式防水玻璃采光顶

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