The present disclosure relates to an aperture cover (1) such as a window. The aperture cover comprises a vacuum insulated glass unit (3) and a frame (2). The frame (2) comprises a fixation frame (7) and a sash (6) fixed to the vacuum insulated glass unit (3), and wherein the sash (6) is movably connected to the fixation frame (7) by means of a hinge connection (80). The fixation frame (7) comprises elongated frame members (8a-8d) defining a frame opening (2a) and the vacuum insulated unit (3) overlaps a surface (11) of at least one elongated frame member (8a-8d) of the fixation frame (7). The sash (6) comprises a sash profile (13) which is fixed to the vacuum insulated glass unit (3) at a part (21, 22) of the vacuum insulated glass unit that overlaps (21) and/or extends beyond (22) the overlapped elongated frame member (8a-8d). A resilient sealing gasket (10) is arranged between the overlapped elongated frame member (8a-8d) and the vacuum insulated glass unit, and the resilient sealing gasket (10) is configured to abut the interior major surface (S2) of the vacuum insulated glass unit when the sash (6) is in a closed position. The interior major surface (S2) of the vacuum insulated glass unit is configured to compress the resilient sealing gasket (10) when moving the sash (6) from an open to a closed position.

The present disclosure relates to an aperture cover (1) such as a window. The aperture cover comprises a vacuum insulated glass unit (3) and a frame (2). The frame (2) comprises a fixation frame (7) and a sash (6) fixed to the vacuum insulated glass unit (3), and wherein the sash (6) is movably connected to the fixation frame (7) by means of a hinge connection (80). The fixation frame (7) comprises elongated frame members (8a-8d) defining a frame opening (2a) and the vacuum insulated unit (3) overlaps a surface (11) of at least one elongated frame member (8a-8d) of the fixation frame (7). The sash (6) comprises a sash profile (13) which is fixed to the vacuum insulated glass unit (3) at a part (21, 22) of the vacuum insulated glass unit that overlaps (21) and/or extends beyond (22) the overlapped elongated frame member (8a-8d). A resilient sealing gasket (10) is arranged between the overlapped elongated frame member (8a-8d) and the vacuum insulated glass unit, and the resilient sealing gasket (10) is configured to abut the interior major surface (S2) of the vacuum insulated glass unit when the sash (6) is in a closed position. The interior major surface (S2) of the vacuum insulated glass unit is configured to compress the resilient sealing gasket (10) when moving the sash (6) from an open to a closed position.

A flashing assembly for use with a roof penetrating structure, such as a roof window, in an inclined roof of a building is disclosed. It comprises a bottom flashing element and at least one side flashing element, both of which are provided with a bend portion bent away from the interior side towards the exterior side and forming a water drainage channel, which extends along an edge. The dimensions of the flashing elements are such that the two water drainage channels extend in continuation of each other in the mounted condition of the flashing assembly, and least one of the water drainage channels has a U-shape in a cross-section perpendicular to the edge of the flashing element along which is extends. A method for manufacturing a flashing assembly is also disclosed.

A roof structure adjustable support frame system comprising a plurality of joist rails configured to adjust longitudinally; a plurality of side rails configured to adjust longitudinally between the plurality of joist rails; a plurality of corner rail connectors configured to couple a side rail to a joist rail; and a plurality of adjustable joist rail connectors. The plurality of adjustable joist rail connectors comprise a joist rail attachment configured to removably attach to an end of the joist rail, an extension support member extending longitudinally from a first end of the joist rail attachment, a hook assembly configured to move longitudinally along the extension support member and engage a roof joist to couple the joist rail to the joist; and a movable stop configured to secure the hook assembly against the roof joist.

The present disclosure relates to a vacuum insulated glass (VIG) unit frame assembly (10), wherein said vacuum insulated glass unit frame assembly (10) comprises: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a gap (11) between said glass sheets (2a, 2b), wherein a plurality of support structures (12) are distributed in said gap (11) and wherein said gap (11) is sealed, and a frame (20) comprising elongated frame profile arrangements (20a-20d, 70) arranged to provide a frame opening (21) extending in a frame opening plane (P2) defined between the elongated frame profile arrangements (20a-20d, 70). A plurality of edges (8a-8d) of said rectangular vacuum insulated glass unit (1) overlaps an elongated frame profile arrangement (20a-20d, 70) of said frame (20), and an inwardly directed, major surface (4a, 4b, 15, 35a) of a glass sheet (2a, 35a,) of the vacuum insulated glass unit (1) is bonded to the overlapped elongated 15 frame profile arrangement (20a-20d, 70) by means of a structural adhesive (45a). Said overlapping edges (8a-8d) of the vacuum insulated glass unit (1) are allowed to thermally deflect (DIS4) relative to said elongated frame profiles (20a-20d, 70) in a deflection direction (D1, D2) perpendicular to said frame opening plane (P2) due to a temperature difference (ΔT=T1−T2) between the two glass sheets (2a, 2b), and wherein said allowed thermal deflection of the overlapping edges (8a-8d) is allowed to have a varying magnitude along the edge (8a-8d) between the corners (9) where the respective edge (8a-8d) terminates. The present disclosure additionally relates to a vacuum insulated glass unit.

The roof window system (1) is configured for being mounted in an opening in a roof structure (23) of a building and includes a ventilation unit (5) configured for being mounted adjacent to a roof window (13) and adapted for providing ventilation of the interior of the building in which the roof window is mounted. The roof window comprises a frame (2) defining a frame plane and including a pane (4) mounted in said frame. The frame comprises a top frame member (2a) intended for being located highest in the mounted state when seen in the direction of inclination of the roof structure, a bottom frame member opposite the top frame member, and two side frame members extending between the top frame member and the bottom frame member, said frame members together form a window structure delimiting a frame opening and each having an interior side (2f) intended for facing the interior in the mounted state, an exterior side intended for facing the exterior, an inner side (2d) facing the frame opening and an outer side (2e) facing away from the frame opening. The ventilation unit is configured for being arranged primarily adjacent to the outer side of a frame member, and comprises a lower side (24) configured for being arranged adjacent to or at the interior side (2f) of said frame member (2a). The roof window system further comprises a ventilation panel (3) allowing air passage from one side of the ventilation panel to another side of the ventilation panel, thereby defining an intended air flow direction, said ventilation panel being configured for facing the interior of the building and extending away from the interior side of the frame member adjacent to which the ventilation unit is mounted.

Herein is disclosed a vacuum insulated glass (VIG) unit frame assembly (10) comprising: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a sealed gap (11) comprising a plurality of support structures (12), and a frame arrangement (20) comprising a fixation system (6, 40) fixating the vacuum insulated glass unit (1) at the frame arrangement (20), wherein said fixation system (6, 40) is arranged so as to allow edges (8a-8d) of said vacuum insulated glass unit (1) to thermally deflect (DIS1, DIS2) in a deflection direction (D1, D2) perpendicular to a frame opening plane (P2) due to a temperature difference (ΔT=T1−T2) between the two glass sheets (2a, 2b), wherein said fixation system (6, 40) is configured so as to allow the magnitude of said thermal deflection (DIS1, DIS2) is configured to vary along the edge (8a-8d) between the corners (9) where the respective edge (8a-8d) terminates.

Herein is disclosed a vacuum insulated glass (VIG) unit frame assembly (10) comprising: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a sealed gap (11) comprising a plurality of support structures (12), and a frame arrangement (20) comprising a fixation system (6, 40) fixating the vacuum insulated glass unit (1) at the frame arrangement (20), wherein said fixation system (6, 40) is arranged so as to allow edges (8a-8d) of said vacuum insulated glass unit (1) to thermally deflect (DIS1, DIS2) in a deflection direction (D1, D2) perpendicular to a frame opening plane (P2) due to a temperature difference (ΔT=T1−T2) between the two glass sheets (2a, 2b), wherein said fixation system (6, 40) is configured so as to allow the magnitude of said thermal deflection (DIS1, DIS2) is configured to vary along the edge (8a-8d) between the corners (9) where the respective edge (8a-8d) terminates.

The present disclosure relates to a vacuum insulated glass (VIG) unit frame assembly (10), wherein said vacuum insulated glass unit frame assembly (1) comprises: a vacuum insulated glass unit (1), and a frame (20) comprising elongated frame profile arrangements (20a-20d, 70) which frames said vacuum insulated glass unit (1) in a frame opening (21). The frame further comprises: —holding parts (6) for fixating said vacuum insulated glass unit (1), and—flexible connection arrangements (7) connecting the holding parts (6) to elongated frame profile arrangements (20a-20d). The flexible connection arrangements (7) are configured to flex when said vacuum insulated glass unit (1) exerts a bending moment (M) on the holding parts (6), so that said holding parts (6) will move relative to the elongated frame profile arrangements (20a-20d, 70) to which the individual holding part (6) is connected. The present disclosure moreover relates to a vacuum insulated glass unit and a frame.

A connector arrangement for a flashing assembly for use in a roof window arrangement is disclosed. It comprises a base connector element, an elevation element and a top connector element. Both connector elements have a gutter in their exterior side, and the gutter is open at one end so that water can drain out of it. An attachment section on the interior side of the base connector element is configured for being attached to a bracket used for connecting a roof window to a load-bearing structure, and the elevation element supports the top connector element so that it is positioned above the base connector element. In the mounted state the second end of the top connector element is arranged above the gutter of the base connector element and their length directions extend substantially in parallel to each other. A method for weather proofing a roof window arrangement is also disclosed.