A refrigerator for storing food includes a multiple-glazed refrigerator door which is configured to be pivotable or slidable, and an access opening which is configured to be closed by the multiple-glazed refrigerator door. The multiple-glazed refrigerator door comprises edge-side spacer elements, a transparent vertical edge, a vertical transparent spacer element comprising a transparent material arranged at the transparent vertical edge of the multiple-glazed refrigerator door, at least one of a horizontal frame element and a vertical frame element configured to have the multiple-glazed refrigerator door be mounted thereon, and at least two transparent glass panes which are spaced apart from each other via the edge-side spacer elements. The access opening is arranged in a vertical plane. No supporting vertical frame element is arranged at the transparent vertical edge of the multiple-glazed refrigerator door.

A patch fitting for a fire-retardant glass door is disclosed herein. The patch fitting comprises a support sandwiched between a first layer of fire retardant material on a first side of the support and a second layer of fire retardant material on an opposing second side of the support. The support comprises a first attachment means for attaching to a first pane of glass of the fire-retardant glass door on the first side of the support, and a second attachment means for attaching to a second pane of glass of the first-retardant glass door on the opposing second side of the support. The patch fitting is configured, in use, to be at least partially sandwiched between the two layers of glass of the firm-retardant glass door.

A foldback door system for at least partially closing an opening having at least one plane, the system including at least two mutually pivoted panels movable between a closed condition relative to a frame having at least one jamb relative to which the at least two mutually pivoted panels are hung, the at least two panels including a lateral panel located closer to the jamb and an inner panel hinged relative to the lateral panel and the frame, the lateral panel being of a first dimension and the inner panel being of a second dimension different to the first dimension, the closed condition in which the at least two panels are in substantial alignment to at least partially close the opening and a fully open, foldback condition in which the at least two panels are substantially parallel with one another and lie at an angle of greater than 90° with respect to the at least one plane of the opening in which the at least two panels lie in the closed condition.

The invention relates generally to the field of construction, and in particular to the use of a glass unit instead of the opening sashes of windows and doors, without using sash profiles into which conventional insulating glass units or insulating glass units with one protruding outer pane are usually fixed. The adaptive insulating glass unit is intended for use on windows and doors pre-installed in an opening or facade, as well as for use in the production of new windows and doors, which in turn are used for glazing door and window openings (fixed glazing or one with a sash opening inward, sideways, outward or upward off the frame) in residential buildings, in public and industrial buildings, display structures. The technical result of the invention is a quicker and more accurate assembly of multi-chambered insulating glass units with glued-in profiles, increased light transmission, thermal insulation and soundproofing properties of existing window and door systems without the need to reconfigure production processes, without the need to readjust and replace equipment used in the production of windows, as well as increased light transmission, thermal insulation and soundproofing properties of window and door systems pre-installed in the openings and facades of buildings without the need to reinstall them. The adaptive insulating glass unit designed to be used instead of the opening sashes of windows and doors, without the use of sash profiles into which conventional insulating glass units or insulating glass units with one protruding outer pane are usually fixed, offers new prospects for the design of new window and door systems. The adaptive insulating glass unit contains two outer panes and at least one inner pane, spaced from each other by spacer frames placed between the panes. Moreover, the outer panes are always larger than the inner ones, and between them there is a profile inserted all the way to all the inner panes and simultaneously to one of the outer panes and glued to said outer pane by means of hard glue with additional fixation of the glued profile to another outer pane through the aid of a spacer element, with the gap formed between the profile and the outer pane to which the profile is not glued by means of hard glue filled with elastic glue and sealant, with the outer part of the profile adapted to fixing fittings and seals, which adapt the adaptive insulating glass unit to specific window systems.

The present disclosure relates to a roof window (1) with a vacuum insulated glass unit (3). The roof window (1) comprises a VIG unit (3) and a frame arrangement (2). The frame arrangement 2 comprises a fixation frame (7) and a sash (6) fixed to the a VIG unit (3), and the sash (6) is movably connected to the fixation frame (7) by means of a hinge connection (80) so that a top end part (16a) of the sash (6) is configured to move inwards and a bottom end part (16b) of the sash is configured to move outwards when opening the sash (6) from a closed position. The bottom end part (16b) of the sash (6) comprises an elongated, structural bottom member (6c) having an inner surface (41) facing towards the top end part (16a) of the sash, and an opposite exterior surface (42) facing away from the top end part (16a). The VIG unit (3) comprises an overlapping part (9b) where the evacuated gap (4) overlaps the elongated, structural bottom member (6c) of the sash (6). The overlapping part (9b) of the VIG unit moreover overlaps at least a part of an elongated bottom frame member (7c) of the fixation frame 7.

A vacuum insulated glass (VIG) unit frame assembly (10) is disclosed, comprising: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a sealed gap (11), wherein a plurality of support structures (12) are distributed in said gap (11), and a frame (20) comprising elongated frame profile arrangements (20a-20d) which frames said vacuum insulated glass unit (1) in a frame opening (21), and wherein said frame (20) comprises a fixation system (45a, 45b, 28a, 28b, 80, 22, 23) fixating the vacuum insulated glass unit (1) at the frame (20), wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is arranged so as to allow edges (8a-8d) of said vacuum insulated glass unit (1) to thermally deflect (DIS4) in a deflection direction (D1, D2) perpendicular to said frame opening due to a temperature difference (ΔT=T1−T2) between the two glass sheets (2a, 2b), wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is configured to allow the magnitude of said thermal deflection (DIS4) to vary along the edge (8a-8d) between the corners (9) where the respective edge (8a-8d) terminates, wherein said fixation system (45a, 45b, 28a, 28b, 80, 22, 23) is arranged to provide a resistance against said thermal deflection (DIS4) of at least two opposing edges (8a-8d) of said vacuum insulated glass unit (1), said resistance being substantially lower at corner parts of the edges (8a-8d) than at centre parts of the edges (8a-8d), and wherein said centre parts of said at least two opposing, parallel edges (8a-8d) constitute at least a third, such as half of the extend of the edge (8a-8d) between said corners (9).

The present disclosure relates to an aperture cover such as a window or a door. The aperture cover comprises a vacuum insulated glass unit (3), and a frame (2, 17) such as a sash. The frame (2, 17) comprises elongated structural frame members (8) which together encloses a frame opening (2a). The vacuum insulated glass unit (3) overlaps (18) at least one of the elongated structural frame members (8) so that the edge surface (7) of the vacuum insulated glass unit (3) extends beyond the outer side surface (14) of the overlapped elongated structural frame member (8). The frame (2) moreover comprises an elongated connection profile (6) comprising a connection wall member (6a) which extends parallel to the overlapped structural frame member (8) and is connected to at least one of the outer major surfaces (S1, S2) of the vacuum insulated glass unit (3), and the elongated connection profile (6) comprises a fixation member (6b) which is connected to the overlapped structural frame member (8).

The present disclosure relates to a swing door system, preferably for use with a chiller device or freezer device, including at least one swing door, a mullion and a sealing element. The at least one swing door includes a transparent pane and the sealing element is arranged between the swing door and the mullion in a closed position of the swing door. The mullion is translucent at least in part.

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 an aperture covering, such as a building aperture covering. The aperture covering comprises a VIG unit 3 and a frame. The frame (2) comprises elongated fixation profiles (6) each of which are fixed to and arranged parallel to an elongated structural frame member (8). The fixation profile (6) comprises a fixation wall (6a) which extends opposite to an exterior major surface (S1) of the vacuum insulated glass unit (3) and is fixed to the exterior major surface (S1) of the vacuum insulated glass unit (3) by means of a bonding seal (9). The fixation profile (6) comprises a connection member (6b) extending from the fixation wall (6a), wherein the connection member (6b) is fixed to the elongated, structural frame member (8). The elongated structural member (8) faces the opposite interior major surface (S2) of the vacuum insulated glass unit (3) placed opposite to the exterior major surface (S1) of the vacuum insulated glass unit.