A glass door construction set in a pre-existing frame includes glass door leaves made of two or more panes of glass, which define a top edge, a bottom edge, and two lateral edges. The top and bottom edges include a top and bottom rail, respectively, to enhance the structural integrity of the glass door leaves. The lateral edges, however, remain free of the typical perimeter framing required on current glass doors to meet the stringent impact standards. The glass door leaves each include handles on either side of the glass leaves that are interconnected to effectively create a structural equivalent of an I-beam. The handles provide the necessary structural rigidity along a vertical extent to meet impact standards.

A glass door construction set in a pre-existing frame includes glass door leaves made of two or more panes of glass, which define a top edge, a bottom edge, and two lateral edges. The top and bottom edges include a top and bottom rail, respectively, to enhance the structural integrity of the glass door leaves. The lateral edges, however, remain free of the typical perimeter framing required on current glass doors to meet the stringent impact standards. The glass door leaves each include handles on either side of the glass leaves that are interconnected to effectively create a structural equivalent of an I-beam. The handles provide the necessary structural rigidity along a vertical extent to meet impact standards.

The invention provides a glass door apparatus with a right and a left glass door leaf (10, 100) and functional end caps (40a, 40b, 240a, 240b), which respectively have a protrusion (52a, 52b, 252a, 252b), which, with respect to a lateral front face of the functional end cap protrudes laterally outwards in a manner at least substantially parallel to a pane face of a glass pane of one glass door leaf as well as away from said glass pane, and/or a cavity (54a, 54b, 254a, 254b) which, with respect to said lateral front face, protrudes laterally inwards in a manner is at least substantially parallel to said pane face and towards said glass pane and which, in the opposite direction, opens laterally outwardly, and wherein, in the closed state of glass door apparatus, the protrusion and/or the cavity is/are overlapped with a complementary counterpiece of the other glass door leaf.

The invention provides a glass door apparatus with a right and a left glass door leaf (10, 100) and functional end caps (40a, 40b, 240a, 240b), which respectively have a protrusion (52a, 52b, 252a, 252b), which, with respect to a lateral front face of the functional end cap protrudes laterally outwards in a manner at least substantially parallel to a pane face of a glass pane of one glass door leaf as well as away from said glass pane, and/or a cavity (54a, 54b, 254a, 254b) which, with respect to said lateral front face, protrudes laterally inwards in a manner is at least substantially parallel to said pane face and towards said glass pane and which, in the opposite direction, opens laterally outwardly, and wherein, in the closed state of glass door apparatus, the protrusion and/or the cavity is/are overlapped with a complementary counterpiece of the other glass door leaf.

The present invention relates to a glazed element with improved water tightness comprising a fixed frame, at least one gasket G.sub.a and at least one frameless inwardly openable casement wherein the casement comprises a multiple glazing comprising in external position a glass pane including at least one thermally treated glass sheet, the glass pane has an overall bow on at least its bottom edge of at most 3.0 mm/m and the gasket G.sub.a is such that it is in continuous contact with the fixed frame and with at least the bottom edge of the glass pane, when the glazed element is in closed position.

Perimeter frame for sliding glass doors of the type including extruded metal profiles that are combined together circumferentially surrounding the glass sheet having two lateral profiles (1) arranged vertically and that fit on the sides of the glass sheet (4), a set of lower profiles (2) arranged horizontally on each side of the glass sheet (4) at its lower part and a set of upper profiles (3) arranged vertically in the upper area of the sheet glass (4), between which there is provided an opening (5) through which protrudes the upper portion of the glass (6), in which the clamps (7) that hold the sheet are applied.

Perimeter frame for sliding glass doors of the type including extruded metal profiles that are combined together circumferentially surrounding the glass sheet having two lateral profiles (1) arranged vertically and that fit on the sides of the glass sheet (4), a set of lower profiles (2) arranged horizontally on each side of the glass sheet (4) at its lower part and a set of upper profiles (3) arranged vertically in the upper area of the sheet glass (4), between which there is provided an opening (5) through which protrudes the upper portion of the glass (6), in which the clamps (7) that hold the sheet are applied.

A vacuum insulated glass unit frame assembly includes a rectangular vacuum insulated glass unit having two glass sheets separated by a sealed gap with a plurality of support structures, and a frame arrangement including a fixation system fixating the vacuum insulated glass unit at the frame arrangement, where the fixation system is arranged so as to allow edges of said vacuum insulated glass unit to thermally deflect in a deflection direction perpendicular to a frame opening plane due to a temperature difference between the two glass sheets, where the fixation system is configured so as to allow the magnitude of the thermal deflection to vary along the edge between the corners where the respective edge terminates.

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 fire-rated sliding elevator glass door is provided. The door includes a face panel, a liner, a fire-rated glass panel, and a retainer that retains the glass panel in the door frame. The elevator door is configured to pass a 90-minute fire rating test. The elevator door can be implemented as a single-speed side open elevator door, a single-speed center open elevator door, a two-speed side opening sliding elevator door, or a two-speed center opening sliding elevator door. A method of constructing the fire-rated elevator door is provided.