The present invention relates to a window (2) or a door, comprising: ⋅(a) a frame or casing; ⋅(b) at least one sash (3) formed of portions of a hollow-chamber profiled element (4); ⋅(c) a planar element (11), which is accommodated in the sash (3), the planar element comprising a functional element (13), the light transmission properties of which can be varied at least in some regions when a voltage is applied; and ⋅(d) a control element (12; 12′), which is designed to control the functional element (11); wherein according to the invention the window or the door is characterized in that the control element (12; 12′) is of a multi-part design and at least one constituent part (12) of the control element (12; 12′) is at least partly accommodated in a hollow chamber (5) of the sash (3). The present invention also relates to a building wall (100) having at least one opening in which a window (2) or door of this type is accommodated.

A glazing assembly for a curtain wall glazing system comprising a glazing unit and a frame structure formed by a plurality of glazing profiles. Each of the plurality of glazing profiles comprises a main structural frame part and a removable clamping part. The removable clamping parts when removed from the structural frame parts unclamp the glazing unit and open a clearance allowing removal of the glazing unit in a direction of a first area. At least one of the main structural frame parts comprises a structural portion and a mobile clamping portion. When removing the mobile clamping portion from the structural frame portions a clearance is opened allowing the performance of maintenance activities to an edge region of the glazing unit from the second area.

A panel frame (10) is provided, comprising a first profile (100) having a first structure (102) to support a first side (52) of an associated panel (50), and a second structure (104) to support an edge (56) of the same panel (50), and a second profile (200) being configured to connect to the first profile (100) and comprising a first structure (202) to support a second side (54) of the panel (50). The first profile (100) comprises at least one magnetic portion (120), such that a magnetic member (300) can be attached to the magnetic portion (120) in order to temporary clamp the panel (50) between the magnetic member (300) and the first structure (102) of the first profile (100).

The present disclosure relates to a building aperture cover (1) such as a window or a door. The building aperture cover comprises a frame arrangement (2) and a vacuum insulated glass unit (3), wherein the vacuum insulated glass unit (3) comprises an evacuated gap (4) placed between a first and a second glass sheet (3a, 3b), and wherein a plurality of support structures (5) are arranged in the evacuated gap (4). The vacuum insulated glass unit (3) is arranged in the frame arrangement (2, 6). The building aperture cover (1) comprises one or more elongated flexible sealing gaskets (21, 22) arranged between an outer major surface (S1, S2) of the vacuum insulated glass unit (3) and a frame part (13a, 13c, 23a, 23c) of the frame arrangement (2, 6). The one or more elongated flexible sealing gaskets (21, 22) is arranged to extend substantially parallel to an edge (7, 50a-50d) of the vacuum insulated glass unit (3). One or more of the one or more elongated flexible sealing gaskets (21, 22) comprises an interior, sealed cavity (21a, 22a) configured to comprise a pressurized fluid.

A window for an above-ground pool is provided. The window includes a window portion (200) and a retainer bracket (250). The window portion (200) includes a window pane (210) and a peripheral rim (220) around a perimeter of the window pane (210). The peripheral rim (220) defines grooves (230) between inner and outer flanges (245, 235) on opposite side of the peripheral rim (220). The retainer bracket (250) includes a peripheral rim junction (260), a peripheral plate (270) and a joint (265) connecting the peripheral rim junction (260) and the peripheral plate (270).

A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and second walls and formed by curing a flowable material.

Embodiments of the present disclosure include a glazing bead system and methods of using the same. The systems and methods can include a frame interface member with structural features that enable the practical and automated coupling of the frame interface member to a frame constituent, before a panel is inserted within the frame interface member.

A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and second walls and formed by curing a flowable material.

A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and se cond walls and formed by curing a flowable material.

A method of forming a thermally enhanced extrudate for a door or window includes providing an extrudate including a channel shaped to receive glass or a frame and having a completely enclosed cavity. The method further includes forming openings in a first flange of the extrudate. The remaining portion of the first flange form bridges that extend between a first wall and a second wall. The method further includes position a flowable material into the cavity through the openings. The flowable material cures to create a solid insulation material in the cavity and the bridges resist warping of the extrudate as the flowable material cures.