A connector bracket for interconnecting roof windows mounted adjacent to each other in an inclined roof structure, one roof window being located below the other roof window when seen in the direction of inclination of the roof structure, is disclosed. A first connecting section of the connector bracket extends in a first direction from a centre section of the connector bracket and is configured for being connected to the mounting bracket on the first roof window in a pivot connection. A second connecting section extends in a second direction from a centre section of the connector bracket and is configured for being connected to the mounting bracket on the second roof window in a fixed connection. The first and second directions are non-parallel. A roof window arrangement where roof windows are interconnected by such a connector bracket and a method for mounting at least two roof windows are also disclosed.

Disclosed in the present invention is a structure for blocking heat transfer through a thermal bridge of a curtain wall building, including a curtain wall, an indoor metal frame, an outdoor metal frame and/or metal components, wherein: an integral thermal break strip, which is installed close to an outside and made of an aerogel thermal insulation blanket, is fixed between the indoor metal frame and the curtain wall and/or the outdoor metal frame and/or the metal components. The present invention has simple structure, convenient construction technology, great structural strength, excellent fireproof performance; low comprehensive construction cost and substantially improved energy-saving effect of the curtain wall.

The present invention discloses a skylight operating system of a modular data center, so as to timely respond to a firefighting requirement of the modular data center to reduce occurrence of firefighting-related accidents. The skylight operating system comprises: an electric skylight; a firefighting environment index monitoring device arranged inside the modular data center; a monitoring and interacting device arranged in a monitoring room outside the modular data center, and connected with the electric skylight and the firefighting environment index monitoring device, the monitoring and interacting device adapted for receiving monitoring information of the firefighting environment index monitoring device, and opening the electric skylight upon determination that a firefighting-related issue occurs inside the modular data center.

Disclosed is a method for attaching a pane element to a sash, including the steps of A) providing a pane element with a border element, thereby making a pane module, and B) bringing a contact surface of the border element into contact with a contact surface of the sash, and connecting the pane module to the sash. Further disclosed a pane module comprising a pane element and a border element, where the border element includes a contact surface adapted for being connected to a contact surface of the sash, wherein the contact surface of the border element is adapted for being connected to the contact surface of the sash by means of an adhesive or glue, where the border element includes one or more elongate support member(s), and where the border element comprises guiding elements projecting from the contact surface of the border element substantially perpendicularly to the pane plane, wherein the guiding elements are adapted for being inserted in openings in the contact surface of the sash.

It is described herein a venting apparatus for an opening in a roof. The venting apparatus for an opening in a roof may comprise a structural frame, an adapter, a mount, a hinge, and a latch. The adapter may comprise a frame adapter section, a lip extending inwardly from a portion of the frame adapter section inner surface, and a protrusion extending upwardly from the lip. The frame adapter section may be configured to fit around an outer surface of the structural frame while the mount may be configured to fit around an outer surface of the protrusion. The latch may be configured to receive a signal from a device when the device detects the presence of smoke within the building to cause the latch to change from a latch closed position to a latch opened position.

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 telescoping rail assembly for a roof hatch includes a bracket configured to couple to the roof hatch, where the roof hatch is configured to provide access to a roof of a building, a post coupled to the bracket and configured to extend from the roof hatch and outward from the roof, and a telescoping rail having a first portion and a second portion, where the first portion and the second portion are slidably adjustable with respect to one another, and where the telescoping rail is disposed along a portion of a perimeter of the roof hatch to enable the telescoping rail assembly to enclose an area that includes the roof hatch.

This disclosure relates to a louvered patio cover. The louvered patio cover may comprise a frame with support beams, louvered panels, support beam couplers, an actuator, a gutter, and/or other components. The support beams may have angled ends. The louvered panels may be rotatably coupled to the support beams. A support beam coupler may comprise first and second receivers. The first receiver may be configured to receive an angled end of a first support beam, and the second receiver may be configured to receive an angled end of a second support beam. The angled ends of the first and second support beams may face, meet, and/or abut each other when received by the first and second receivers. The actuator may be configured to rotate the louvered panels. A gutter may comprise a lighting channel configured to hold a light source for lighting an area under the louvered patio cover.

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.