Lighting devices and methods for providing daylight to the interior of a structure are disclosed. Some embodiments disclosed herein provide a daylighting device including a tube having a sidewall with a reflective interior surface, a light collecting structure, and a light reflector positioned to reflect daylight into the light collector. In some embodiments, the light collector is associated with one or more light-turning and/or light reflecting structures configured to increase the amount of light captured by the daylighting device. Optical elements may allow for the absorption and/or selective transmission of infrared light away from an interior of the daylighting device.

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), andflexible 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 load support structure supports a load on a metal panel roof. Such load support structure includes multiple closure members including opposing side rails, and optionally end closures. The rails are mounted on roof panel ribs. Cavities can be disposed inwardly of the outer perimeter of the support structure as defined by the closure members, in upper portions of the closure members. Rods may be inserted through slot-shaped openings, into the cavities. Cross-section dimensions of the rods are less than the widths of the cavity openings. Either the rods are compressed, or the cavity openings are expanded, or both, so as to enable manually inserting the rods into the cavities. Elongate thermal breaks may be installed at and adjacent the cavities, to assist in controlling thermal conduction through the closure members, between the outside environment and the enclosed space above the roof opening.

A curb assembly is provided for mounting on a sloped, standing seam metallic roof, in order to provide support for a roof fixture, such as an exhaust fan or skylight. The curb assembly includes a box-like structure mounted atop the roof in surrounding relationship to a roof opening. The curb assembly further includes an underlying, below-roof frame assembly. Specialized upper and lower end connection structure serves to securely mount the curb assembly to the metal roof.

A roof load support structure supports a load on a sloping metal panel roof such that substantially all of the load is conveyed through rails, which are mounted on roof panel ribs, then through the roof panel ribs, and to underlying building support structure. Minor portions of the load can be conveyed through an upper diverter and a lower closure. The upper diverter diverts water laterally away from the support structure, in two opposing directions to two opposing sides of the support structure.

In the roof window, each frame member (22) comprises a plurality of receiving structures at an interior, exterior, inner and/or outer side. The receiving structures comprise a number of grooves (25, 26, 27, 28) to interact with auxiliary equipment in an assembled condition of the frame.

A method for mounting a roof window (1) in a roof structure (11) comprising a roofing material (112), said roof window comprising a frame (2), a sash (3) carrying a pane element (4), where the method comprises the steps of A) Arranging the roof window (1) in an opening in the roof structure (11), B) Arranging a plurality of flashing members so that they cover a joint between the frame (2) of the roof window (1) and the roof structure (11) with a top flashing member (1011) extending along the top frame member (21), a bottom flashing member (1014) extending along the bottom frame member (24), and at least two side flashing members (1012, 1013) extending along the side frame members (22, 23), and during step B) a flange (1017) of at least one side flashing member (1012, 1013) is inserted into a flashing reception groove (85) in the outer side (200) of at least one side frame member (22, 23), said flashing reception groove extending in the length direction (L) of the side frame member.

A flashing device (1014) for a roof window (1) comprising a first flashing member (1015), a second flashing member (1016) and two sealing members (106) arranged at opposite ends of the flashing device. The first and second flashing members are interconnected in sliding engagement allowing the relative position between them to be adjusted during mounting. Each sealing member (106) includes a first sealing portion (1061) positioned substantially in parallel with an inward portion of the second flashing member and a second sealing portion (1062) positioned substantially in parallel with a downward portion of the second flashing member. The sealing member (106) further comprises at least one frame attachment portion configured for attachment of the sealing member to the frame of the roof window. A method of mounting a flashing device is also disclosed.

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 (T=T1T2) 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.

A curb assembly is provided for mounting on a sloped, standing seam metallic roof, in order to provide support for a roof fixture, such as an exhaust fan or skylight. The curb assembly includes a box-like structure mounted atop the roof in surrounding relationship to a roof opening. The curb assembly further includes an underlying, below-roof frame assembly. Specialized upper and lower end connection structure serves to securely mount the curb assembly to the metal roof.