An industrial roof panel includes a projection and a complementary wing at opposite sides. The projection has a recess configured for clamping the panel to a second neighboring panel using a fastener such that the panel is supported by the second neighboring panel for reduced buckling under downward load. A modular panel system includes first and second mutually juxtaposed panels, each supported by purlins of a building structure extending along a width of the panels. The second panel has an undercut extending along a length of the panel on a distal side thereof. The first panel has an integral wing-type female coupler extending along a length of the first panel and overlaying an upward projection of the second panel, to which it is secured using fasteners and bolts.

An extruded convex plastic panel (100) for use in a metal roof system (118) including a light transmitting member (101) having top and bottom layers (101A, 101B) and a rib structure (102) disposed between the top and bottom layers (101A, 101B). The extruded convex plastic panel (100) further includes a pair of standing seams (103, 106) provided along two opposite side edges of the light transmitting member (101). A pair of connector assemblies (105, 115) provided as a separate unit, which connects the extruded convex plastic panel (100) to the metal roofing system (118) and allows the light transmitting member (101) to expand and contract freely without the use of any fasting devices for connecting the extruded convex plastic panel (100) to the metal roofing system (118).

A thermally adaptive glazing panel roofing system is provided. The system includes a glazing panel including at least one notch formed in a side of the glazing panel, two side brackets each including a ledge feature. Opposite sides of the glazing panel are supported by the ledge features. The system further includes at least one panel support plate attached to one of the ledge features and engaged to the notch. The system further includes a first pressure cap affixed to a first side bracket of the two side brackets and a second pressure cap affixed to a second side bracket of the two side brackets. The glazing panel is operable to thermally expand along the ledge features.

A thermally adaptive glazing panel roofing system is provided. The system includes a glazing panel including at least one notch formed in a side of the glazing panel, two side brackets each including a ledge feature. Opposite sides of the glazing panel are supported by the ledge features. The system further includes at least one panel support plate attached to one of the ledge features and engaged to the notch. The system further includes a first pressure cap affixed to a first side bracket of the two side brackets and a second pressure cap affixed to a second side bracket of the two side brackets. The glazing panel is operable to thermally expand along the ledge features.

The invention relates to a roof forming element for a roof, comprising a roof plate, a beam integral with the roof plate, such that the integral combination of the roof plate and the beam has an L-shaped cross-section, a cover, and coupling means for coupling the roof forming element to a further, neighbouring element. The roof forming element, at least in a mounted condition of a plurality of such elements, is configured such that the second longitudinal side of the element is arranged to be supported by the first longitudinal side of a further, neighbouring one of said elements, so that the beam of the further roof forming element also supports the roof plate of the roof forming element, and so that the respective roof plate elements of said roof forming element and further roof forming element are flush with respect to each other.

Roof forming element, a plurality of which may form a roof of a building, comprising base part comprising an elongate roof plate of a polymer, a cover for covering the roof plate, and coupling means for coupling the roof forming element in use to further, neighbouring roof forming element, the base part comprising an elongate reinforcement part comprising a strip comprising polymer and unidirectional fibers, bonded to the base part at the interior side of the base part and extending in the length direction along the length of the base part, the elongate reinforcement part covering at least a part of the width of the base part,the strip of the elongate reinforcement part having a higher Young's modulus than the base part, or at least a part of the base part to which the elongate reinforcement part has been bonded.

The invention relates to a roof forming element for a roof, comprising a roof plate, a beam integral with the roof plate, such that the integral combination of the roof plate and the beam has an L-shaped cross-section, a cover, and coupling means for coupling the roof forming element to a further, neighbouring element. The roof forming element, at least in a mounted condition of a plurality of such elements, is configured such that the second longitudinal side of the element is arranged to be supported by the first longitudinal side of a further, neighbouring one of said elements, so that the beam of the further roof forming element also supports the roof plate of the roof forming element, and so that the respective roof plate elements of said roof forming element and further roof forming element are flush with respect to each other.

A retention clip for use with a panel system has a base plate having a pair of opposing flanges at least one of which is configured for attaching to a support structure. An upright extends between the base plate and a top plate having a pair of opposing flanges and defines opposing first and second surfaces that in use are dimensioned to engage opposing first and second ends of a pair of first and second adjacent panels. At least the first surface supports a spacer element that is configured to prevent mutual abutment of opposing ends of the first and second panels at least during construction of the panel system.

In another embodiment, a connector assembly comprises a first side collector, comprising a first panel engagement region comprising a first receiving area that has a size to attach onto an edge of a first panel; and a second side collector, comprising a second panel engagement region comprising a second receiving area that has a size to attach onto an edge of a second panel. The first side collector and second side collector can be configured to directly mate with each other to hold panels together.

In another embodiment, a connector assembly comprises a first side collector, comprising a first panel engagement region comprising a first receiving area that has a size to attach onto an edge of a first panel; and a second side collector, comprising a second panel engagement region comprising a second receiving area that has a size to attach onto an edge of a second panel. The first side collector and second side collector can be configured to directly mate with each other to hold to panels together.