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 invention relates to an installation including: a series of orientable slats (3); a slat orientation system (3) adapted to ensure the pivoting of the slats in order to occupy a closed position or an open position; a system for moving in translation the slats (3) between a stowed position and a deployed position; and a control device piloting the displacement system and the orientation system, on the one hand to define from the stowed position of the slats a transition area (Ev) in which each of the slats exiting its stowed position switches from its open upright position to its closed position and conversely for each of the slats arriving to its stowed position, and on the other hand to ensure the translational displacement of the slats in the closed position outside the transition area (Ev).

A roof system including a frame, a plurality of roof panels, wherein each roof panel is connected to the frame and is rotatable with respect to the frame, and a holding mechanism for holding a first roof panel among the plurality of roof panels in a closed position, wherein each roof panel among the plurality of roof panels overlaps at least one adjacent roof panel among the plurality of roof panels, and wherein release of the holding mechanism causes each of the roof panels to rotate toward an open position in a sequential manner.

A new louver, and a louvered roof assembly having a plurality of these louvers is provided wherein the plurality of louvers. are movable within a frame between an open condition and a closed condition. The louvers, each having first and second ends, are pivotally coupled to the frame for rotation about an axis. A linear drive motor is coupled to a moveable arm bar to which each louver is connected by a pin which pin is attached at the pin's opposite end to a member disposed within the center of each respective louver. Single set and dual sets of louvers may be operated by a single linear drive actuator.

A sun shade includes a cover that is extendable and retractable, a guide rail assembly that is engageable with the cover and defines a first path of movement via a first movable engagement point between the cover and the guide rail assembly, and a support bracket that is engageable with the guide rail assembly and arranged at a lower position relative to the cover. The support bracket defines a second path of movement for the guide rail assembly with the cover via a second movable engagement point between the guide rail assembly and the support bracket.

Removable roofing system comprising a motor inserted inside a drum (2), a cord, a compensation device (4), two rigging rails (5a, 5b), at least one guide arch (6a) and removable roofing, the at least one guide arch (6a) being connected to the cord and to the removable roofing, and being designed so that each of its ends slides in a rigging rail (5a, 5b), the cord passing along each rigging rail (5a, 5b) and through the compensation device (4) and being connected at its two ends to the drum (2) so that the rotating of the drum (2) by the motor causes the cord to move in a direction dependent on the direction of rotation of the drum (2), deploying or retracting the removable roofing by moving the at least one guide arch (6a), each rigging rail (5a, 5b) being equipped with at least one end pulley (21a, 21b) and with at least two corner-block deflecting pulleys (20a, 20b, 23a, 23b) which are designed to guide the cord from the compensation device towards the at least one end pulley (21a, 21b), and the compensation device (4) is designed to automatically compensate for variations in cord tension.

A method of applying a foil on an inclined roof structure having a ridge beam, a gutter, a plurality of parallel roof bars interconnecting the beam and the gutter and a ventilation opening frame which surrounds an opening that is located between the beam, the gutter and two neighboring bars, comprises: supplying a window frame that fits inside the ventilation opening frame, introducing the window frame within and holding the window frame at a fixed position with respect to the ventilation opening frame, laying a foil onto the roof structure such that it extends at least from the beam to the gutter and covers at least the neighboring roof bars, fixing the foil to the window frame and the ventilation opening frame along respective circumferential edges thereof, cutting the foil between the window frame and the ventilation opening frame, hence forming the window frame including the foil.

A vertical escape structure comprises an escape housing disposed in a vertical orientation and mounted to a ground to maintain structural integrity in the vertical orientation against external flooding. The escape housing includes an interior which is sealed against water entry from exterior flooding and at least one of a staircase, a ladder, an elevator, or a lift disposed in the interior of the escape housing. The vertical escape structure further comprises a connecting walkway to connect the escape housing to a building. The escape housing has a smaller horizontal footprint than the building. The walkway is severable from the building by force without damaging the escape housing to cause water entry from the exterior flooding.

A louvered pergola includes (a) a plurality of horizontally spaced apart posts; (b) an elevated frame supported by the posts and defining a central frame opening; and (c) a plurality of louvers supported by the frame and extended parallel with each other across the frame opening. The plurality of louvers include a static first louver fixed to the frame, a static second louver fixed to the frame opposite the static first louver, and a plurality of pivotable louvers pivotably supported by the frame between the static first and second louvers. The pivotable louvers are pivotable relative to the static first and second louvers between a closed position in which each pair of adjacent louvers of the plurality of louvers interlock to close the frame opening, and an open position in which a gap is provided between each pair of adjacent louvers of the plurality of louvers.

A long-span structure engaged with a plurality of first and second transportation devices for moving the long span structure. The transportation devices travel along parallel, longitudinally-oriented first and second tracks; moving the structure between a first position and a second position. A first region of the structure is fixed to each first transportation device. A second region of the structure is secured to each second transportation device via a bearing assembly. The first and second regions of the structure are laterally spaced apart. When the long-span structure thermally expands or contracts, a slider plate of each bearing assembly moves laterally relative to the rest of the bearing assembly. Growth of the structure in a predictable direction is forced by keeping the first region thereof fixed against lateral movement with the first transportation devices and allowing movement of the second region thereof via the bearing assemblies on the second transportation devices.