A shading apparatus with panels configured to provide shade volume over time, reduce wind load, and optionally generate solar energy. The shading apparatus with panels has first panel and second panel arrays. The first panel array moves up and down using a ganging assembly and linear actuator. The second panel array is fixed opposite the first panel array. Both panel arrays are connected to a rotateable spindle and central post. The shading apparatus is configured to reduce wind load with offset panels that provide passages between the offsets. Embodiments include control logic with various modes, including a mode for orienting the panels orthogonal to the sun over a period of time.

A shading apparatus with panels configured to provide shade volume over time, reduce wind load, and optionally generate solar energy. The shading apparatus with panels has first panel and second panel arrays. The first panel array moves up and down using a ganging assembly and linear actuator. The second panel array is fixed opposite the first panel array. Both panel arrays are connected to a rotateable spindle and central post. The shading apparatus is configured to reduce wind load with offset panels that provide passages between the offsets. Embodiments include control logic with various modes, including a mode for orienting the panels orthogonal to the sun over a period of time.

A foldable structure for a sunshade, a shutter or a fence, comprising at least one guiding member (10); a plurality of displaceable elements (20) slidably connected to said guiding member (10) forming a row (2), a stroke end (54), a first actuator (31) connected to first displaceable element (20) of the row (2), foldable spacers (40) connecting each pair of successive displaceable elements (20), and a spacer guide (50) including successive first portion (51), second portion (52), third portion (53), wherein the second portion (52) urge the foldable spacers (40) from a first folding position to a second folding position; and wherein a second actuator (32) produces a relative movement between the second portion (52) of the spacer guide (50) and the stroke end (54) to adjust the longitude of the third portion (53), said second actuator (32) being in coordination with the first actuator (31).

A foldable structure for a sunshade, a shutter or a fence, comprising at least one guiding member (10); a plurality of displaceable elements (20) slidably connected to said guiding member (10) forming a row (2), a stroke end (54), a first actuator (31) connected to first displaceable element (20) of the row (2), foldable spacers (40) connecting each pair of successive displaceable elements (20), and a spacer guide (50) including successive first portion (51), second portion (52), third portion (53), wherein the second portion (52) urge the foldable spacers (40) from a first folding position to a second folding position; and wherein a second actuator (32) produces a relative movement between the second portion (52) of the spacer guide (50) and the stroke end (54) to adjust the longitude of the third portion (53), said second actuator (32) being in coordination with the first actuator (31).

The panel-layer system for thermal insulation of the shaded surface according to the invention comprises mounted to the outer side of the building envelope, especially a window, especially a roof window, a supporting construction in the form of at least two rigid and non-deformable rails, to which permanently mounted are lamellae, wherein the edge of the lamellae, outer in relation to the shielded envelope, has an irregular shape and the lamellae are inserted into notches made in the supporting construction and are additionally glued to it and the inclination angle of each lamella is constant, wherein for the lamellae situated in the upper part of the building envelope, the inclination angle is not more than 70° with respect to the envelope plane and decreases towards the bottom of the envelope so that the lowest lamella is inclined at an angle of not more than 25°, and the supporting construction shall be mounted to the building envelope so that an air cavity of at least 10 mm wide and not more than 100 mm is maintained between the envelope, mounted to it lamellae, and the plane of the building envelope.

The panel-layer system for thermal insulation of the shaded surface according to the invention comprises mounted to the outer side of the building envelope, especially a window, especially a roof window, a supporting construction in the form of at least two rigid and non-deformable rails, to which permanently mounted are lamellae, wherein the edge of the lamellae, outer in relation to the shielded envelope, has an irregular shape and the lamellae are inserted into notches made in the supporting construction and are additionally glued to it and the inclination angle of each lamella is constant, wherein for the lamellae situated in the upper part of the building envelope, the inclination angle is not more than 70° with respect to the envelope plane and decreases towards the bottom of the envelope so that the lowest lamella is inclined at an angle of not more than 25°, and the supporting construction shall be mounted to the building envelope so that an air cavity of at least 10 mm wide and not more than 100 mm is maintained between the envelope, mounted to it lamellae, and the plane of the building envelope.

This disclosure relates to a patio cover control system. The system comprises a frame comprising support beams, support posts configured to support the frame, cover panels rotatably coupled to the support beams, an actuator mounted to the frame and coupled to the cover panels, a gutter coupled to the frame, a light source coupled to the gutter, a precipitation sensor, a fan, and/or a portable controller wirelessly coupled to the actuator, the light source, the precipitation sensor, and/or the fan. The actuator may be configured to rotate the cover panels between an open configuration and a closed configuration. The light source may be configured to light an area under the cover panels. The portable controller may be configured to control the actuator, the light source, the precipitation sensor, the fan, and/or other components.

This disclosure relates to a patio cover control system. The system comprises a frame comprising support beams, support posts configured to support the frame, cover panels rotatably coupled to the support beams, an actuator mounted to the frame and coupled to the cover panels, a gutter coupled to the frame, a light source coupled to the gutter, a precipitation sensor, a fan, and/or a portable controller wirelessly coupled to the actuator, the light source, the precipitation sensor, and/or the fan. The actuator may be configured to rotate the cover panels between an open configuration and a closed configuration. The light source may be configured to light an area under the cover panels. The portable controller may be configured to control the actuator, the light source, the precipitation sensor, the fan, and/or other components.

A louvered pergola includes (a) a plurality of 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 extending parallel with each other across the frame opening. The plurality of louvers includes a first louver fixed to the frame, a second louver fixed to the frame opposite the first louver, and a plurality of pivotable louvers pivotably supported by the frame between the first and second louvers. The pivotable louvers are pivotable between a closed position in which the plurality of louvers partially overlap with each other to close the frame opening and an open position in which a gap is provided between adjacent louvers of the plurality of louvers.

A louvered pergola includes (a) a plurality of 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 extending parallel with each other across the frame opening. The plurality of louvers includes a first louver fixed to the frame, a second louver fixed to the frame opposite the first louver, and a plurality of pivotable louvers pivotably supported by the frame between the first and second louvers. The pivotable louvers are pivotable between a closed position in which the plurality of louvers partially overlap with each other to close the frame opening and an open position in which a gap is provided between adjacent louvers of the plurality of louvers.