An automated window shutter assembly includes a pair of shutters that is each movably positioned on an exterior wall of a building. Each of the shutters is positionable in an open position or a closed position. A housing is coupled to the exterior wall of the building and the housing is positioned above the window. A pair of screws is each rotatably positioned within the housing and each of the screws is rotatable in a closing direction or an opening direction. A drive unit is positioned within the housing and the drive unit engages each of the screws. The drive unit is turned on to rotate each of the screws in the closing direction or the opening direction. A plurality of engagements each threadably engages a respective one of the screws. Each of the engagements is coupled to a respective one of the shutters for opening and closing the shutters.

A sensor may detect glare from a recorded image and a shade position of a motorized window treatment may be controlled based on the position of the detected glare in the image. A luminance of a pixel may be calculated in an image and a glare condition may be detected based on the luminance of the pixel. For example, the sensor may start at a first pixel in a bottom row of pixels and step through each of the pixels on the bottom row before moving to a next row of pixels. When the sensor detects a glare condition, the sensor may cease processing the remaining pixels of the image. The sensor may calculate a background luminance of the image by reordering the pixels of the image from darkest to lightest and calculating the luminance of a pixel that is a predetermined percentage from the darkest pixel.

An automated window shutter assembly includes a pair of shutters that is each movably positioned on an exterior wall of a building. Each of the shutters is positionable in an open position or a closed position. A housing is coupled to the exterior wall of the building and the housing is positioned above the window. A pair of screws is each rotatably positioned within the housing and each of the screws is rotatable in a closing direction or an opening direction. A drive unit is positioned within the housing and the drive unit engages each of the screws. The drive unit is turned on to rotate each of the screws in the closing direction or the opening direction. A plurality of engagements each threadably engages a respective one of the screws. Each of the engagements is coupled to a respective one of the shutters for opening and closing the shutters.

Window for outdoor settings, which comprises a movable wing provided with a first support frame hinged to a second support frame of a fixed framework by means of a hinging system, so that, when the movable wing is closed, the two frames define two opposite perimeter faces delimiting a slit. The window comprise a first perimeter gasket fixed to one of the two opposite perimeter faces, acting against the other perimeter face, and placed at an internal opening of the slit in order to conceal from view the hinging system of the window. The window further comprises a second perimeter gasket fixed to one of the two opposite perimeter faces, acting against the other perimeter face, and placed at an intermediate position between the internal opening and an external opening of the slit.

A sensor may detect glare from a recorded image and a shade position of a motorized window treatment may be controlled based on the position of the detected glare in the image. A luminance of a pixel may be calculated in an image and a glare condition may be detected based on the luminance of the pixel. For example, the sensor may start at a first pixel in a bottom row of pixels and step through each of the pixels on the bottom row before moving to a next row of pixels. When the sensor detects a glare condition, the sensor may cease processing the remaining pixels of the image. The sensor may calculate a background luminance of the image by reordering the pixels of the image from darkest to lightest and calculating the luminance of a pixel that is a predetermined percentage from the darkest pixel.

A window shutter system includes a frame assembly and a shutter. The frame assembly is configured to be coupled to a wall. The frame assembly includes a first rail and a second rail. The first rail includes a first mating feature. The second rail is parallel to the first rail. The shutter is configured to be selectively coupled to, and selectively repositionable along, the first rail and the second rail. The shutter includes a second mating feature, a first side, and a second side. The second mating feature is configured to selectively interface with the first mating feature to maintain a position of the shutter relative to the first rail. The first side is configured to be selectively exposed. The second side is configured to be selectively exposed. The second side is different from the first side.

In one aspect, a shutter assembly includes a shutter frame and a plurality of louvers supported by the frame. The shutter assembly also includes a louver drive assembly and a. motor positioned within the frame. The motor is configured to rotationally drive a drive shaft extending within the frame. Additionally, the shutter assembly includes a clutch assembly rotationally coupled between the drive shaft and the louver drive assembly. The clutch assembly is configured to disengage or decouple the drive shaft from the louver drive assembly when a torque transmitted through the clutch assembly exceeds a given torque threshold.

A window shutter for securing windows. The window shutter comprises at least one first shutter and at least one second shutter. The first shutter is coupled to the second shutter via hinges. The first shutter is affixed to a wall and adjacent to a window frame. The second shutter is operable to swing about a pivot axis of the hinges. The second shutter is used to secure windows provided in the window frame.

The invention relates to an overhead door for covering a door opening comprising a door blade (11) with a plurality of panels (17), said door blade (11) being movable between a vertical, closed position and a horizontal, opened or overhead position within a side frame (12) comprising double-sided a vertical track (13) and a horizontal track (14), connected by a connecting portion (15), respectively, and with a belt (20) or a chain associated with one side each of the said side frame (12) to lift the panels (17) from said vertical position to said horizontal position. To develop the stated overhead door in a way that the advantages of a high speed rollup door and an overhead door are combined, to offer an overhead door with a low space requirement, low maintenance requirements and a high speed closing possibility, the stated overhead door comprises driving means (27) for simultaneously driving a plurality of said panels (17).

An improved bi-fold shutter that includes a more efficient coupling mechanism at a hinge point suited to facilitate opening and closing the bi-fold shutter with greater ease. In one embodiment, the shutter may be designed for a window such that the shutter, when closed, is relatively close to the face of the associated window, and when open, forms an awning or overhang. The shutter includes an improved coupling mechanism at a hinge point between a first shutter portion and a second shutter portion. The improved hinge point shifts a direction of force needed to maneuver the shutter when moving the shutter from one position to another. The shift in opening and closing force directions improves the efficiency by which the shutter can be operated. In some embodiments, the shutter may be hand-operated. In other embodiments, the shutter may be powered.