An impact resistant operable blind includes a sealed impact resistant unit including a first glass layer and a second laminated glass layer spaced from the first glass layer and defining a sealed chamber therebetween. The second laminated glass layer includes a first heat strengthened glass layer laminated to a second heat strengthened glass layer by an interlayer. A blind unit is disposed within the sealed chamber and includes a tiltrod supported at a top of the sealed chamber and supporting a plurality of ladder strings that support a plurality of slats.

An automated tilt wand controller could precisely control the tilt of a plurality of slats of installed window blinds using an actuator to turn a tilt wand. A remote or mobile device could be used to control the automated tilt wand controller.

A window covering includes a positional adjustment mechanism connected to a first rail that includes a spring motor unit, a first lift cord pulley connected to the spring motor unit, a first lift cord collection mechanism having a first roller positioned in the first rail, and a first lift cord that extends from the first lift cord pulley through window covering material such that a portion of the first lift cord passes along the first roller. The first roller is configured so that it only rotates a pre-selected number of revolutions when the window covering material is moved from the extended position to the retracted such that the first roller no longer rotates in the second rotational direction as the window covering material is moved from an extended position to a retracted position after having rotated the pre-selected number of revolutions in the second rotational direction.

An apparatus for automating a set of window blinds is described. The apparatus includes a motor and a microcontroller. The motor includes a window blind coupler that couples a window blind tilt rod to the motor. The microcontroller stores instructions that, when executed, instruct the microcontroller to dynamically actuate the window blind coupler via the motor. The instructions include obtaining a desired room temperature, calculating a first temperature gradient between the window-side of the window blinds and the room-side of the window blinds based on a window-side temperature and a room-side temperature, and calculating a second temperature gradient between the room-side temperature and the desired temperature. The instructions further include retrieving a tilted state related to the first temperature gradient, the desired room temperature, and a zero-value second temperature gradient, and activating the motor to turn the window blind coupler to tilt the window blinds to the tilted state.

A spring drive system for a window shade includes a housing, a first and a second gear engaged with each other and respectively assembled about a first and a second pivot axis, two springs respectively assembled at two opposite sides of the second gear and respectively connected with two take-up reels provided on the first gear, a first cord drum and a third gear fixedly connected with each other and assembled about a third pivot axis, the first and third gears being respectively located at different levels along the first and third pivot axes and respectively engaged with a first gear train, a second cord drum and a fourth gear fixedly connected with each other and assembled about a fourth pivot axis, the second and fourth gears being respectively located at different levels along the second and fourth pivot axes and respectively engaged with a second gear train.

An actuation device for the slats of a wing of a shutter has two sections intended to be mounted in the uprights of a frame of the wing, a plurality of flanges that are rotatably mounted in holes obtained in the sections, and locking devices disposed in such a way to hold the flanges and prevent the flanges from coming out of the holes of the section.

An electromechanical orientation actuator (10) for orientating a sunscreen (SCR) with orientable blades (B1, B2, B3; B′1, B′2, B′3) comprises, in series, a motor (11), at least one first speed reduction module (21), a second speed reduction module (31) and a rocker (4) for orienting the blades (B1, B2, B3; B′1, B′2, B′3). The actuator (10) further comprises at least a third speed reduction module (43) in series between the second speed reduction module (31) and the orientation rocker (4). The actuator preferably belongs to a range of actuators further comprising an electromechanical movement actuator (110) for moving a sunscreen (SCR2) that can be moved between a raised position and a lowered position, comprising, in series, a motor (111), at least a first speed reduction module (121) and at least a winder (140) for a suspension cord (L3) of the first screen (SCR2) or for the first screen (SCR2). Notably, the two actuators have a speed reduction module of the same model. For preference, the motor of the first actuator and the motor (11) of the second actuator (10) have identical voltage/current characteristics.

A driving assembly for window blinds includes a mounting plate, a winding roller and driving wheels that are engaged with one another, at least one first guiding roller, and at least one second guiding roller. An elastic element is elastically wound around the driving wheels, a pull rope has a starting end fixed to the winding roller and is divided into at least two sections, under a first status, the pull rope partially winds around the winding roller then winds around the second guiding roller and the first guiding roller in turns along outer edges of the second and the first guiding rollers; while under a second status, the pull rope disengages from the winding roller, the second guiding roller and the first guiding roller in turns. The driving assembly has simple structure and convenient assembly, and brings effortless and quick operation to pull or lift the window blind.

A window blind, wherein each ladder tape thereof includes two longitudinal cords, plural bearers and plural limiting members. The longitudinal cords each have an end connected to a deflecting mechanism disposed on the upper rail. The bearers are disposed between the two longitudinal cords for respectively supporting the slats. The limiting members include a first limiting member and a second limiting member neighboring thereto. The first limiting member has an end disposed on one of the longitudinal cords and includes a first slat-through portion located between two ends thereof passing through a first through hole of a first slat. A first linking loop is formed after the first slat-through portion passes through the first through hole. The second limiting member passes through the first linking loop for keeping the first through hole threaded through by one of the first limiting member and the second limiting member.

A blind control for a window covering having a narrow profile; and particularly relates to a control module for a window shade where the location of the drive mechanism is selected to minimize the gap between the end of the window shade and inside edge of a window opening; locating the drive mechanism in a shell disposed in a housing to rigidity a reduced thickness of the drive so as to minimize the gap; and use a single rod depending from the control module to activate the drive mechanism in a safe and secure manner. The invention also includes a housing with an end wall adjacent one end of the shade; a clutch projecting from said end wall and rotatable about a clutch axis, a drive gear engageable at one end of the clutch for rotatably driving said clutch and shade, said drive gear disposed in said housing adjacent said end wall; and a wand for driving said drive gear.