A self-locking balance weight-type insulated glass assembly has two panes of glass with an inner cavity and a blinds assembly therein. The blinds assembly comprises a head rail, a slat assembly hung on the head rail, a bottom rail, a privacy fascia and a hollow side rail. The head rail has a hollow inner cavity with a rotary rod assembly and a rotary rod locking device therein. The slat assembly, the bottom rail and the rotary rod assembly are connected through a pull cord for controlling slats to rise or fall and a ladder cord for controlling the slats to turn. The rotary rod locking device has an end connected to the rotary rod assembly and an end connected to a gear box. An external magnetic operator is magnetically coupled to an internal magnetic operator arranged outside the inner cavity formed by the panes of glass.

A self-locking balance weight-type insulated glass assembly has two panes of glass with an inner cavity and a blinds assembly therein. The blinds assembly comprises a head rail, a slat assembly hung on the head rail, a bottom rail, a privacy fascia and a hollow side rail. The head rail has a hollow inner cavity with a rotary rod assembly and a rotary rod locking device therein. The slat assembly, the bottom rail and the rotary rod assembly are connected through a pull cord for controlling slats to rise or fall and a ladder cord for controlling the slats to turn. The rotary rod locking device has an end connected to the rotary rod assembly and an end connected to a gear box. An external magnetic operator is magnetically coupled to an internal magnetic operator arranged outside the inner cavity formed by the panes of glass.

Systems and methods for controlling a motorized wand in order to operate at least one set of blinds is disclosed herein. Certain embodiments include a motorized wand having features to enable manual or remote control of slats or louvres to at least one set of blinds, wherein a user may program specific actions through a software or app-based device. In other aspects, a user may switch between manual and automatic operation of the wand through specified, simple steps.

Systems and methods for controlling a motorized wand in order to operate at least one set of blinds is disclosed herein. Certain embodiments include a motorized wand having features to enable manual or remote control of slats or louvres to at least one set of blinds, wherein a user may program specific actions through a software or app-based device. In other aspects, a user may switch between manual and automatic operation of the wand through specified, simple steps.

An architectural-structure covering is disclosed. The architectural-structure covering may include a covering moveable between retracted and extended positions, and between closed and open configurations. The covering may include front and rear sheets and a plurality of vanes extending therebetween. In the deployed position, the covering may be configured so that the vanes are positioned substantially perpendicular to the incoming light. The architectural-structure covering may also include a rotatable member including a scoop configured to create a pocket to secure a bottom rail of a rear covering so that the bottom rail does not prematurely deploy. Moreover, the architectural-structure covering may also include an external booster movable between a first state of operation wherein the external booster stores potential energy and a second state of operation wherein the external booster releases the stored potential energy to rotate the rotatable member in a predetermined direction to effect additional rotation of a covering.

An architectural-structure covering is disclosed. The architectural-structure covering may include a covering moveable between retracted and extended positions, and between closed and open configurations. The covering may include front and rear sheets and a plurality of vanes extending therebetween. In the deployed position, the covering may be configured so that the vanes are positioned substantially perpendicular to the incoming light. The architectural-structure covering may also include a rotatable member including a scoop configured to create a pocket to secure a bottom rail of a rear covering so that the bottom rail does not prematurely deploy. Moreover, the architectural-structure covering may also include an external booster movable between a first state of operation wherein the external booster stores potential energy and a second state of operation wherein the external booster releases the stored potential energy to rotate the rotatable member in a predetermined direction to effect additional rotation of a covering.

A covering for an architectural opening is provided. The covering may include a roller rotatable about a longitudinal axis, a shade associated with the roller, and an operating system operably associated with the roller. The operating system may include a base, a drive mechanism, a transmission, an actuator arm, and an engagement arm. The drive mechanism may be associated with the base to provide an input torque. The transmission may be associated with the drive mechanism to selectively transmit the input torque to the roller. The actuator arm may be associated with the base to indirectly set a rotation direction of the roller. The engagement arm may be associated with the base and engageable with the transmission.

A covering for an architectural opening is provided. The covering may include a roller rotatable about a longitudinal axis, a shade associated with the roller, and an operating system operably associated with the roller. The operating system may include a base, a drive mechanism, a transmission, an actuator arm, and an engagement arm. The drive mechanism may be associated with the base to provide an input torque. The transmission may be associated with the drive mechanism to selectively transmit the input torque to the roller. The actuator arm may be associated with the base to indirectly set a rotation direction of the roller. The engagement arm may be associated with the base and engageable with the transmission.

A cordless retractable shade including an operating system for the shade that varies a biasing force of a spring to counterbalance the shade. The bottom rail of a retractable shade can be raised or lowered, and due to the operating system remains in any selected position of the covering between fully extended and fully retracted, without the use of operating cords. The system includes a method of negating and reversing the spring bias effect at a strategic position whereby the flexible vanes of the shade can be adjusted between open and closed.

A cordless retractable shade including an operating system for the shade that varies a biasing force of a spring to counterbalance the shade. The bottom rail of a retractable shade can be raised or lowered, and due to the operating system remains in any selected position of the covering between fully extended and fully retracted, without the use of operating cords. The system includes a method of negating and reversing the spring bias effect at a strategic position whereby the flexible vanes of the shade can be adjusted between open and closed.