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.

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 Venetian blind includes a plurality of slats arranged between a headrail and a bottom rail. Two rotary drums are disposed in two brackets mounted in the headrail and connected with each other through a transmission shaft. A first drawing member is connected with one rotary drum, and a second drawing member is connected with the other rotary drum. When the first drawing member is pulled downward, the rotary drums are rotated from a first position to a second position, such that the ladder cords are driven by the rotation of the rotary drums to tilt the slats to a closed position. When the second drawing member is pulled downward, the rotary drums are rotated from the second position to the first position, such that the ladder cords are driven by the rotation of the rotary drums to tilt the slats to an open position.

A Venetian blind includes a plurality of slats arranged between a headrail and a bottom rail. Two rotary drums are disposed in two brackets mounted in the headrail and connected with each other through a transmission shaft. A first drawing member is connected with one rotary drum, and a second drawing member is connected with the other rotary drum. When the first drawing member is pulled downward, the rotary drums are rotated from a first position to a second position, such that the ladder cords are driven by the rotation of the rotary drums to tilt the slats to a closed position. When the second drawing member is pulled downward, the rotary drums are rotated from the second position to the first position, such that the ladder cords are driven by the rotation of the rotary drums to tilt the slats to an open position.

A control mechanism for a double pitch blind including an array of tiltable slats having a first sub-array of tiltable first slats and a second sub-array of tiltable second slats includes a first spool drive and a second spool drive, both the first spool drive and the second spool drive being configured to be rotated by a common drive shaft. The first spool drive has elongate members extendable and retractable on opposite sides of the slats and the second spool drive has elongate members extendable and retractable on opposite sides of the slats. The first and second spool drives are configured to transfer rotation of the drive shaft to spool-in and to spool-out the elongate members. The first spool drive spools by a first length, and the second spool drive spools by a second length. The first length is larger than the second length.

A control mechanism for a double pitch blind including an array of tiltable slats having a first sub-array of tiltable first slats and a second sub-array of tiltable second slats includes a first spool drive and a second spool drive, both the first spool drive and the second spool drive being configured to be rotated by a common drive shaft. The first spool drive has elongate members extendable and retractable on opposite sides of the slats and the second spool drive has elongate members extendable and retractable on opposite sides of the slats. The first and second spool drives are configured to transfer rotation of the drive shaft to spool-in and to spool-out the elongate members. The first spool drive spools by a first length, and the second spool drive spools by a second length. The first length is larger than the second length.

A window covering system comprises a headrail, a bottom rail, a covering material, a control unit, and a first rotating unit, wherein the first rotating unit is configured to be driven to rotate in a first direction when the bottom rail descends to expand the covering material; and a locking device coiled to the first rotating unit, wherein the locking device provides a restriction force to the first rotating unit to restrict the first rotating unit from rotating in the first direction, as well as to restrict the bottom rail from descending; and an actuating device configured to operate with the control unit simultaneously; when the control unit drives the actuating device to push the locking device in order to reduce the restriction force provided by the locking device to the first rotating unit, the bottom rail descends to drive the first rotating unit to rotate in the first direction.

A window covering system comprises a headrail, a bottom rail, a covering material, a control unit, and a first rotating unit, wherein the first rotating unit is configured to be driven to rotate in a first direction when the bottom rail descends to expand the covering material; and a locking device coiled to the first rotating unit, wherein the locking device provides a restriction force to the first rotating unit to restrict the first rotating unit from rotating in the first direction, as well as to restrict the bottom rail from descending; and an actuating device configured to operate with the control unit simultaneously; when the control unit drives the actuating device to push the locking device in order to reduce the restriction force provided by the locking device to the first rotating unit, the bottom rail descends to drive the first rotating unit to rotate in the first direction.

A displacement controlling device comprises a shaft having a displacement region, a movable unit connected to the shaft and configured to move within the displacement region, a damper connected to one end of the shaft, and a restraint unit arranged between the movable unit and the damper, wherein the restraint unit is configured to be driven by the movable unit from a first position toward a second position; the damper outputs a resistance when the restraint unit is at the first position, and the damper stops outputting the resistance if the restraint unit is at the second position.