A motorized window covering switching mechanism is described herein. The switching mechanism includes a deflectable arm and a pull cord. The deflectable arm is connected to a first contact, and the pull cord is connected to the deflectable arm such that, as the pull cord is tugged, the deflectable arm deflects to move the first contact toward a second contact, thereby converting gestures of the pull cord into electrical signals that control a motorized window covering. In some embodiments, cord gestures that deflect the deflectable arm include pull sequences, numbers of pulls, strength of pulls, or combinations thereof. Additionally, in some embodiments, a controller receives the cord gestures and translates the cord gestures into operational commands to control and operate a window covering gearbox assembly.

An apparatus in accordance with the invention includes a motor and a gearbox coupled to the motor and comprising an output shaft configured to actuate a window covering. A position encoder, directly driven by the output shaft, is configured to measure at least one of an angular position and a number of rotations of the output shaft. The angular position and number of rotations may be used to calculate an angular position of slats of a window blind and/or an amount a window covering is opened or closed. A corresponding method is also disclosed herein.

An apparatus in accordance with the invention includes a motor and a gearbox coupled to the motor and comprising an output shaft configured to actuate a window covering. A position encoder, directly driven by the output shaft, is configured to measure at least one of an angular position and a number of rotations of the output shaft. The angular position and number of rotations may be used to calculate an angular position of slats of a window blind and/or an amount a window covering is opened or closed. A corresponding method is also disclosed herein.

A method of retrofitting a window covering with a motorized tilting assembly is disclosed herein. The method includes removing a tilt rod from a blinds tilting mechanism and introducing the motorized tilting assembly into the blinds tilting mechanism. The assembly includes a motor, a gearbox having an internal enclosure and an external enclosure, and an output shaft. The internal enclosure encloses gears, and the external enclosure encloses the internal enclosure. The output shaft includes a through-channel and extends through the internal enclosure and the external enclosure. The method further includes: selecting a tilt rod adapter having an internal shape complementary to the tilt rod and an external shape complementary to the through-channel of the output shaft; inserting the tilt rod adapter into the output shaft; and reinstalling the tilt rod such that the tilt rod passes completely through the output shaft and the tilt rod adapter.

A louver roller mechanism is described herein. The louver roller mechanism comprises a turning cylinder in which at least one roller is mounted, a turning cylinder cover is mounted at the opening of the turning cylinder, the turning cylinder and the turning cylinder cover are sequentially and axially mounted on a rotating shaft, and a square shaft is mounted in the rotating shaft. A roller system consisting of a roller mechanism and a gear clutch turning mechanism is also described, which comprises a base and a top cover. The roller mechanism and the gear clutch turning mechanism are set on the base, the roller mechanism is wound with ladder tapes, the roller mechanism is in axial connection with the gear clutch turning mechanism, and the roller mechanism and the gear clutch turning mechanism are driven to rotate by the square shaft.

A louver roller mechanism is described herein. The louver roller mechanism comprises a turning cylinder in which at least one roller is mounted, a turning cylinder cover is mounted at the opening of the turning cylinder, the turning cylinder and the turning cylinder cover are sequentially and axially mounted on a rotating shaft, and a square shaft is mounted in the rotating shaft. A roller system consisting of a roller mechanism and a gear clutch turning mechanism is also described, which comprises a base and a top cover. The roller mechanism and the gear clutch turning mechanism are set on the base, the roller mechanism is wound with ladder tapes, the roller mechanism is in axial connection with the gear clutch turning mechanism, and the roller mechanism and the gear clutch turning mechanism are driven to rotate by the square shaft.

A method in accordance with the invention includes a headrail bracket configured to be inserted into a headrail at an angle from a top thereof. The headrail bracket includes clips snap into a top edge of the headrail, and an attachment mechanism to attach to a gearbox assembly configured to rotate a tilt rod of a window blind tilting mechanism. In certain embodiments, the headrail bracket is a single component with a substantially low profile. This headrail bracket may span a top of the headrail. In other embodiments, the headrail bracket includes a first component to secure a first end of the gearbox assembly to the headrail and a second component to secure a second end of the gearbox assembly to the headrail. In certain embodiments, the first component slides over the first end of the gearbox assembly and the second component slides over the second end of the gearbox assembly

An apparatus in accordance with the invention includes a gearbox assembly configured to electromechanically operate a window covering. A controller, incorporated into the window covering, is provided to control the gearbox assembly. A security device, such as a camera, motion sensor, audio sensor, proximity sensor, impact sensor, or the like, communicates with the controller and is configured to monitor security at a window associated with the window covering. Such a security sensor may, for example, monitor opening and/or closing of the window, breaking of the window, or the like. In certain embodiments, operation of the window covering is triggered in response to conditions sensed by the security device. A corresponding method is also disclosed herein.

An apparatus in accordance with the invention includes a gearbox assembly configured to electromechanically operate a window covering. A controller, incorporated into the window covering, is provided to control the gearbox assembly. A security device, such as a camera, motion sensor, audio sensor, proximity sensor, impact sensor, or the like, communicates with the controller and is configured to monitor security at a window associated with the window covering. Such a security sensor may, for example, monitor opening and/or closing of the window, breaking of the window, or the like. In certain embodiments, operation of the window covering is triggered in response to conditions sensed by the security device. A corresponding method is also disclosed herein.

An apparatus in accordance with the invention includes a directional switching device configured to provide directional control along multiple axes (e.g., perpendicular axes). Directional control along a first axis enables selection of a current function from a plurality of functions. Similarly, directional control along a second axis increases or decreases an amount associated with the current function. In certain embodiments, an indicator, such as colored light, may indicate the current function of the directional switching device. Selection of a first function from the plurality of functions may enable the directional switching device to wirelessly control a first device, while selection of a second function from the plurality of functions may enable the directional switching device to wirelessly control a second device. A corresponding method is also disclosed herein.