Embodiments of the disclosure provide a waterproof pullcord station for management of patient care. The pullcord station includes a cord, and a face plate assembly coupled to a wall plate assembly. The face plate assembly includes a cord retainer coupled to the cord, and an actuator post coupled to the cord retainer. The wall plate assembly includes a wall plate comprising a frontside and a backside, wherein the frontside comprises a single material and the backside comprises an opening, the wall plate serving as a housing for an electronic circuit. The wall plate assembly further includes the electronic circuit wirelessly coupled to the actuator post and configured to determine whether the cord has been pulled by monitoring the wireless coupling between the actuator post and the electronic circuit. The wall plate assembly further includes a back cap configured to interface with the opening of the backside.

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.

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 electric switching device contains a first contact piece and a second contact piece. The first contact piece can be driven by a first kinematic chain. The second contact piece can be driven by a second kinematic chain. The electric switching device contains a first switching point and a second switching point, which are electrically connected in series, the first contact piece being associated with the first switching point and the second contact piece with the second switching point.

An electric switching device contains a first contact piece and a second contact piece. The first contact piece can be driven by a first kinematic chain. The second contact piece can be driven by a second kinematic chain. The electric switching device contains a first switching point and a second switching point, which are electrically connected in series, the first contact piece being associated with the first switching point and the second contact piece with the second switching point.

The invention is a motorized gearbox assembly. The motorized gearbox assembly includes a motor that drives an output shaft. The output shaft actuates a window covering by applying torque to a tilt rod of the window covering. The output shaft extends substantially an entire length of the motorized gearbox assembly. It also has a through-channel that extends substantially an entire length of the output shaft, so that the tilt rod can pass entirely through the motorized gearbox assembly. Because of this, the motorized gearbox assembly can be used for retrofitting blinds. In some embodiments, the motorized gearbox assembly has a diametrically polarized magnet driven by the output shaft, and a position encoder that measures the output shaft's position and number of rotations.

A window covering in accordance with the invention includes a gearbox assembly comprising a controller incorporated into the gearbox, a motor incorporated into the gearbox, and an external sensor is provided to provide external inputs to the controller in the gearbox assembly. The external sensor may include a security sensor, a temperature sensor, a light sensor, an audio sensor, a smoke detector, a carbon monoxide detector, or a humidity sensor. The controller is further configured to relay sensor information to a remote HVAC system or security system.

A system in accordance with the invention includes a video display adapter, such as a USB or HDMI dongle, configured to generate a signal when a video display (e.g., a television, projector, etc.) is turned on or off. A controller receives the signal and automatically actuates a motorized window covering in response to the signal. In certain embodiments, the motorized window covering receives the signal directly from the video display adapter without requiring any intervening electronic devices. A corresponding method is also disclosed herein.

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.

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.