Abstract: The present invention is directed to switch device that includes a switch actuator having a user-accessible surface, the user accessible surface including an indicator element and an interior channel optically coupled to the indicator element. The switch actuator is configured to actuate a mechanical linkage by moving between a first actuator position and a second actuator position in response to a user-stimulus, the mechanical linkage actuation driving the set of electrical contacts between a first contact state and a second contact state. A light emitting portion is disposed within the interior channel and optically coupled to the indicator element so that the interior channel moves relative to the light emitting portion when the switch actuator moves between the first actuator position and the second actuator position. The light emitting portion is optically coupled to the indicator element when the interior channel moves relative to the lighting portion.

Abstract: The present is directed to a protective device that includes a separator portion disposed between a back body member and a front cover portion. The separator portion includes a reset pin aperture accessible via a first major surface facing the front cover and a reset pin guide portion disposed on an opposite second major surface facing the back body member. The device further includes a latch block assembly having a central latch block portion configured to accommodate a reset pin and a latching element. The central latch block portion includes an open side configured to accommodate the reset pin guide portion. The reset pin is substantially prevented from exiting the central latch block portion via the open side by the reset pin guide portion.

Abstract: The present invention is directed to an intelligent dimmer that is capable of “learning” the type of load it is controlling, and adjusts its operating parameters accordingly. The present invention can adaptively drive electrical loads over a wide range of wattages. The intelligent dimmer of the present invention is configured to automatically calibrate itself based on the load current demands of a particular electrical load. The intelligent dimmer of the present invention also adaptively limits in-rush currents to extend the life expectancy of the solid state switching components used therein.

Abstract: The present invention is directed to an electrical device that includes a lighting circuit is disposed in the second housing and coupled to the voltage output terminals. The lighting circuit includes a control circuit coupled to a plurality of first light elements and at least one second lighting element. The plurality of first light elements is configured to provide a relatively wide illumination beam when energized by the control circuit in a first operational state, and the at least one second lighting element being configured to provide a relatively narrow illumination beam when energized by the control circuit in a second operational state. The control circuit is configured such that the first operational state and second operational state do not simultaneously occur.

Abstract: The present invention is directed to an electrical wiring device that includes a variable control mechanism configured to regulate power to the at least one electrical load by way of a control knob being user settable between a first adjustment stop and a second adjustment stop. A regulation circuit is configured to establish a pre-determined load power setting when the calibration button is actuated when the regulation circuit is in the calibration mode.

Abstract: The present invention is directed to an intelligent dimmer that is capable of “learning” the type of load it is controlling, and adjusts its operating parameters accordingly. The present invention can adaptively drive electrical loads over a wide range of wattages. The intelligent dimmer of the present invention is configured to automatically calibrate itself based on the load current demands of a particular electrical load. The intelligent dimmer of the present invention also adaptively limits in-rush currents to extend the life expectancy of the solid state switching components used therein.

Abstract: The present invention is directed to a circuit interrupting device including an actuator that provides an actuator stimulus upon the occurrence of the fault actuation signal. A circuit interrupter is positioned to electrically disconnect the first, second and third electrical conductors from each other upon the occurrence of the actuator stimulus. An automated test circuit is coupled to the circuit interrupting assembly. The automated test circuit is configured to automatically produce the simulated fault condition during a predetermined portion of an AC line cycle to determine whether the fault detection assembly is operational such that the fault detection assembly provides a fault detection signal without the circuit interrupter electrically disconnecting the first, second and third electrical conductors from each other.

Abstract: The present invention is directed to an electrical wiring device that includes a test circuit that is configured to generate a recurring simulated fault signal. A detection circuit is configured to generate a test detection signal in response to the recurring simulated fault signal. An end-of-life monitor circuit is configured to generate an end-of-life detection signal if the test detection signal is not generated within a first predetermined period of time. At least one indicator is configured to emit an indication signal in response to the end-of-life detection signal. A response mechanism is configured to decouple the plurality of line terminals from the plurality of load terminals after a second predetermined period of time has elapsed following the end-of-life detection signal.

Abstract: The present invention is directed to an electrical device that includes a control circuit having a processing circuit, an electronic switch, light emitting elements and an ambient light sensor disposed on a substrate. The processing circuit provides an electronic barrier between the light emitting elements and the ambient light sensor such that the operation of the ambient light sensor is not contaminated by light emitted by the plurality of light emitting elements. A cover assembly includes a lens element and a switch actuator comprised of a diffusing material. The lens element and the switch actuator are disposed over the light emitting elements such that the light emitted by the light emitting elements is diffused by the lens element and the switch actuator to emit a substantially uniform illumination without any shadow or hot spot artifacts being visible on either the lens element or the switch actuator.

Abstract: The present invention is directed to a switch device that includes an actuator guide coupled to the switch actuator plate. The perimeter wall of the guide is disposed within the back body member in a nesting arrangement such that the actuator guide is configured to slide within the back body member in a substantially linear motion between a non-switch actuating position and a switch actuating position. The perimeter wall forms a contaminant shield to substantially prevent dust external to the device from contaminating the plurality of guide portions. A transmission mechanism is coupled to the actuator guide and configured to convert the linear motion of the actuator guide into a rotational movement when the switch actuator plate is depressed. A mechanical switch mechanism is configured to move between a first switch state and a second switch state in response to the rotational movement of the transmission mechanism.