Described is a built-in electromechanical equipment for controlling devices in a building, comprising a cover plate (10), which is coupled to a functional frame (11), incorporating a socket-holder frame (12); the plate (10) and the functional frame (11) are also coupled to a built-in box (16), which contains a power supply device (30). More specifically, the functional frame (11) has a lower protruding rim (14), on which are positioned a series of sensors and contains an electronic circuit (25), equipped with a series of LEDs (26) and a microcontroller (32), which analyses, controls and manages the LEDs (26), the sensors and a series of communication ports (40, 41, 42) of the electronic circuit (25); moreover, between the plate (10) and the functional frame (11) there is a light guide (22), which is coupled to the LEDs (26) and which is configured to uniformly illuminate the outer surface of the plate (10).

A wall-mounted keypad may include a light detector circuit located inside the keypad that is configured to measure an ambient light level in a space. The light detector circuit may receive ambient light through an aperture that is hidden from view by the keypad. The keypad may include a reflector for directing ambient light onto the light detector circuit. The keypad may include an enclosure that houses the light detector circuit. The enclosure may define a recess that exposes at least a portion of the light detector circuit. The enclosure may include a reflector that may focus ambient light received through the aperture onto the light detector circuit. The keypad may include a control circuit that may be configured to illuminate the indicia of respective buttons of the control device in response to actuations of the one or more buttons, in accordance with the measured ambient light level.

A manually operated disconnect maintains a machine/process in a de-energized state. The disconnect employs a sensor that automatically detects, via wireless communication, a lock affixed to the disconnect that locks the disconnect in an open state. Processing circuitry coupled to the sensor determines lockout tagout data, such as identification of a user associated with the lock, a time of application of the lock, and data identifying and/or locating the disconnect or a machine/process to which the disconnect provides power when in a closed state. Memory circuitry coupled to the processing circuitry stores the lockout tagout data, and holds it available for user review, transmission, analysis, reporting, and so forth.

Described herein are several examples of an apparatus that features receptacles configured to accept interchangeable buttons. Each of the interchangeable buttons has a receptacle interface on a first side, which allows them to electrically connect to and communicate with the aforementioned apparatus, and a unique user-perceivable label on a second side. Electronic elements embedded in each interchangeable button, or alternatively located on its first side, correspond to a unique user-perceivable label. Based on these electronic elements, the apparatus recognizes each button individually, and identifies their user-perceivable label. As a result, the interchangeable buttons may be re-positioned on the apparatus and maintain their intended functionality according to their user-perceivable label. In addition, new interchangeable buttons with different user-perceivable labels and new functionality, according to their labels, can be introduced to the apparatus.

Disclosed is a switch device that includes or is formed by a switchgear. Two sensors of the switchgear monitor two measured values and a switch of the switchgear is switched depending on these measured values. The adjustable thresholds for the measured values are displayed on a digital display integrated in the switchgear or arranged on an external input device. Both thresholds are adjusted digitally via the input device. The input device can be a commercially available smartphone with an app or a laptop.

A circuit breaker assembly including a housing assembly and a tamper detection system. The housing assembly defines a sealed enclosure. The sealed enclosure includes a division interface. The sealed enclosure is structured to be in one of a closed, first configuration, wherein the sealed enclosure defines a generally enclosed space, and an open, second configuration, wherein the sealed enclosure allows access to the enclosed space, and wherein, as the sealed enclosure moves between the first configuration to the second configuration, the sealed enclosure is reconfigured at the division interface. The tamper detection system includes a protective assembly and an indicator assembly. The protective assembly is structured to be coupled to the sealed enclosure at the division interface. The indicator assembly includes a rupturable construct. The rupturable construct is structured to transform from an intact, first configuration to a ruptured, second configuration.

An apparatus for supplying power includes a power input, a switch connected to the power input, a load configured to draw power from the power input through the switch, and a switch lock configured to prevent the switch from disconnecting the load from the power input.

A remote blade closing detector switch is positioned on or near the jaws of an electric power disconnect switch, where proper seating of the blade in the jaws activates a detector switch. An extended conductor lead electrically connects the detector switch an RFID tag placed in a convenient reading location. The detector switch is configured to control a data signal, power to the antenna of the RFID tag, the power supply to the RFID tag, or a data signal between an RFID chip and an antenna as mechanisms for enabling and disabling the tag to report a status indicator. An antenna tuning compensator may be utilized to compensate for the impedance of the long conductor lead connected to the antenna. A noise filter may also be used to suppress electrical noise picked up by the long conductor lead in the harsh electrical environment of the disconnect switch.

According to one aspect of the present disclosure, a device and technique for impact detection includes a housing enclosing a mass member where the housing is configured to enable movement of the mass member from a first position to a second position within the housing in response to receipt by the housing of an acceleration event. The impact indicator also includes switch circuitry and a passive radio-frequency identification (RFID) module coupled to the switch circuitry. Responsive to movement of the mass member from the first position to the second position, the mass member causes a change in the switch circuitry where the change in the switch circuitry causes a change in a value output by the RFID module when activated.

A switch apparatus has a wireless function and is provided with a body, a knob, which is assembled to the body and can be switch-operated, an antenna coil for communication operations, which is wound on the body, and a connecter terminal. The connecter terminal includes at least one terminal, which is provided to the body by insert molding and is bonded to the antenna coil, and at least one pin.