Embodiments of an ESD protection device are described. In an embodiment, an ESD protection device includes a first voltage rail electrically connected to a first node, a second voltage rail electrically connected to a second node, and ESD cells connected between the first and second voltage rails and configured to shunt current in response to an ESD pulse received between the first and second nodes. Each of the ESD cells includes clamp circuits electrically connected to the second voltage rail, ballast resistors connected between the first voltage rail and the clamp circuits, where at least some of the ballast resistors are electrically connected to a third voltage rail, a driver circuit connected between the second and third voltage rails and configured to generate a driver signal, and an output stage configured to generate an output signal in response to the driver signal.

A sheath-bonding link box includes a housing forming an enclosure defining an interior space. A plurality of electrically conductive connectors extend through the housing between an exterior of the enclosure and the interior space. The plurality of connectors each have an internal connecting portion positioned inside of the interior space and an external portion positioned outside of the enclosure. The internal connecting portion is electrically connectable to a functional link in the interior space. The external portion is dimensioned to be electrically connectable to a sheath-bonding lead. The internal connecting portions of the electrically conductive connectors and the functional links are mounted to at least one electrically insulating carrier unit. The carrier unit includes a plurality of receptacles, with each receptacle adapted to at least partly receive one of the functional links in an orientation along a longitudinal axis of the internal connecting portion of each connector.

An electronic isolator device arranged for receiving field wiring from a field element includes a connector configured to receive a surge element for providing surge functionality to the electronic isolator device, and to provide surge protection to the connectivity by way of the field wiring. The connector is configured to connect the surge element to the electronic isolator device and to the field wiring. The connector is arranged for parallel connection of the surge element with respect to the field wiring such that the surge element can be connected and disconnected with the isolator device without disrupting the connection of the isolator device with the field elements.

An electric meter circuit assembly is disclosed which can be used as a conversion kit or in a meter installation generally. The circuit assembly includes an electric meter adapter that has a wiring harness, a meter socket adapter having a socket face adapted to receive a plug-in meter, the meter socket adapter including a plurality of meter connections exposed at the socket face; a current transformer subassembly including a plurality of current transformers, each current transformer being associated with a phase of the multi-phase electrical service, each current transformer of the plurality of current transformers being electrically connected between a meter connection of the plurality of meter connections and a phase of the multi-phase electrical service. The circuit assembly further includes a voltage transformer subassembly electrically connected between phases of the multi-phase electrical service and electrical connections in a connector adapted to be connected to the wiring harness.

An electromagnetic interference (EMI) circuit assembly includes a first, second, and third conductive layer. A protection component disposed between the first and second conductive layers. A dielectric layer is disposed between the second and the third conductive layers. The protection component is configured to protect a load from one or both of an overcurrent condition and an over temperature condition, and the third layer define a capacitor configured to suppress EMI signals.

Example embodiments relate to connection modules for luminaires. One example connection module for a luminaire with a light module includes a support. The connection module also includes a surge protection circuitry arranged on the support. Additionally, the connection module includes a first and second supply terminal for connection to a power supply. The first and second supply terminal are connected to the surge protection circuitry. Further, the connection module includes a first and second load terminal for connection to a drive means of the light module. The first and second load terminal are connected to the surge protection circuitry. In addition, the connection module includes at least a first and second control terminal. A connection line for electrically connecting the first and second control terminals is arranged on the support.

As an example, a circuit is provided. The circuit includes an ESD (electrostatic discharge) clamping circuit with a control signal controlling clamping operations of the ESD clamping circuit. The circuit further includes a counter coupled to the control signal of the ESD clamping circuit. The counter produces a set of output signals responsive to the control signal. The circuit also includes a communications interface for coupling to the set of output signals of the counter. The communications interface also couples to communications circuitry external to the circuit.

A CR snubber element includes a first resistance part, a first capacitance part, a second resistance part, and a second capacitance part. The first capacitance part is connected in series to the first resistance part. The second resistance part is connected in series to the first resistance part and the first capacitance part and the second capacitance part is connected in parallel to the second resistance part. The CR snubber element is configured such that the second resistance part is disconnected when the first capacitance part is short-circuited.

The present invention provides for an electronic isolator, or barrier, device arranged for receiving field wiring from a field element and further including connection means arranged to receive a surge element for providing surge functionality to the device, and to provide surge protection to the connectivity by way of the field wiring, the device arranged such that the surge element connects to the device and to the said field wiring by way of the said connection means so that operational connection/disconnection of the surge element to the device does not require disconnection of the field wiring from the device.

An air gap metal tip structure is provided for (ESD) protection. The structure includes first and second metal tips disposed along at least one horizontal axis that is parallel to a upper substrate and a lower substrate. The structure includes an air chamber formed between the upper and lower substrate within which the first metal tip and the second metal tip are disposed. The air chamber includes a portion between points of the metal tips. The structure includes an under fill level disposed between the lower and upper substrates, and above one or more layers having the metal tips. Oxygen trapped in the air chamber is converted into ozone responsive to an arc between the metal tips to dissipate the arc, and the ozone is decomposed back into the oxygen responsive to an absence of the arc between the metal tips to maintain the ESD protection for subsequent arcs.