A current transformer assembly includes a first current transformer, a plug, a first wire and a second wire between the plug and the first current transformer adapted to transmit a measurement of the first current transformer; and a memory chip adapted to store a first scale factor of the first current transformer.

A current sensing modular system, which allows sensing the phase current and/or the around-fault or zero-sequence current, having to that end at least a first module having at least one phase current sensor embedded therein and a second module having a zero-sequence current sensor embedded therein. The first module is independent of the second module, both modules being installed directly in the connection elements, i.e., in the connection point between at least one bushing and at least one connector of at least one grid cable.

A current sensing modular system, which allows sensing the phase current and/or the around-fault or zero-sequence current, having to that end at least a first module having at least one phase current sensor embedded therein and a second module having a zero-sequence current sensor embedded therein. The first module is independent of the second module, both modules being installed directly in the connection elements, i.e., in the connection point between at least one bushing and at least one connector of at least one grid cable.

A cable television apparatus is applied to an input coaxial cable and an output coaxial cable to transmit a cable television signal and an alternating current power. The cable television apparatus includes a high saturation current transformer, an input terminal, an output terminal and a coupling side. The high saturation current transformer includes a ferrite core, a primary side circuit and a secondary side coil. The ferrite core is a high saturation current ferrite core, so that the primary side circuit transmits the cable television signal and the alternating current power, and couples the cable television signal to the secondary side coil.

A device (9) for protecting a direct current electrical system (1) having one or more modules (2) from electric arcs comprises: a first sensor (10) provided with a first ring of ferromagnetic material configured to generate a first signal, representing a oscillating component of a current flowing through a cable inserted into the ring; a conditioning stage (12), having a bandpass filter, for conditioning the first signal; a first threshold comparator (13); a counter (15); a processor (14); a second sensor (19), configured to generate a second signal representing a direct current component of the current flowing through the cable; a second threshold comparator (20).

A heat-resistance element includes: a heat-resistant substrate including a ceramic material; one or more power wires embedded in the heat-resistant substrate; and a coil structure that is configured by a coil wire extending between start and end points and includes coil segments. The coil segment includes or corresponds to one winding of the coil wire. The coil segment includes: a first conductor extending along the power wire; a second conductor arranged farther from the one or more power wires than the first conductor, the second conductor extending along the power wire; a first connection wire coupling the first and second conductors in the same coil segment; and a second connection wire coupling first and second conductors of adjacent coil segments in the circumferential direction, all of which are embedded in the heat-resistant substrate, and at least the first conductor and the second conductor are not exposed from the heat-resistant substrate.

A heat-resistance element includes: a heat-resistant substrate including a ceramic material; one or more power wires embedded in the heat-resistant substrate; and a coil structure that is configured by a coil wire extending between start and end points and includes coil segments. The coil segment includes or corresponds to one winding of the coil wire. The coil segment includes: a first conductor extending along the power wire; a second conductor arranged farther from the one or more power wires than the first conductor, the second conductor extending along the power wire; a first connection wire coupling the first and second conductors in the same coil segment; and a second connection wire coupling first and second conductors of adjacent coil segments in the circumferential direction, all of which are embedded in the heat-resistant substrate, and at least the first conductor and the second conductor are not exposed from the heat-resistant substrate.

A power distribution monitoring system is provided that can include a number of features. The system can include a plurality of power line sensing devices configured to attach to individual conductors on a power grid distribution network. In some embodiments, the power line sensors can include a split-core transformer. In some embodiments, a power line sensing device is disposed on each conductor of a three-phase network. The sensing devices can be configured to measure and monitor, among other things, current and electric-field on the conductors. Methods of installing, sealing, and protecting the split-core transformers of the power line sensors are also discussed.

A power distribution monitoring system is provided that can include a number of features. The system can include a plurality of power line sensing devices configured to attach to individual conductors on a power grid distribution network. In some embodiments, the power line sensors can include a split-core transformer. In some embodiments, a power line sensing device is disposed on each conductor of a three-phase network. The sensing devices can be configured to measure and monitor, among other things, current and electric-field on the conductors. Methods of installing, sealing, and protecting the split-core transformers of the power line sensors are also discussed.

An apparatus for positioning and retaining a current transformer, such as a Rogowski coil, about a conductor includes at least two members, a coupling mechanism, and a non-conductive securing structure. Each member of the apparatus includes a respective retention structure configured to receive a respective section of the Rogowski coil. The coupling mechanism is configured to movably deploy at least one of the apparatus members relative to the other and around the conductor, which may be a distribution transformer power node. The securing structure is configured to engage the conductor and retain the apparatus members in fixed positions relative to the conductor and to each other.