An assembly for connecting to a high-voltage grid includes a plurality of single-phase transformers, each of which has a transformer tank that is filled with a fluid and is equipped with a core with at least one coil. The coils of the single-phase transformers are at least partly connected together, thereby forming a neutral or star point. In order to permit the assembly to be quickly assembled in situ while at the same time providing a reliable current path for compensation and grounding currents, the coils are connected together by a neutral or star point conductor or rail in order to form the neutral or star point. The neutral or star point conductor or rail is retained in an insulated manner on the transformer tank.

An assembly for connecting to a high-voltage grid includes a plurality of single-phase transformers, each of which has a transformer tank that is filled with a fluid and is equipped with a core with at least one coil. The coils of the single-phase transformers are at least partly connected together, thereby forming a neutral or star point. In order to permit the assembly to be quickly assembled in situ while at the same time providing a reliable current path for compensation and grounding currents, the coils are connected together by a neutral or star point conductor or rail in order to form the neutral or star point. The neutral or star point conductor or rail is retained in an insulated manner on the transformer tank.

An assembly for connecting to a high-voltage grid includes a plurality of single-phase transformers, each of which has a transformer tank that is filled with a fluid and is equipped with a core with at least one coil. The coils of the single-phase transformers are at least partly connected together, thereby forming a neutral or star point. In order to permit the assembly to be quickly assembled in situ while at the same time providing a reliable current path for compensation and grounding currents, the coils are connected together by a neutral or star point conductor or rail in order to form the neutral or star point. The neutral or star point conductor or rail is retained in an insulated manner on the transformer tank.

An assembly for connecting to a high-voltage grid includes a plurality of single-phase transformers, each of which has a transformer tank that is filled with a fluid and is equipped with a core with at least one coil. The coils of the single-phase transformers are at least partly connected together, thereby forming a neutral or star point. In order to permit the assembly to be quickly assembled in situ while at the same time providing a reliable current path for compensation and grounding currents, the coils are connected together by a neutral or star point conductor or rail in order to form the neutral or star point. The neutral or star point conductor or rail is retained in an insulated manner on the transformer tank.

An energy harvesting method and apparatus for harvesting electrical energy from an elongate conductor through which alternating electrical current is flowing. The apparatus includes a magnetically permeable ferromagnetic metal U-shaped core. An electromagnetic coil surrounds the central section of the core. The core legs form an opening leading to a gap between the legs. The opening and gap are larger than the cross section of the conductor. The conductor is received through the opening into the gap whereat the flowing alternating electric current electromagnetically couples with the core and induces electric current in the coil. The opening is maintained open for selectively removing the conductor therethrough. The apparatus is encapsulated within an electrically insulative housing for electrically insulating and preventing physical contact with the conductor. The apparatus powers an electronic circuit which senses and transmits, via electromagnetic radiation, the operational status of the conductor.

An energy harvesting method and apparatus for harvesting electrical energy from an elongate conductor through which alternating electrical current is flowing. The apparatus includes a magnetically permeable ferromagnetic metal U-shaped core. An electromagnetic coil surrounds the central section of the core. The core legs form an opening leading to a gap between the legs. The opening and gap are larger than the cross section of the conductor. The conductor is received through the opening into the gap whereat the flowing alternating electric current electromagnetically couples with the core and induces electric current in the coil. The opening is maintained open for selectively removing the conductor therethrough. The apparatus is encapsulated within an electrically insulative housing for electrically insulating and preventing physical contact with the conductor. The apparatus powers an electronic circuit which senses and transmits, via electromagnetic radiation, the operational status of the conductor.

A device for harvesting energy from a power line carrying AC current including: a transformer having a core with separate first and second sections, the core being formed of ceramic material or layered nickel alloy tape; a first secondary winding wound around the first section of the core; a second secondary winding wound around the second section of the core; a first DC core-flux control winding wound around the first section of the core; and a second DC core-flux control winding wound around the second section of the core; wherein the core is configured to be in operative communication with a magnetic field radiated from the power line, such that an AC voltage is generated in the first and second secondary windings, and the maximum AC voltage produced by the first and second secondary windings is limited by the first and second DC core-flux control windings.

A device for harvesting energy from a power line carrying AC current including: a transformer having a core with separate first and second sections, the core being formed of ceramic material or layered nickel alloy tape; a first secondary winding wound around the first section of the core; a second secondary winding wound around the second section of the core; a first DC core-flux control winding wound around the first section of the core; and a second DC core-flux control winding wound around the second section of the core; wherein the core is configured to be in operative communication with a magnetic field radiated from the power line, such that an AC voltage is generated in the first and second secondary windings, and the maximum AC voltage produced by the first and second secondary windings is limited by the first and second DC core-flux control windings.