A high-voltage lead-through device includes an insulator body having a solid exterior and including insulation, a main conductor passing therethrough, a sensor adjacent the main conductor inside the insulator body measuring a physical property of the device and a communication unit adjacent the main conductor outside the insulator body, wherein the main conductor has a first electric potential, a section of the solid exterior of the insulator body faces a second electric potential, the communication unit is connected to the sensor using a signal conductor as a first electrical communication medium and the communication unit employs a different communication medium for communicating with a data distribution device at a third electric potential.

Provided is a reactor including: an assembly that has a coil that has a pair of winding portions that are arranged side by side, and a magnetic core; a base member that has a mount plate on which the assembly is mounted; and a sensor assembly that has a sensor main body that detects a physical value related to the reactor, and a wiring portion extending from the sensor main body. The reactor includes a wire catch member provided on the assembly or the base member, the wire catch member allowing a part of the wiring portion to be arranged thereon, and a cable tie for fixing the wiring portion to the wire catch member.

An aspect of the present disclosure provides a shield 300 for a terminal 206 of a high-voltage electrical device 200 comprising a first shield element 301 having at least one axial opening 304 and at least one lateral opening 305, and at least one second shield element 302, 303, wherein the at least one second shield element 302, 303 is movable between a first shield position and a second shield position for selectively opening and closing at least one of the at least one axial opening 304 and the at least one first lateral opening 305. Further aspects provide a high-voltage electrical bushing 200 comprising a shield 300 according to the aspect above, and a transformer 100 comprising said high-voltage electrical bushing 200. Yet a further aspect provides a method 400 for installing a high-voltage bushing having a shield according to the aspect above.

An aspect of the present disclosure provides a shield 300 for a terminal 206 of a high-voltage electrical device 200 comprising a first shield element 301 having at least one axial opening 304 and at least one lateral opening 305, and at least one second shield element 302, 303, wherein the at least one second shield element 302, 303 is movable between a first shield position and a second shield position for selectively opening and closing at least one of the at least one axial opening 304 and the at least one first lateral opening 305. Further aspects provide a high-voltage electrical bushing 200 comprising a shield 300 according to the aspect above, and a transformer 100 comprising said high-voltage electrical bushing 200. Yet a further aspect provides a method 400 for installing a high-voltage bushing having a shield according to the aspect above.

A rupture reduction system for fluid-immersed electrical equipment includes a turret for mounting of a bushing. The turret is expandable in volume in response to a surge in pressure of the fluid in the turret. The expansion volume can be provided by an expandable section of the turret, which may include a bellows.

A reactor includes a reactor main body that includes a core and a coil attached to the core, a casing that houses therein the reactor main body and has a portion where an opening is formed, a terminal stage that supports the portion of a conductor electrically connected to the coil, and a shielding member that is integrally formed with the terminal stage and suppresses the leakage of magnetic fluxes from the reactor main body while maintaining the opening opened.

A reactor includes a reactor main body that includes a core and a coil attached to the core, a casing that houses therein the reactor main body and has a portion where an opening is formed, a terminal stage that supports the portion of a conductor electrically connected to the coil, and a shielding member that is integrally formed with the terminal stage and suppresses the leakage of magnetic fluxes from the reactor main body while maintaining the opening opened.

A bushing for a transformer is provided, the bushing comprising an elongate enclosure body to accommodate a conductor extending along a longitudinal axis, the conductor having a first terminal end a second terminal end, the ends extending from opposite sides of the enclosure body; and a mounting flange fitted to the enclosure body to enable the bushing to be mounted to an enclosure of the transformer. The enclosure body comprises two electrically insulating layers partially surrounding the conductor, a first layer of the insulating layers being substantially provided by a first polymeric material, and a second layer of the insulating layers being substantially provided by a second polymeric material, the layers being arranged about the conductor in such a manner that the bushing is substantially cavity-free. In an embodiment, the first layer defines an inner core, with the second layer providing an outer cover which at least partially covers the inner core.

A bushing for a transformer is provided, the bushing comprising an elongate enclosure body to accommodate a conductor extending along a longitudinal axis, the conductor having a first terminal end a second terminal end, the ends extending from opposite sides of the enclosure body; and a mounting flange fitted to the enclosure body to enable the bushing to be mounted to an enclosure of the transformer. The enclosure body comprises two electrically insulating layers partially surrounding the conductor, a first layer of the insulating layers being substantially provided by a first polymeric material, and a second layer of the insulating layers being substantially provided by a second polymeric material, the layers being arranged about the conductor in such a manner that the bushing is substantially cavity-free. In an embodiment, the first layer defines an inner core, with the second layer providing an outer cover which at least partially covers the inner core.

A swivel component allows a power cable to a pool or spa component, to swivel when the inductive power couplings are coupled. The couplings include a first inductive coupling that can be positioned within and/or mounted into a wall fitting, a second inductive coupling that inductively couples with the first inductive coupling, a swivel component attached to the second inductive coupling for allowing the second coupling to swivel with respect to the first inductive coupling, and a retainer ring that engages with the wall fitting and retains the first and second couplings and the swivel component in position within the wall fitting. A power cable is connected at one end to the second inductive power coupling and at an opposite end to a pool or spa component, such as an electric cleaner. Swiveling of the second power coupling relative to the first power coupling reduces kinking of the power cable.