초록 ▼

A power transformer having at least one high voltage winding and one low voltage winding. Each of the windings includes at least one current-carrying conductor, a first layer having semiconducting properties provided around said conductor, a solid insulating layer provided around said first layer, a

A power transformer having at least one high voltage winding and one low voltage winding. Each of the windings includes at least one current-carrying conductor, a first layer having semiconducting properties provided around said conductor, a solid insulating layer provided around said first layer, and a second layer having semiconducting properties provided around said insulating layer. The windings are intermixed such that turns of the high voltage winding are mixed with turns of the low voltage winding.

대표청구항 ▼

1. A transformer comprising:a high voltage winding having turns, and a low voltage winding having turns, wherein, each of said high voltage winding and said low voltage winding being magnetically permeable and having a flexible conductor that is configured to contain an electric field, and the turns

1. A transformer comprising:a high voltage winding having turns, and a low voltage winding having turns, wherein, each of said high voltage winding and said low voltage winding being magnetically permeable and having a flexible conductor that is configured to contain an electric field, and the turns of the high voltage winding being intermixed with turns of the low voltage winding, said flexible conductor includes, a central electrical conductor, a first layer having semi-conducting properties provided around said electrical conductor, a solid insulating layer provided around said first layer, and a second layer having semi-conducting properties provided around said solid insulating layer and configured to contain an electric field in the flexible conductor, wherein said central conductor includes a plurality of strands of wire, a portion of said strands being insulated strands such that at most only a minority of said plurality of strands being in electrical contact with other strands that are not insulated. 2. A transformer according to claim 1, wherein:said low voltage winding being wound as a low voltage winding layer positioned between two corresponding adjacent high voltage winding layers. 3. A transformer according to claim 1, wherein:respective layers of said high voltage winding and said low voltage winding being arranged in a repeated periodic pattern comprising one high voltage winding layer, followed by a low voltage winding layer, followed by two high voltage winding layers, and followed by repetitions of a low voltage winding layer, followed by another two high voltage winding layers. 4. A transformer according to claim 1, wherein:at least one of the turns of the low voltage winding being split into subturns, each of said subturns being connected in parallel so as to reduce a difference between a number of high voltage winding turns and a number of low voltage winding turns. 5. A transformer according to claim 4, wherein:each turn of the low voltage winding being split into parallel-connected subturns equal in number to a corresponding number of high voltage winding turns. 6. A transformer according to claim 5, wherein:the turns of the high voltage winding and the turns in the low voltage winding being arranged symmetrically in a chessboard pattern, when viewed in a cross-section through said high voltage winding and said low voltage winding. 7. A transformer according to claim 1, wherein:a potential on said first layer being substantially equal to a potential on the conductor. 8. A transformer according to claim 1, wherein:said second layer being arranged to constitute substantially an equipotential surface surrounding said conductor. 9. A transformer according to claim 8, wherein:said second layer being connected to a node at a predetermined potential. 10. A transformer according to claim 9, wherein:said predetermined potential being ground potential. 11. A transformer according to claim 1, wherein:at least one pair of said first layer and said solid insulating layer, and said solid insulating layer and said second layer having substantially equal thermal expansion coefficients. 12. A transformer according to claim 1, wherein:each of said first layer, said solid insulating layer and said second layer being fixedly connected to a respective adjacent layer along substantially a whole connecting surface. 13. A transformer according to claim 1, wherein:a cross-section area of said central electrical conductor being in an inclusive range of 80 through 3000 mm. 14. A transformer according to claim 1, wherein:an external diameter of the flexible conductor being in an inclusive range of 20 though 250 mm. 15. A transformer according to claim 1, further comprising:struts of laminated magnetic material located between said high voltage winding and said low voltage winding. 16. A transformer according to claim 1, wherein:the electric field contained in the flexible conductor being from a high voltage in said conductor in excess of 36 kV. 17. A transformer according to claim 1, wherein:the flexible conductor being configured to handle a power in excess of 0.5 MVA. 18. A method of winding a transformer, comprising steps of:simultaneously winding a high voltage flexible conductor and a low voltage flexible conductor configured to contain an electric field and being magnetically permeable to form a high voltage winding and a low voltage winding, and intermixing turns of the high voltage winding with turns of the low voltage winding, wherein said flexible conductor includes, a central electrical conductor, a first layer having semi-conducting properties provided around said electrical conductor, a solid insulating layer provided around said first layer, and a second layer having semi-conducting properties provided around said solid insulating layer and configured to contain an electric field in the flexible conductor, and said central conductor includes a plurality of strands of wire, a portion of said strands being insulated strands such that at most only a minority of said plurality of strands being in electrical contact with other strands that are not insulated. 19. A method according to claim 18 wherein:said simultaneously winding step comprises simultaneously unwinding the high voltage winding and the low voltage winding from respective drums and winding the high voltage flexible conductor and the low voltage flexible conductor on to a transformer drum. 20. A transformer comprising:a high voltage winding having turns, and a low voltage winding having turns, wherein, each of said high voltage winding and said low voltage winding comprising means for handling a high voltage and containing an electric field associated with said high voltage, and the turns of the high voltage winding being intermixed with turns of the low voltage winding, said means for handling a high voltage includes means for setting an electric potential of an outer surface of at least one of said high voltage winding and said low voltage winding to ground potential, wherein said means for handling a high voltage includes a flexible conductor, said flexible conductor includes, a central electrical conductor, a first layer having a semi-conducting properties provided around said electrical conductor, a solid insulating layer provided around said first layer, and a second layer having semi-conducting properties provided around said solid insulating layer an configured to contain an electric field in the flexible conductor, and said central conductor includes a plurality of strands of wire, a portion of said strands being insulated strands such that at most only a minority of said plurality of strands being in electrical contact with other strands that are not insulated.