The invention relates to an electrotechnical coil, to a method for producing same, and to an electromagnet or an electric machine comprising at least one such coil. The aim of the invention is to produce and use an electrotechnical coil for achieving an increased slot fill factor reliably and easily in a reproducible and economical manner. This is achieved in that the method according to the invention has the steps: step A: casting an electrotechnical coil with at least one winding which runs about a coil axis; and step B: shaping the coil, thereby changing the cross-section Q, Q′ of the at least one winding, such that the centroid FS, FS′ of the cross-section Q, Q′ of the at least one winding is displaced at least partly in the radial direction R relative to the coil axis A.

The invention relates to an electrotechnical coil, to a method for producing same, and to an electromagnet or an electric machine comprising at least one such coil. The aim of the invention is to produce and use an electrotechnical coil for achieving an increased slot fill factor reliably and easily in a reproducible and economical manner. This is achieved in that the method according to the invention has the steps: step A: casting an electrotechnical coil with at least one winding which runs about a coil axis; and step B: shaping the coil, thereby changing the cross-section Q, Q′ of the at least one winding, such that the centroid FS, FS′ of the cross-section Q, Q′ of the at least one winding is displaced at least partly in the radial direction R relative to the coil axis A.

Embodiments of the disclosure provide an integrated circuit (IC) structure. The IC structure may include a first metal layer on a substrate, and a second metal layer on the substrate that is horizontally separated from the first metal layer. A dielectric material may include a first portion on the first metal layer, and having a first upper surface, a second portion on the second metal layer, and having a second upper surface, and a third portion on the substrate between the first metal layer and the second metal layer. The third portion of the dielectric material includes a third upper surface above the first upper surface of the first portion and the second upper surface of the second portion of the dielectric material.

Embodiments of the disclosure provide an integrated circuit (IC) structure. The IC structure may include a first metal layer on a substrate, and a second metal layer on the substrate that is horizontally separated from the first metal layer. A dielectric material may include a first portion on the first metal layer, and having a first upper surface, a second portion on the second metal layer, and having a second upper surface, and a third portion on the substrate between the first metal layer and the second metal layer. The third portion of the dielectric material includes a third upper surface above the first upper surface of the first portion and the second upper surface of the second portion of the dielectric material.

A coil component includes a body; a supporting substrate embedded in the body; a coil portion including a coil pattern, and a lead-out pattern exposed to an outside of the body through an external surface of the body, and disposed on the supporting substrate and embedded in the body; and an insulating film disposed between the coil portion and the body, wherein at least a portion of the lead-out pattern contacts the body through an opening formed in the insulating film.

A coil component includes a body; a supporting substrate embedded in the body; a coil portion including a coil pattern, and a lead-out pattern exposed to an outside of the body through an external surface of the body, and disposed on the supporting substrate and embedded in the body; and an insulating film disposed between the coil portion and the body, wherein at least a portion of the lead-out pattern contacts the body through an opening formed in the insulating film.

The present invention relates to a method for manufacturing a pole-mounted transformer using no insulation oil, and a pole-mounted transformer manufactured using same, wherein the transformer uses a solid insulation material and an insulation oil is removed from the transformer, and more specifically, to a method for manufacturing a pole-mounted transformer using no insulation oil and a pole-mounted transformer manufactured using same, the method comprising: a first coil part formation step of winding a low-voltage coil and a high-voltage coil to produce a first coil part; a casting step of putting the first coil part into a mold and filling an empty space between the outer peripheral portion of the first coil part and a wound wire with a casting insulation material in a liquid or gel phase, followed by solidification, so as to produce a second coil part; a conductive material attachment step of coupling a conductive material to the outer peripheral surface of the second coil part to produce a third coil part; an iron core coupling step of coupling an iron core to the third coil part; and a transformer completion step of inserting, into an outer case, the third coil part having the iron core coupled thereto to complete a product.

The present invention relates to a method for manufacturing a pole-mounted transformer using no insulation oil, and a pole-mounted transformer manufactured using same, wherein the transformer uses a solid insulation material and an insulation oil is removed from the transformer, and more specifically, to a method for manufacturing a pole-mounted transformer using no insulation oil and a pole-mounted transformer manufactured using same, the method comprising: a first coil part formation step of winding a low-voltage coil and a high-voltage coil to produce a first coil part; a casting step of putting the first coil part into a mold and filling an empty space between the outer peripheral portion of the first coil part and a wound wire with a casting insulation material in a liquid or gel phase, followed by solidification, so as to produce a second coil part; a conductive material attachment step of coupling a conductive material to the outer peripheral surface of the second coil part to produce a third coil part; an iron core coupling step of coupling an iron core to the third coil part; and a transformer completion step of inserting, into an outer case, the third coil part having the iron core coupled thereto to complete a product.

A spacer tape is provided for spacing apart turns of a winding, which comprises a tape having an upper surface, a lower surface and a longitudinal axis, wherein the lower surface is adhesable and configured to be adhered to a conductor forming a turn of the winding, and spacers with an upper surface and a lower surface arranged on the tape, wherein the lower surface of the spacers is adhered to the upper surface of the tape, and wherein the upper surface of the spacers are adhesable and configured to be adhered to the conductor forming an adjacent turn of the winding.

There are provided a reactor, a reactor coil covering, and a method for manufacturing a reactor, which are capable of preventing peeling off of an insulation coat with which an outer peripheral surface of a winding is covered. A reactor includes a core, a coil disposed on an outer periphery of the core, and a resin mold portion partially covering and integrating the core and the coil. A winding of the coil has an outer peripheral surface covered with an insulation coat. At least one part of a surface of the coil is covered with a protective membrane to cover a boundary between adjacent turns of the coil.