This application relates to transformers used for electric power distribution, and more particularly to shielding for coils in dry-type transformers.
Transformers are employed to increase or decrease voltage levels during electrical power distribution. To transmit electrical power over a long distance, a transformer may be used to raise the voltage and reduce the current of the power being transmitted. Reduced current levels reduce resistive losses from the electrical cables used to transmit that power. When the power is to be consumed, a transformer may be employed to reduce the voltage level and increase the current of the power to a level specified by the end user.
One type of transformer that may be employed is a dry-type, submersible transformer, as described, for example, in U.S. Pat. No. 8,614,614. Such transformers may be employed underground, in cities, etc., and may be designed to withstand harsh environments that may expose the transformers to humidity, water, pollution, and the like. Improved apparatus, assemblies, and methods for submersible and other dry-type transformers are desired.
In some embodiments, a shielded coil assembly is provided that includes (1) a coil having an outer surface, an inner surface, an upper end surface and a lower end surface and a first insulating material formed over the outer surface, inner surface, upper end surface and lower end surface of the coil; and (2) a conductive shield comprising a conductive paint applied along the first insulating material so that the conductive paint extends over at least a portion of each of the outer surface, inner surface, upper end surface, and lower end surface of the coil. In one or more embodiments, a dry-type transformer may be formed using the shielded coil assembly.
In some embodiments, a shielded coil assembly is provided that includes (1) a coil having an outer surface, an inner surface, an upper end surface and a lower end surface and a first insulating material formed over the outer surface, inner surface, upper end surface and lower end surface of the coil; and (2) a conductive shield having (a) a conductive mesh applied along the first insulating material so that the conductive mesh extends over at least a portion of the outer surface, inner surface, upper end surface, and lower end surface of the coil; and a semi-conductive paint formed over the conductive mesh. The conductive mesh and semi-conductive paint form a composite structure over at least a portion of each of the outer surface, the inner surface, the upper end surface, and the lower end surface of the coil. In one or more embodiments, a dry-type transformer may be formed using the shielded coil assembly.
In some embodiments, a method of forming a coil assembly is provided that includes (1) providing a coil having an outer surface, an inner surface, an upper end surface and a lower end surface; (2) encasing the coil in a first insulating material; and (3) forming a conductive shield over the coil by applying a conductive paint so that the conductive paint extends over at least a portion of each of the outer surface, inner surface, upper end surface, and lower end surface of the coil.
In some embodiments, a method of forming a coil assembly is provided that includes (1) providing a coil having an outer surface, an inner surface, an upper end surface and a lower end surface; (2) encasing the coil in a first insulating material; and (3) forming a conductive shield over the coil by (a) applying a conductive mesh along the first insulating material so that the conductive mesh extends over at least a portion of the outer surface, inner surface, upper end surface, and lower end surface of the coil; and (b) applying a semi-conductive paint over the conductive mesh so that the conductive mesh and semi-conductive paint form a composite structure over at least a portion of each of the outer surface, inner surface, upper end surface, and lower end surface of the coil.
Still other aspects, features, and advantages of this disclosure may be readily apparent from the following detailed description illustrated by a number of example embodiments and implementations. This disclosure may also be capable of other and different embodiments, and its several details may be modified in various respects. Accordingly, the drawings and descriptions are to be regarded as illustrative in nature, and not as restrictive. The drawings are not necessarily drawn to scale.
As mentioned above, a submersible dry-type transformer may be employed underground and/or in other harsh environments that may expose the transformer to water, humidity, pollutants, etc. When a transformer is exposed to wet, humid or otherwise hostile environments, the transformer may be susceptible to corrosion. For proper operation, as well as safety considerations, such a transformer should be grounded to prevent transmission of dangerous electrical voltages to the surrounding environment and/or to personnel in the vicinity of the transformer. This is particularly important when the transformer is submerged.
In accordance with one or more embodiments described herein, shielded coil assemblies are provided for use in dry-type transformers, as are methods for forming such shielded coil assemblies. The shielded coil assemblies have shielding that may be grounded so transformers using the shielded coil assemblies are free from static charge and/or have no dangerous voltages levels on exterior surfaces of the transformers. The shielding may be embedded in a protective layer, such as an epoxy resin, so that the shielding will not corrode if transformers employing the shielded coil assemblies are exposed to a wet or otherwise corrosive environment.
In some embodiments, a shielded coil assembly may include an inner coil and an outer coil, with shielding provided for at least the outer coil of the shielded coil assembly. For example, the outer coil may have an outer surface, an inner surface, an upper end surface and a lower end surface having an insulating material, such as an epoxy resin, formed thereon (e.g., on all surfaces). A conductive shield including a conductive paint may be applied to the insulated outer coil and extend over at least a portion of each of the outer surface, inner surface, upper end surface, and lower end surface of the outer coil. To prevent loop current formation, a gap in the conductive paint may be provided in some embodiments. A ground lead or cable may be coupled to the conductive shield, and the conductive shield may be embedded within another insulating material (e.g., an epoxy resin). In one or more embodiments, a semi-conductive paint may be provided beneath the conductive paint. For example, in some embodiments, the entire insulated outer coil may be coated with a semi-conductive paint prior to the formation of the conductive paint layer. In such embodiments, the conductive paint may be formed as a continuous layer (e.g., with the exception of a gap region employed to reduce/prevent loop currents), or the conductive paint may be provided in only some regions (e.g., by painting stripes or a grid pattern with the conductive paint). Numerous other embodiments are provided. A dry-type transformer may be formed using the shielded coil assembly in some embodiments.
In accordance with other embodiments, the conductive shield may be formed by wrapping an insulated outer coil with conductive mesh and applying a semi-conductive paint over the (and/or between) the conductive mesh. For example, the conductive mesh may be applied along the insulated outer coil so that the conductive mesh extends over at least a portion of the outer surface, the inner surface, the upper end surface, and the lower end surface of the outer coil. A gap region may be formed in the conductive mesh to reduce/prevent loop currents. The semi-conductive paint may help hold the conductive mesh in place during subsequent processing (e.g., during encapsulation of the outer coil in a second insulating material, such as an epoxy resin). Because the semi-conductive paint may be applied over the conductive mesh, as well as in any openings in the conductive mesh, the conductive mesh and semi-conductive paint may form a composite structure over at least a portion of each of the outer surface, inner surface, upper end surface, and lower end surface of the outer coil. A ground lead or cable may be coupled to the conductive shield. In one or more embodiments, a dry-type transformer may be formed using the shielded coil assembly.
By way of example, the dry-type transformer 100 may include a core assembly 102 (shown in phantom) mounted between an upper frame portion 104U and lower frame portion 104L. In one or more embodiments, insulating sheets (not shown) may be provided to insulate the sides of the core assembly 102 from the respective upper and lower frames 104U, 104L, while in other embodiments such insulating sheets (not shown) may not be used. In some embodiments, core assembly 102 may be formed from multiple laminations of a magnetic material. Example magnetic materials include iron, steel, amorphous steel or other amorphous magnetically permeable metals, silicon-steel alloy, carbonyl iron, ferrite ceramics, and/or combinations of the above materials, or the like. In some embodiments, laminated ferromagnetic metal materials having high cobalt content may be used. Other suitable magnetic materials may be used.
As shown, core assembly 102 may include multiple interconnected pieces and may include vertical core columns or regions 102L, 102C, and 102R (each shown in phantom). Vertical core columns 102L, 102C, and 102R may be assembled with top and bottom core members 102T, 102B (shown in phantom). Construction may include step-laps between respective components of the core assembly 102. Construction of the core assembly 102 may be as is shown in U.S. Pat. No. 8,212,645, for example. Other configurations of the core assembly 102 may be used. In some embodiments, within transformer 100, each core column 102L, 102C, and 102R may be surrounded by a coil assembly, namely coil assemblies 106, 108, 110.
Referring again to
Each of the coil assemblies 106, 108, 110 of the transformer 100 may be provided with high voltage terminals 118 that in one embodiment may be positioned at a top front of the respective coil assemblies 106, 108, 110. Low voltage terminals 119 of the low voltage inner coil 112 (
The transformer 100 may also include delta connections 120A, 120B, and 120C (
A tap changer assembly 132 may be included on each of the high-voltage outer coils 114. For example, the tap changer assembly 132 may be provided as an extension from a front of the high-voltage outer coil 114. More particularly, the tap changer assembly 132 may be, as shown in
The high-voltage outer coil 114 of each of the coil assemblies 106, 108, 110 may include a grounding terminal 128. Grounding conductors 129 (
A conductive shield 210 (shown in phantom) may provide shielding to each of the surfaces of high-voltage outer coil 114 (as described further below). The conductive shield 210 may be highly electrically conductive so as to provide a low resistance path to ground for static charge and/or high voltage levels on the exterior surfaces of high-voltage outer coil 114. The grounding terminal 128 is connected to the conductive shield 210 thereby providing a means of electrically grounding the outer surface of high-voltage outer coil 114.
A loop separator region 212 may be included in the conductive shield 210 across each of the surfaces of high voltage outer coil 114 on which the conductive shield 210 is formed. As shown, the loop separator region 212 is formed as an interruption in the conductive shield 210 (beneath each of the outer surface 202, the inner surface 204, the upper end surface 206, and the lower end surface 208 of the high-voltage outer coil 114). The loop separator region 212 forms a continuous loop that is devoid of electrically-conductive material (e.g., an open loop). The inclusion of the loop separator region 212 in the conductive shield 210 helps prevent the creation of loop currents on the surfaces of the high-voltage outer coil 114.
In an aspect with broad applicability to transformers, an improved conductive shield 210 applied to each of the surfaces of the high-voltage outer coil 114 is provided.
Formation of the conductive shield 210 of high-voltage outer coil 114 is illustrated in
With reference to
Example conductive shields for high-voltage outer coil 114 are described below with reference to
A conductive shield 210 is formed over the first insulating material 216. Specifically, the conductive shield 210 is formed over insulating material 216 on at least a portion of each surface comprising the high-voltage outer coil 114. For example, as shown in
In some embodiments, the conductive shield 210 may be a conductive paint applied to the first insulating material 216. The conductive paint may be comprised of a conductive metal including one or more of copper, nickel, silver-coated copper, nickel-silver, and silver. Other suitable conductive paints may be used. In some embodiments, the conductive paint may have an electrical resistance between about 0.01 Ohm/sq in/mil to 1 Ohm/sq in/mil and/or have a thickness of between about 30 and 500 microns, and in some embodiments between about 30 and 150 microns, as applied, although other suitable resistances and/or thickness ranges may be used (wherein “sq in” is an abbreviation for “square inch” and “mil” is 0.001 inch). The conductive paint may be applied by any suitable process, such as brushing, rolling, spraying, and dipping. Moreover, a stencil or mask may be used to form a pattern on the first insulating material 216, the pattern including a grid pattern, a striped pattern or any other suitable pattern. In some embodiments, the application of the conductive shield 210 may be done in a manner that ensures its electrical continuity across each of the surfaces of the high-voltage outer coil 114 (e.g., each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of the high-voltage outer coil 114).
In some embodiments, the conductive shield 210 may include a loop separator region 212. The loop separator region 212 may be formed by an interruption in the conductive shield 210 on each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of the high-voltage outer coil 114 (
In some embodiments, a ground connection 310 may be coupled to the conductive shield 210. For example, in some embodiments, the ground connection 310 may be a metal plate in direct contact with the conductive shield 210 or a conductive tape formed over or under the conductive shield 210. When the conductive shield 210 comprises conductive paint, at least a portion of the ground connection 310 may be placed on top of or underneath the conductive paint, for example. Other ground connections may be used. A ground terminal 312 may be attached to the ground connection 310 to which an external ground lead or cable may be attached. Ground connection 310 and/or ground terminal 312 may be formed from any suitable material such as copper, brass, aluminum or the like. In some embodiments, one or more of high voltage terminal 118, upper terminal 122, lower terminal 124, ground terminal 128, and/or tap changer assembly 132 may be masked during application of the conductive shield 210.
A second insulating material 314 may be applied over the conductive shield 210 and the ground connection 310. As with the first insulating material 216, the insulating material may be an epoxy resin, polyurethane, polyester, silicone, or the like. Other suitable insulating materials may be employed. Whichever insulating material is employed, the second insulating material 314 may protect the conductive shield 210 from humidity, water, pollution, and the like.
In the embodiment of
Semi-conductive paint 316 may be similar in composition to conductive paint 317 in that it may be comprised of a conductive metal including one or more of copper, nickel, silver-coated copper, nickel-silver, and silver. Other suitable semi-conductive paint types may be used. Semi-conductive paint 316 differs from conductive paint 317 in that it generally encompasses a higher electrical resistance range. In some embodiments, the semi-conductive paint 316 may have an electrical resistance between about 1 kilo-ohm/sq in/mil to 10 kilo-ohm/sq in/mil and/or a thickness of between about 10 and 500 microns, and in some embodiments between about 10 and 50 microns, as applied, although other suitable electrical resistances and/or thickness ranges may be used.
After formation of the layer of semi-conductive paint 316, conductive paint 317 is formed over the layer of semi-conductive paint 316. For example, the conductive paint 317 may be formed over the semi-conductive paint 316 that was formed on first insulating material 216, with the conductive paint 317 covering at least a portion of each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 that was covered with semi-conductive paint 316. Conductive shield 210, which includes conductive paint 317 and underlying semi-conductive paint 316, is therefore formed on at least a portion of each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of high-voltage outer coil 114 (as shown in
Conductive paint 317 may be comprised of a conductive metal including one or more of copper, nickel, silver-coated copper, nickel-silver, and silver. Other suitable conductive paints may be used. In some embodiments, the conductive paint 317 may have an electrical resistance between about 0.01 Ohm/sq in/mil to 1 Ohm/sq in/mil and/or have a thickness of between about 30 and 500 microns, and in some embodiments between about 30 and 150 microns, as applied, although other suitable resistance and/or thickness ranges may be used. The semi-conductive paint 316 and/or conductive paint 317 may be applied by any suitable process, such as brushing, rolling, spraying, and dipping. In some embodiments, a stencil or mask may be used to form a pattern of conductive paint on the layer of semi-conductive paint 316 formed over the first insulating material 216, the pattern including a grid pattern, a striped pattern or any other suitable pattern. In some embodiments, the application of the conductive shield 210 may be done in a manner that ensures its electrical continuity across each of the surfaces of the high-voltage outer coil 114 (e.g., across each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of the high-voltage outer coil 114).
In some embodiments, the conductive shield 210 may include a loop separator region 212. The loop separator region 212 is formed as an interruption in the conductive paint 317 portion of conductive shield 210 on each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of the high-voltage outer coil 114 (
The semi-conductive paint 316 exposed in the loop separator region 212 in conductive paint 317 helps prevent leakage of an electric field through the loop separator region 212 during operation of the high-voltage outer coil 114. Moreover, the higher electrical resistance range of the layer of the semi-conductive paint 316 helps prevent the formation of a ground loop within the layer of semi-conductive paint 316 (even though the semi-conductive paint 316 may be present in the loop separator region 212). In one or more embodiments, semi-conductive paint 316 may have a resistance that is high enough to prevent the formation of (measurable) current loops on the surfaces of the high-voltage outer coil 114.
In some embodiments, a ground connection 310 may be coupled to the conductive shield 210. For example, in some embodiments, the ground connection 310 may be a metal plate in direct contact with the conductive shield 210 or a conductive tape formed over or under the conductive shield 210. When the conductive shield 210 comprises conductive paint, at least a portion of the ground connection 310 may be placed on top of or underneath the conductive paint (e.g., on top of semi-conductive paint 316), for example. Other ground connections may be used. A ground terminal 312 may be attached to the ground connection 310 to which an external ground lead or cable may be attached. In some embodiments, one or more of high voltage terminal 118, upper terminal 122, lower terminal 124, ground terminal 128, and/or tap changer assembly 132 may be masked during application of the conductive shield 210.
A second insulating material 314 may be applied over the conductive shield 210 and the ground connection 310. As with the first insulating material 216, the insulating material may be an epoxy resin, polyurethane, polyester, silicone, or the like. Other suitable insulating materials may be employed. Whichever insulating material is employed, the second insulating material 314 may protect the conductive shield 210 from humidity, water, pollution, and the like.
As mentioned, the combination of the conductive shield 210 and the ground connection 310 provides for a low resistance path to ground for static charge and/or high voltages distributed across the exterior surfaces of the high-voltage outer coil 114.
In the embodiment of
Conductive mesh 318 may be comprised of a conductive material formed into a pattern (e.g., a grid or screen). Example conductive materials for the conductive mesh 318 include conductive metals such as one or more of copper, nickel, silver-coated copper, nickel-silver, silver or the like, although other types of conductive meshes may be used. In some embodiments, conductive mesh 318 may have an electrical resistance of between about 0.01 to 1 Ohm/sq cm, although other suitable electrical resistance ranges may be used.
In some embodiments, semi-conductive paint (not separately shown) may be used to hold conductive mesh 318 in place and/or to fill the gaps regions of conductive mesh 318. The semi-conductive paint applied to the conductive mesh 318 may be comprised of a conductive metal including one or more of coal powder, copper, nickel, silver-coated copper, nickel-silver, and silver, although other suitable types of semi-conductive paint may be used. In some embodiments, the semi-conductive paint may have an electrical resistance of between about 1 kilo-ohm/sq in/mil to 10 kilo-ohm/sq in/mil, although other suitable electrical resistance ranges may be used.
Once the conductive mesh 318 has been positioned on the first insulating material 216, semi-conductive paint may be applied to the conductive mesh 318 by any suitable process, such as brushing, rolling, spraying, and dipping. The composite structure of conductive mesh material and semi-conductive paint serves as conductive shield 210. In some embodiments, the composite structure may have a thickness of between about 100 and 500 microns, although other suitable thickness ranges may be used.
In some embodiments, the conductive shield 210 may include a loop separator region 212. The loop separator region 212 may be formed as an interruption in the conductive shield 210 on each of the outer surface 220a, the inner surface 220b, the upper end surface 220c and the lower end surface 220d of first insulating material 216 of the high-voltage outer coil 114 (
In some embodiments, a ground connection 310 may be coupled to the conductive shield 210. For example, in some embodiments, the ground connection 310 may be a metal plate in direct contact with the conductive shield 210 or a conductive tape formed over or under the conductive shield 210. When the conductive shield 210 comprises conductive mesh with semi-conductive paint, at least a portion of the ground connection 310 may be placed on top of or underneath the conductive mesh, for example. Other ground connections may be used. A ground terminal 312 may be attached to the ground connection 310 to which an external ground lead or cable may be attached. In some embodiments, one or more of high voltage terminal 118, upper terminal 122, lower terminal 124, ground terminal 128, and/or tap changer assembly 132 may be masked during application of the conductive shield 210.
A second insulating material 314 may be applied over the conductive shield 210 and the ground connection 310. As with the first insulating material 216, the insulating material may be an epoxy resin, polyurethane, polyester, silicone, or the like. Other suitable insulating materials may be employed. Whichever insulating material is employed, the second insulating material 314 may protect the conductive shield 210 from humidity, water, pollution, and the like.
Now referring to
The method 400 further includes, in 404, providing the outer surfaces of the coil (e.g., winding 214) with a layer of a first insulating material (e.g., first insulating material 216 of
Further, the method 400 includes, in 406, providing a conductive shield (e.g., conductive shield 210) over at least a portion of each of the outer surface, the inner surface, the upper end surface and the lower end surface of the coil. The conductive shield may be a conductive paint (e.g.,
Moreover, the method 400 includes, in 408, providing a ground connection (e.g., grounding connection 310) coupled to the conductive shield. In some embodiments, the ground connection may be a metal plate in direct contact with the conductive shield, a conductive tape formed over or under the conductive shield or the like. A ground terminal may be attached to the ground connection, and an external ground lead or cable may be attached thereto.
Additionally, the method 400 further includes, in 410, providing the coil with a layer of a second insulating material on the outside surfaces of the coil (e.g., second insulating material 314). The layer of second insulating material may fully encapsulate or encase the conductive shield on the surfaces of the coil. As with the first insulating material, the second insulating material may be an epoxy resin, polyurethane, polyester, silicone, or the like.
The embodiments described with reference to
In some embodiments, the conductive shield may be configured to overlap itself while maintaining a loop separator region. Such an arrangement may be used, for example, in very high electric field applications.
A similar overlap in conductive shield 210 may be employed when conductive shield 210 includes an underlying semi-conductive paint layer (
While the present disclosure is described primarily with regard to submersible dry-type transformers, it will be understood that the disclosed conductive shields may also be employed with other types of transformers or coil assemblies, such as inductors.
The foregoing description discloses only example embodiments. Modifications of the above-disclosed assemblies and methods which fall within the scope of this disclosure will be readily apparent to those of ordinary skill in the art. For example, although the examples discussed above are illustrated for dry-type transformers, other embodiments in accordance with this disclosure may be implemented for other devices. This disclosure is not intended to limit the invention to the particular assemblies and/or methods disclosed, but, to the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the claims.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/090317 | 6/7/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/232763 | 12/12/2019 | WO | A |
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Number | Date | Country | |
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20210151246 A1 | May 2021 | US |