The invention relates to a winding unit for connecting to a high-voltage grid, having a winding which is embedded in a solid insulating body, a first connection terminal which is connected to a first winding end of the winding and is arranged on a first support which is formed on the insulating body, and a second connection terminal which is connected to a second winding end of the winding, wherein the winding comprises partial windings and taps, by means of which the number of series-connected turns of the partial windings can be adjusted, and which are respectively connected, by means of an outgoing line which extends in the insulating body, to a tap connection terminal which is accessible from the exterior.
In practice, a winding unit of this type will be known to a person skilled in the art, wherein the known winding unit is illustrated in an end face view in
An upper main connection terminal 19 can be seen at the free end of a support 1 which is formed on the resin block 11. A lower main connection terminal 20 is correspondingly configured at the free end of a support 2 which is likewise formed on the resin block 11. In order to interconnect the main connection terminals 19 and 20, it is necessary for two tap connection terminals to be connected to one another. By the connection of the tap connection terminals 5 and 6, the number of series-connected turns of the higher-voltage winding 12 is at a maximum. Connection of the tap connection terminals 4 and 7 results in the series connection of an intermediate number of turns, whereas a connection of the tap connection terminals 3 and 8 results in the series connection of turns, the number of which is comparatively the smallest.
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The known winding unit is handicapped by a disadvantage, in that the outgoing lines 15, 16 and 18 which are centrally routed through the resin block prevent the enclosure of the higher-voltage winding in a shielding cage over its entire periphery. In order to permit the passage of the outgoing lines 15, 16 and 18, the shielding cage would be required to incorporate an opening, as a result of which the shielding effect would be negated.
The object of the invention is the provision of a winding unit of the abovementioned type which permits the higher voltage to be encapsulated in the resin block over its entire periphery, by means of a shielding cage.
This object is fulfilled by the invention by configuring the tap connection terminals on the support.
Conversely to the known solution from the prior art, within the context of the invention, the tap connection terminals are no longer centrally configured on the insulating body or, in other words, the winding block, but are configured in combination with one of the main connection terminals on the support. As the support is generally arranged at the end face of the higher-voltage winding which is arranged in the insulating body, the connecting lines of the taps can also be brought out of the end face of the winding. In this manner, connecting lines which extend out of the insulating body in a transverse direction from a centrally arranged tap in the insulating body are eliminated. Accordingly, the winding unit can be equipped with a shielding in the insulating body which entirely encloses the winding, in the manner of a cage. The shielding is advantageously arranged in the immediate vicinity of the winding. The winding is advantageously a higher-voltage winding, which is consequently rated for higher voltages and lower currents.
Advantageously, each support assumes a rotationally symmetrical configuration and is equipped with ribs, wherein each support extends in a longitudinal direction, and the tap connection terminals between two ribs are arranged in an evenly-distributed manner over the periphery of the respective support. According to this advantageous configuration of the invention, ribs are provided on the support in order to extend the path for creepage currents, such that the latter, insofar as possible, are entirely suppressed. Creepage currents are undesirable, as these can compromise the dielectric strength of the insulating body.
Advantageously, the first main connection terminal is configured at the free end of the support.
Advantageously, the first turn of the higher-voltage winding is connected to the main connection terminal by means of an outgoing line which extends over the full length of the support.
In one configuration of the invention, the tap connection terminals are arranged with an offset in relation to the insulating body, and are thus configured with a clearance to the first main connection terminal.
In a further variant, all the tap connection terminals are arranged at the same level, and are spaced from the first main connection terminal by means of at least one rib. It is appropriate that the number of turns between the first end face turn of the winding and the taps should be as small as possible. The potential difference between the first main connection terminal and the tap connection terminals on the support would otherwise be too great for the latter to be arranged in combination on one support and separated from one another by one rib only.
Advantageously, the number of turns of the first partial winding, the uppermost end face turn of which is connected to the first main connection terminal and the final turn of which is connected to a tap connection terminal on the support, lies between 1 and 20, conversely to the number of turns of the second partial winding, the first end face turn of which is connected to a tap connection terminal and the final turn of which is connected to the second main connection terminal.
Appropriately, a second support is provided, which extends from the winding body at the free end thereof, wherein the second main connection terminal is configured at the free end of the second support. According to this advantageous further development, two main connection terminals are provided, each of which is arranged at the free end of a support. Between the connection terminals, by bridging of the appropriately selected tap connection terminals, the number of turns between the first and the second main connection terminal, and thus the voltage, can be adjusted.
According to an appropriate further development with respect hereto, the second support also comprises ribs. Here again, the function of said ribs is to extend the creepage path, thereby increasing the dielectric strength of the winding unit.
Advantageously, the insulating body and each of the supports are comprised of a cured resin. As an appropriate resin, epoxy resin can be considered for this purpose, wherein appropriate admixtures are added to the resin for the curing thereof. However, insulating bodies of resin will be known to a person skilled in the art, such that any detailed descriptions thereof can be omitted at this point.
According to a preferred configuration of the invention, a flexible cap which is attached to the support is provided, the function of which is to protect the tap connection terminals. The cap, for example, is formed of a flexible elastomer, and serves for the exclusion of dirt, rainwater or similar. On the grounds of the flexibility of the cap, the latter can be pulled over the respective ribs of the support, optionally over the tap connection terminals.
Further advantageous configurations and advantages of the invention are the subject matter of the following description of exemplary embodiments of the invention, with reference to the figures and the drawing, wherein identically functioning components are identified by the same reference numbers, and wherein:
The winding unit 10 according to the invention represented in
The partial windings 13, 14 moreover differ with respect to the number of turns. Whereas, in the winding unit 11 according to
In
The support 2, at the free end of which the second main connection terminal 20 is located, is also equipped with external ribs 22.
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Number | Date | Country | Kind |
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10 2017 220 779.5 | Nov 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/079127 | 10/24/2018 | WO | 00 |