EP2115754A1 - Transformer - Google Patents

Abstract

A transformer (10) with an insulation arrangement between a high voltage winding (4) and a low voltage winding (8) for potential isolation, or an insulation arrangement for potential isolation between a high voltage winding (4) and a low voltage winding (8) of a transformer, has a layered structure, comprising inner insulation (2; 2a, 2b) between the high voltage winding (4) and the low voltage winding (8), which are adjoined by at least one semiconductive layer (6, 6a, 6b). In this way, the dimensions of a transformer can be reduced, and, in addition, partial discharges towards the outside can be reduced or entirely suppressed.

Description

 transformer

The invention relates to a transformer with a voltage insulation between a high-voltage winding and a low-voltage winding for potential separation. In particular, the invention relates to a high-voltage transformer, in particular to the insulation for electrical isolation, between the high-voltage winding and the undervoltage winding. Furthermore, the invention relates to an insulation arrangement for potential separation between a high-voltage winding and a low-voltage winding of a transformer.

High voltage transformers are needed to adapt to different voltage levels. For example, an oil-immersed furnace transformer transforms a voltage of 110 kV to a voltage of 1.5 kV

Mains transformer in oil version a voltage of 110 kV to 0.4 kV and a distribution transformer in dry version a voltage of 33 kV to 0.4 kV. The power for such transformers starts at approx. 0.4 megawatts and can amount to more than 100 megawatts.

One problem is that in high-voltage transformers in the power range, from 36 kV an oil insulation is necessary, or at a dry insulation below 36 kV, large air gaps between the high voltage winding and undervoltage winding are respected or a very expensive complete casting resin is required. When using known dry insulation, a partial discharge takes place at high voltages on the surface of the insulation, which limits the reliability of the transformer or makes the construction impossible.

Today, no high-voltage transformers in the high power range are known, which manage above 36 kV without oil insulation. Dry transformers are built without oil insulation up to a voltage of 36 kV. These are cast resin transformers in which a casting resin for Isolation is used. Furthermore, insulating materials having a multilayer structure are known. However, these have no electrically conductive layers with defined potential in combination with insulating layers and semiconducting layers. Furthermore, there are pure dry transformers up to 20 kV, but with the disadvantage of requiring very large air gaps, this in turn requires large dimensions and is very expensive.

From DE 17 63 515 A, a high-voltage transformer is known in which in a layer structure of the high-voltage insulation, an electrically conductive layer is set to high voltage potential and another electrically conductive layer to undervoltage potential. Due to the potential conditions, partial discharges occur on the surface of the layer subjected to the undervoltage, which destroy the insulation.

An object of the invention is to provide an insulation arrangement for potential separation between the high-voltage winding and the low-voltage winding of a transformer or a transformer with a corresponding insulation arrangement, which at higher voltages, e.g. above 36 kV, without oil insulation, or with which the air gaps at lower voltages, e.g. below 36 kV, can be reduced.

The invention relates to a transformer according to the features of claim 1. Furthermore, the invention relates to an insulation assembly according to the features of claim 21. Embodiments and advantageous embodiments of the invention are set forth in the dependent claims.

In particular, the invention relates to a transformer having an insulation arrangement between a high-voltage winding and a negative voltage winding for potential separation, which has a layer structure, comprising an inner insulation between the high-voltage winding and the low-voltage winding, to which at least one semiconducting layer is adjacent.

Furthermore, the invention relates in particular to an insulation arrangement for potential separation between a high-voltage winding and a Undervoltage winding of a transformer, which has a layer structure comprising an internal insulation for the arrangement between the high-voltage winding and the low-voltage winding of the transformer, to which at least one semiconducting layer is adjacent.

The advantage of the invention is that it allows to transform a transformer above a relatively high voltage, e.g. of 36 kV without realizing a risky oil design or at relatively low voltages, e.g. Below 36 kV, to reduce the partial discharge and the air gaps and thus reduce the dimensions of the transformer. In particular, partial discharges to the outside can be substantially reduced or completely prevented.

In one embodiment, the inner insulation on a first and second side, which are in particular opposite sides, adjoin a respective semiconductive layer.

In a further embodiment, the transformer comprises a first electrically conductive layer, which is laid to a first defined potential and which is arranged between the high-voltage winding and the inner insulation. In particular, the first electrically conductive layer is set to a first defined potential, which is equal to or at least close to the upper voltage of the high-voltage winding.

In a further embodiment, the transformer alternatively or additionally comprises a second electrically conductive layer which is laid to a second defined potential and which is arranged between the low-voltage winding and the inner insulation. In particular, the second electrically conductive layer is set to a second defined potential, which is equal to or at least close to the undervoltage winding undervoltage.

The electrically conductive layers may be supplied by an external voltage source, which may have a current limiting, or by the winding voltages of the transformer. In a further embodiment of the invention, the transformer comprises a first inner insulation between the high-voltage winding and the low-voltage winding, to which at least a first semiconductive layer adjoins, and a second inner insulation between the high-voltage winding and the lower-voltage winding, to which at least one second semiconductive layer adjoins.

In this embodiment, a first electrically conductive layer, which is laid to a first defined potential and which is arranged between the high-voltage winding and the first inner insulation, also a second electrically conductive layer, which is placed on a second defined potential and the is disposed between the first inner insulation and the second inner insulation, and a third electrically conductive layer which is placed on a third defined potential and which is arranged between the lower voltage winding and the second inner insulation.

In particular, the first electrically conductive layer is set to a first defined potential, which is equal to or at least close to the upper voltage of the high voltage winding, and the third electrically conductive layer is set to a third defined potential, which is equal to or at least close to the undervoltage winding undervoltage. The second electrically conductive layer is preferably set to approximately half the total potential difference between the high-voltage winding and the low-voltage winding. The first and third electrically conductive layers can be insulated from the upper or lower voltage winding by a respective insulation layer.

In one embodiment of the invention, the first electrically conductive layer is followed by the first inner insulation, followed by the first semiconductive layer and the second electrically conductive layer, followed by the second inner insulation, followed by the second semiconductive layer and the third electrically conductive layer ,

In principle, such an arrangement according to the invention can be extended in a modular manner to a plurality of internal isolations with respective semiconducting layers become. In other words, the layer structure can be connected in series. In this way, 2, 3, 5, etc. successive layers are possible. For example, another embodiment includes an arrangement in which the third electrically conductive layer is followed by a third inner insulation, followed by a third semiconductive layer and a fourth electrically conductive layer which is set at a fourth defined potential equal to the undervoltage or at least close. Accordingly, the second and third electrically conductive layer are placed on a respective intermediate potential between the upper and lower voltage, for example, two-thirds or one-third of the total potential difference between the high-voltage winding and low-voltage winding.

An aspect of the invention consists, in particular, in a high-voltage insulation for potential separation, which has a firmly connected layer structure, with an electrically conductive layer, electrically connected or insulated to the upper voltage, wherein in an insulated embodiment, the electrically conductive layer is set to a defined potential, which of the upper voltage followed by an internal insulation, followed by a semiconducting layer to prevent partial discharges at the surface of the insulation and another electrically conductive layer, connected or isolated to the undervoltage, wherein in an insulated embodiment, the electrically conductive layer is set to a defined potential which is close to the undervoltage.

The electrically conductive layers may be supplied by an external voltage source, which may have a current limiting, or by the winding voltages of the transformer.

At very high voltages, the layer structure can be switched several times in series, wherein the electrically conductive layers are connected by a voltage source to a defined potential. For example, at a top voltage of 60 kV, the first conductive layer is set to the potential of the undervoltage of 400 volts, the second electrically conductive layer to 30 kV and the third conductive layer to 60 kV. Due to the electrically conductive layers with a defined potential, there is virtually no potential difference to adjacent winding. The voltage curve of the high-voltage winding is equal to the voltage curve of the electrically conductive layer belonging to the upper voltage, or is close to this voltage curve in an insulated embodiment. The same applies to the undervoltage.

The electrically conductive layers may, depending on the application, be electrically conductively connected to the upper or lower voltage winding and / or connected to an external voltage source. For this purpose, voltage dividers, transformers or the like can be used, which are directly or indirectly coupled to the upper or lower voltage winding. Such components may change the amount of voltage of the respective electrically conductive layer with respect to the upper or lower voltage winding or, for the same amount of voltage, ensure power decoupling for the high and low voltage windings.

Due to its construction, the insulation arrangement can be made very thin, in contrast to the usual air gaps. Furthermore, a partial discharge on the surface of the insulation is prevented by the semiconductive layer.

Depending on the application, the resistance of the semiconductive layer can be determined for all values which exist between the resistance of an electrical conductor, e.g. Copper, and that of an electrical nonconductor, z. As silicone, are designed. A favorable variant for the semiconducting layer is the spraying of a thin carbon layer with a defined resistance. This may for example be between 0.1 Ω and 1 MΩ, in particular 2 Ω to 10 kΩ, for example approximately 5 kΩ.

Another variant is that the voltage insulation is formed very stable with their layer structure, so that they can form a winding support for receiving the voltage winding itself, wherein the winding support of the upper voltage in the interior has an electrically conductive layer, this the same potential as the high-voltage winding has As a result of this, an internal insulation followed by a semiconductive layer and a further electrically conductive layer is realized, the potential of this electrically conductive layer being equal to the potential of the undervoltage, or by means of an insulation is located close together, and the layers are fixed together and without air pockets.

It is also possible to connect the voltage insulation in series with very high potential differences. In this case, the high-voltage winding is electrically connected to the first electrically conductive layer or insulated from the upper voltage, wherein in an insulated embodiment, the electrically conductive layer is set to a defined potential, which is close to the upper voltage, then the first inner insulation, then the first semiconducting layer, then another electrically conductive layer, which is placed on a defined potential, for example half of the total potential difference, then a third electrically conductive layer, then a second inner insulation, then a second semiconducting layer, then a fourth electrically conductive layer, which is electrically connected to the lower voltage winding, or insulation to the fourth electrically conductive layer. In isolation to the undervoltage, the fourth electrically conductive layer is set to a defined potential, which is close to the undervoltage.

In particular, the invention relates to the following further aspects:

An embodiment comprises a high-voltage transformer with a high-voltage insulation between a high-voltage winding and a low voltage winding for potential separation, having a firmly bonded layer structure, comprising or consisting of an electrically conductive layer, which is set to a defined potential which is equal to or at least close to the upper voltage followed by an internal insulation, followed by a semiconductive layer and another electrically conductive layer, which is set at a defined potential which is equal to or at least close to the undervoltage. The electrically conductive layer and / or the further electrically conductive layer may be electrically conductively connected to the high-voltage winding or the low-voltage winding. The electrically conductive layer and / or the further electrically conductive layer may be electrically insulated from the high-voltage winding or the low-voltage winding. The inner insulation can have a semiconducting layer on both sides. In a further refinement, the electrically conductive layer and / or the further electrically conductive layer has an insulation for the high-voltage winding or for the low-voltage winding.

In one embodiment, the layer structure forms a winding carrier for receiving the high-voltage winding.

A further embodiment of the invention comprises a high-voltage transformer having a high-voltage insulation between a high-voltage winding and a low-voltage winding for potential separation, which has a firmly bonded layer structure comprising or consisting of a first electrically conductive layer which is set to a defined potential which is equal to the upper voltage or at least close, followed by a first inner insulation followed by a first semiconductive layer and a second electrically conductive layer laid to a second defined potential followed by a second inner insulation followed by a second semiconducting layer and a third one electrically conductive layer, which is placed on a third defined potential, followed by a third inner insulation, followed by a third semiconductive layer and a fourth electrically conductive layer, which on a fourth defined Po tential, which is equal to or at least close to the undervoltage. In this case, the second electrically conductive layer can be applied to half the total potential difference between the high-voltage winding and the low-voltage winding.

The bobbin or winding support for receiving the high-voltage winding is rotatable in a variant around the transformer core, so that electrically conductive material and insulation material can be wound. The bobbin is driven externally. The electrically conductive layers are supplied in a further variant of an external voltage source, so that a current limit is possible. But this is not absolutely necessary.

The bobbin or winding support for receiving the high-voltage winding can be prefabricated and divided or can be made in one piece directly around the toroidal core.

The compact insulation can also be mounted as a cylinder between the high-voltage winding and low-voltage winding, wherein an air gap can be approximately in the form of an air gap between the high-voltage winding and between the low-voltage winding.

Side flanges of the bobbin in one embodiment may have a frictional or positive surface.

The invention will be explained in more detail below with reference to the figures represented in the drawing, which schematically illustrate embodiments of the invention. Show it:

1 is a schematic representation of an embodiment of a transformer with an insulation arrangement according to an embodiment of the invention,

2 shows a schematic illustration of an embodiment of a transformer with an insulation arrangement according to another embodiment of the invention,

3 is a schematic cross-sectional illustration of an exemplary winding process of the high-voltage winding of an embodiment of a transformer according to the invention on a winding carrier in the form of a toroidal core. Figure 1 shows a schematic representation of an embodiment of a transformer with an insulation arrangement according to an embodiment of the invention. The transformer is shown for the sake of clarity only roughly schematically. Between an upper voltage winding 4 and a lower voltage winding 8, an insulation arrangement is arranged. This can be designed differently according to the principles of the invention, a variant being shown in FIG. In particular, the layer structure according to the invention, which is firmly bonded, for example, is not limited to the layer sequence described below, but can be changed in itself and can also be extended in a modular manner depending on the application. The exemplary embodiments explained in the figures are each a high-voltage transformer in which the advantages of the invention become particularly apparent. However, the invention and its advantages are basically applicable to a variety of types of transformers, especially in the medium or low voltage range.

FIG. 1 shows a transformer 10 with an insulation arrangement between a high-voltage winding 4 and a low-voltage winding 8 for potential separation between the upper and lower voltage. The insulation arrangement has a layer structure which comprises an inner insulation 2 of the transformer. Furthermore, an insulating layer 3 is arranged between the high-voltage winding 4 and a first electrically conductive layer 1. Here, the first electrically conductive layer 1 is set to a defined potential A, which is equal to the potential of the high-voltage winding 4 or this comes close. Thus, there is no significant potential difference between the electrically conductive layer 1 and the high-voltage winding 4. The inner insulation 2 forms the actual insulation layer for electrical isolation and comprises or consists of, for example, silicone or other suitable non-conductive material. The inner insulation 2 is followed by a semiconducting layer 6, for example with or of a carbonaceous material. Thus, the partial discharge is suppressed on the surface of the inner insulation 2 to the outside. Another electrically conductive layer 5 is connected to the potential B, which is equal to the potential of the low-voltage winding 8 or, separated from this by an insulating layer 7, is close. Furthermore, the insulation layer 7 follows and then the undervoltage Winding 8. The layers 3, 1, 2, 6, 5 and 7 are firmly connected and form a unit.

The layer arrangement according to FIG. 1 can also be varied in such a way that the semiconducting layer 6 is arranged on the other side of the inner insulation 2, ie on the high-voltage side of the inner insulation 2, or on both sides on opposite sides of the inner insulation 2 a semiconducting layer is provided , It is also possible in certain applications to provide none or only one of the pairs of layers 3, 1 or 5, 7 or to supply only one of the electrically conductive layers 1, 5 with an external voltage source.

Figure 2 shows a schematic representation of another embodiment of a transformer with an insulation arrangement according to an extended embodiment of the invention. In particular, FIG. 2 shows a structure of a transformer 20 with two inner insulations 2a and 2b between the high-voltage winding 4 and the low-voltage winding 8 and an external voltage source SP. The transformer 20 comprises a first electrically conductive layer 1, which is placed on a first defined potential A and which is arranged between the high voltage winding 4 and the first inner insulation 2a, a second electrically conductive layer 5, which is placed on a second defined potential B. and disposed between the first inner insulation 2a and the second inner insulation 2b, and a third electrically conductive layer 11 laid to a third defined potential C and disposed between the lower-voltage winding 8 and the second inner insulation 2b. A first semiconductive layer 6a adjoins the first inner insulation 2a, and a second semiconducting layer 6b adjoins the second inner insulation 2b.

The multilayer structure becomes advantageous at high voltages because the voltage of, for example, 60 kV is divided in half within the isolation arrangement. For example, with the external voltage source SP, the potential A of 60 kV is applied to the first electrically conductive layer 1, the potential B of 30 kV to the second electrically conductive layer 5, and the potential C of 0.4 kV to the third electrically conductive layer 11 created. The semiconducting layers 6a and 6b serve for a defined potential reduction. The insulating layer 7 forms a Separation to the low-voltage winding 8 and the insulation layer 3 is a separation to the high-voltage winding 4 of the transformer 20th

The layer arrangement according to FIG. 2 can also be varied in that the semiconducting layers 6a, 6b are respectively arranged on the other side of the inner insulation 2a or 2b, ie on the high-voltage side of the inner insulation 2a or 2b, or on opposite sides on both sides the respective inner insulation 2a, 2b is provided a semiconducting layer. It is also possible in certain applications to provide none or only one of the pairs of layers 3, 1 or 11, 7 or to supply only one or selected of the electrically conductive layers 1, 5, 11 with an external voltage source. In certain cases, it is also possible to dispense with the electrically conductive layer 5.

Also, the arrangement of Figure 2 can be extended in a modular manner by further successive layers. This will be explained below, starting from FIG. 2, without a more detailed drawing. For example, the third electrically conductive layer 11 is followed by a third inner insulation, followed by a third semiconductive layer and a fourth electrically conductive layer, which is placed at a fourth defined potential which is equal to or at least close to the undervoltage. In this case, the potential C corresponds to a suitable intermediate potential between upper and lower voltage, e.g. about one-third of the total potential difference (in the above numerical example, for example, 20 kV), while potential B is then e.g. about two-thirds of the total potential difference between upper and lower voltage corresponds (in the above numerical example, for example, 40 kV). The variations described above with respect to FIGS. 1 and 2 may also find application in this embodiment.

FIG. 3 shows a schematic cross-sectional representation of an exemplary winding process of the high-voltage winding of an embodiment of a transformer according to the invention on a winding carrier in the form of a toroidal core 24. In particular, FIG. 3 shows an arrangement in which two winding carriers 21 are simultaneously wound with respective layer structures according to the invention. The high-voltage winding support 21 are around the Transformer core 24 rotatably and are driven in the arrow direction to wind the winding materials of electrically conductive material (here aluminum flat strip) 22 and insulation material 23 on the winding support 21. Several high-voltage segments are connected in series and form the high-voltage winding of the toroidal transformer.

The insulation layer structure according to the invention, which forms a winding carrier 21 (so-called bobbin) for receiving the high-voltage winding 4, can be prefabricated and divided or can be manufactured in one piece directly around the transformer core 24.

The layer structure may be mounted as a cylinder between the high-voltage winding 4 and the low-voltage winding 8, wherein at least one air gap (not shown) may be provided for cooling purposes between the upper-voltage winding and the lower-voltage winding. Such an air gap may in principle be arranged between any two layers of the layer structure, but will generally be arranged relatively close to the upper and / or lower voltage winding.

The winding support 21 may have side flanges (not shown) which have a frictional or positive surface. This has an advantageous effect during the winding process.

Claims

claims

1. Transformer (10) with an insulation arrangement between a high-voltage winding (4) and a low-voltage winding (8) for electrical isolation, which has a layer structure, comprising an inner insulation (2, 2a, 2b) between high-voltage winding (4) and low-voltage winding (8) to which at least one semiconductive layer (6, 6a, 6b) adjoins.

2. Transformer according to claim 1, wherein the inner insulation (2, 2a, 2b) on a first and second side adjacent to a respective semiconductive layer (6, 6a, 6b).

3. A transformer according to claim 1 or 2, further comprising a first electrically conductive layer (1), which is placed on a first defined potential (A) and between the high-voltage winding (4) and the inner insulation (2, 2a, 2b) is arranged.

4. Transformer according to claim 3, wherein the first electrically conductive layer (1) is placed on a first defined potential (A), which is equal to or at least close to the upper voltage of the high-voltage winding (4).

5. A transformer according to claim 3 or 4, wherein between the first electrically conductive layer (1) and the high-voltage winding (4), a first insulating layer (3) is arranged.

6. Transformer according to one of claims 1 to 5, further comprising a second electrically conductive layer (5) which is placed on a second defined potential (B) and which between the low-voltage winding (8) and the inner insulation (2, 2a) is arranged.

7. A transformer according to claim 6, wherein the second electrically conductive layer (5) is set to a second defined potential (B) which is equal to or at least close to the sub-voltage of the low-voltage winding (8).

8. A transformer according to claim 6 or 7, wherein between the second electrically conductive layer (5) and the lower voltage winding (8), a second insulating layer (7) is arranged.

9. Transformer according to one of claims 1 to 8, wherein the layer structure forms a winding support for receiving the high-voltage winding (4).

10. Transformer according to one of claims 1 to 9, comprising

a first inner insulation (2a) between the high-voltage winding (4) and the low-voltage winding (8), to which at least one first semiconductive layer (6a) adjoins,

a second inner insulation (2b) between the high-voltage winding (4) and the low-voltage winding (8), to which at least one second semiconducting one

Layer (6b) is adjacent.

The transformer of claim 10, further comprising

a first electrically conductive layer (1) which is laid on a first defined potential (A) and which is arranged between the high-voltage winding (4) and the first inner insulation (2a),

- a second electrically conductive layer (5), which is placed on a second defined potential (B) and which is arranged between the first inner insulation (2a) and the second inner insulation (2b), - a third electrically conductive layer (11 ) which is connected to a third defined potential (C) and which is arranged between the low-voltage winding (8) and the second inner insulation (2b).

The transformer of claim 11, wherein the first electrically conductive layer (1) is followed by the first inner insulation (2a), followed by the first semiconducting layer (6a) and the second electrically conductive layer (5), followed by the first second inner insulation (2b), followed by the second semiconductive layer (6b) and the third electrically conductive layer (11).

13. A transformer according to claim 11 or 12, wherein the second electrically conductive layer (5) is placed on approximately half of the total potential difference between the high-voltage winding (4) and low-voltage winding (8).

A transformer according to claim 12, wherein the third electrically conductive layer (11) is followed by a third inner insulation, followed by a third semiconductive layer and a fourth electrically conductive layer, which is placed at a fourth defined potential, that of the undervoltage equal or at least close.

15. Transformer according to one of claims 1 to 14, wherein the layer structure forms a winding support for receiving the high-voltage winding (4) which is rotatable about a transformer core (24), so that electrically conductive material (22) and insulation material (23 ) is aufspulbar.

16. Transformer according to one of claims 3 to 15, wherein at least one or more of the electrically conductive layers (1, 5, 11) are supplied by an external voltage source (SP).

17. Transformer according to one of claims 1 to 16, wherein the layer structure forms a winding support for receiving the high-voltage winding (4), which is prefabricated and divided or is made in one piece directly around a transformer core (24).

18. Transformer according to one of claims 1 to 17, wherein the layer structure is mounted as a cylinder between the high-voltage winding (4) and low-voltage winding (8), wherein at least one air gap between the high-voltage winding and the low-voltage winding is present.

19. Transformer according to one of claims 1 to 18, wherein the layer structure forms a winding support for receiving the high-voltage winding (4) having side flanges, which have a frictional or positive surface.

20. Transformer according to one of claims 1 to 19, which is designed as a high voltage transformer, wherein the insulation arrangement is designed as high voltage insulation.

21. An insulation arrangement for potential separation between a high-voltage winding (4) and a low-voltage winding (8) of a transformer having a layer structure, comprising an inner insulation (2, 2a, 2b) for arrangement between the high-voltage winding (4) and low-voltage winding (8) of the transformer to which at least one semiconductive layer (6, 6a, 6b) adjoins.