EP2661756A1

EP2661756A1 - Transformer winding with cooling channel

Info

Publication number: EP2661756A1
Application number: EP11790876.4A
Authority: EP
Inventors: Benjamin Weber; Bhavesh Patel; Burak Esenlik; Frank Cornelius; Marcos Bockholt; Jens Tepper
Original assignee: ABB Technology AG
Current assignee: ABB Schweiz AG
Priority date: 2011-01-04
Filing date: 2011-11-29
Publication date: 2013-11-13
Also published as: US9208939B2; US20130293329A1; EP2472533A1; CN103270560B; WO2012092941A1; CN103270560A

Abstract

The invention relates to a transformer winding (10, 40) with at least two hollow-cylindrical winding modules (12, 14, 42, 44), which are nested one inside the other and extend about a common winding axis (16), wherein said winding modules are spaced apart from one another radially (32, 62) within at least one hollow-cylindrical cooling channel (18, 46) arranged between said winding modules by means of strips of insulation (20, 22, 24, 26, 28, 30, 32, 48). The strips of insulation (20, 22, 24, 26, 28, 30, 32, 48) have a cross-sectional form which predominantly avoids a surface profile (50, 52, 54) radially (32, 62) with respect to the winding axis (16).

Description

Transformer winding with cooling channel

description

The invention relates to a transformer winding with at least two hollow cylindrical nested around a common winding axis extending winding modules, which are radially spaced from each other within at least one interposed hollow cylindrical cooling channel by means of insulating strips.

It is well known that power transformers, for example, with a rated power of a few MVA and in a voltage range of, for example, 5kV to 30kV or 110kV, sometimes even up to 170kV, are also designed as dry-type transformers, wherein in the latter voltage range well rated power of 50MVA and are possible about it. During operation of a transformer, a loss of heat arises in its electrical windings, which is dissipated to the environment. Therefore, for cooling purposes of such a dry transformer usually at least one guided along the axial extent of the winding cooling channel is pronounced to lead out the heat loss preferably by means of natural air cooling from the winding interior. In order to increase the cooling effect, in particular the usually radially inwardly located lower voltage winding is divided into a plurality of radially spaced and electrically connected in series hollow cylindrical winding segments, between which a likewise hollow cylindrical cooling channel is arranged. But also between low and high voltage winding a cooling channel is usually provided. A radial spacing of adjacent winding modules, through which ultimately a cooling channel is formed, takes place here via electrically insulating rectangular profiles or also via so-called "dog-bone" strips.

The disadvantage here, however, is that the cooling channel - depending on electrical boundary conditions - must be made partially wider than necessary from the cooling cross section

CONFIRMATION COPY would be digs, because, if necessary, still a minimum electrical insulation effect between adjacent winding modules is required, which is achieved by correspondingly thicker insulation strips. As a result, the transformer winding is unnecessarily large and the power density of a transformer is reduced accordingly.

Based on this prior art, it is an object of the invention to provide a transformer winding with a cooling channel, which has an improved insulation capability.

This object is achieved by a transformer winding of the aforementioned type. This is characterized in that the insulating strips have a cross-sectional shape which avoids a surface profile radially to the winding axis predominantly.

The insulating ability of an insulator is determined on the one hand by its material and on the other hand by its outer surface. Longitudinal surface discharges can occur along these lines, insofar as the voltage stress is correspondingly high, for example a few 100 V / cm and higher. Surface discharges are favored when the electric field lines are tangent to the surface of an insulator, so that the stress stress along the surface is highest. Within a hollow-cylindrical cooling channel, the field lines or also equipotential lines-depending on the concrete structure of the transformer-extend approximately concentrically about a central axis of the cooling channel, which also corresponds to the winding axis of the winding. Therefore, when using the usual rectangular profiles or the double-T similar "Dog-Bone" profile strips as insulation strips within a cooling channel, the stress load along their outer surfaces maximum, because they extend to a very high proportion radially to the winding axis background for such an arrangement The cross-sectional shape of the insulating strips according to the prior art therefore depends on a mechanical form which is as simple as possible, and the basic idea of the invention is now to provide a corresponding insulation capability for the insulating strips Design of the cross-section or outer surfaces to be designed so that the voltage stress is reduced, wherein On the other hand, however, a correspondingly high mechanical stability is ensured.

According to a preferred embodiment of the invention, the insulating strips are made of a fiber-reinforced epoxy or polyester resin. On the one hand, this has a high insulating ability. On the other hand, it is possible by the fiber reinforcement to realize a high variety of variants of cross-sectional shapes, which are still characterized by a high mechanical stability. The shape of such an insulating strip could be produced, for example, by milling or by pultrusion methods. Another prerequisite for use in a transformer winding, namely a temperature resistance up to 150 ° C and beyond, as may well be required in dry-type transformers, is also given in an advantageous manner.

Of course, it is also possible to use other insulation materials, such as unreinforced thermoplastic materials such as polyamides. Of course, only the polyamides are suitable, which also have a correspondingly high stability at least 130 ° C. The particular advantage of polyamides lies in their particularly simple formability.

According to the invention, it is provided according to a further variant that the at least one cooling channel has a radially inner and a radially outer wall, which are then spaced by the insulating strips. The walls can also be segmented. Thus, a simplified assembly of then shell-like cooling channels is made possible in an advantageous manner, which also allows protection of the adjacent winding surfaces.

According to a further variant of the invention, the insulating strips have a diamond-like or a round cross-section. These are standard geometric shapes which are easy to manufacture and yet which are suitable for improved insulation. From weight and material savings, it may prove advantageous if the insulation strips are designed with an inner cavity. According to further embodiments of the insulating strips, these have an S, X, V, or Y-shaped cross-section. Here radially extending outer surface portions are advantageously largely avoided, so that an improved insulating ability is achieved. In addition, in particular the X, V and Y variants prove to be particularly stable due to their carrier-like structure. Especially with regard to a Torsionsbeanspruchung between the adjacent and spaced winding modules is here to highlight the X and V shape with their slanted support areas as particularly preferred.

But also insulation strips, which have a cross-section with sawtooth-like outer edges, are suitable according to the invention to achieve an improved insulating ability. This can mean both an additionally corrugated surface shape of an insulation strip according to the invention and, for example, a rib-like surface or outer surface shape of an insulation strip with a conventional rectangular cross section.

According to a preferred variant of the invention, the insulating strips have a flattened shape at their radially inner and / or radially outer end, which is ideally designed such that an insulating strip arranged in a cooling channel adjoins the flattened regions as flatly as possible to the regions to be supported. This can be either a winding module itself or a separate wall of a cooling channel. In a particularly preferred variant, the flattened shape is cylinder-spherical, that is adapted to the cylindrical shape of the adjacent winding modules. As a result, electrical discharges are avoided at the contact areas in an advantageous manner. Depending on the embodiment of the transformer winding, the term "cylindrical shape" or else "hollow cylindrical" is not to be understood as strictly geometrical with a round base surface, but rather is to be understood as meaning a basic shape approximating a rectangle with round edge regions. Namely, this allows a particularly high utilization of a volume available in a transformer core by transformer windings.

According to a further embodiment of the invention, the winding modules are galvanically connected to each other. This is a cooling channel with inventive according to spacing between both galvanically isolated upper and lower voltage windings and between winding modules or winding segments of a divided transformer winding possible. This is particularly useful in dry transformers greater power, where in operation correspondingly much waste heat to dissipate from the interior, which is simplified by several cooling channels accordingly.

The advantages of a transformer winding according to the invention also become apparent for a transformer comprising at least one transformer core and a transformer winding according to the invention. This is namely smaller than a conventional transformer winding and thus advantageously allows a smaller construction volume of a transformer according to the invention.

Further advantageous embodiment possibilities can be found in the further dependent claims.

Reference to the embodiments illustrated in the drawings, the invention, further embodiments and other advantages will be described in detail.

Show it:

1 shows a section through an exemplary first transformer winding and

Fig. 2 is a section through exemplary second transformer winding.

1 shows a section through an exemplary first transformer winding 10. A first hollow-cylindrical winding module 12 and a second hollow-cylindrical winding module 14 are arranged concentrically around a winding axis, wherein a likewise hollow-cylindrical cooling channel 18 is formed between them. The two winding modules 12, 14 may, for example, comprise a strip conductor, wherein a winding layer is just as wide as the strip conductor. This is particularly useful in a low-voltage winding, since there is a high conductor cross section is required because of the high current flow in relation to the high-voltage winding during operation of the winding. But it is also common, especially in nungsseitigen windings, that a conductor layer having a plurality of individual turns, which also sets a more complex potential distribution along the cooling channel during operation of the transformer winding. The diameter of such a transformer winding is for example 0.5m to 2.5m, depending on the voltage level and rated power.

In the cooling channel 18, a plurality of insulating strips 20, 22, 24, 26, 28, 30, 32 are shown by way of example with their cross-sectional shapes, by which the two winding modules 12, 14 are spaced apart in the radial direction 34. The diamond-like insulating strip 20 is just like the round insulating strip 24 provided with an inner cavity 36 and 38, which serves in particular the weight savings. The insulating strips 20, 22, 24, 26, 28, 30, 32 have a cross-sectional shape with a surface course radially 34 to the winding axis 16, which a surface over the radial axis largely avoids the winding axis. As a result, the insulation resistance of the cooling channel 18 is increased in an advantageous manner. Of course, preferably only a single type of insulating strips 20, 22, 24, 26, 28, 30, 32 are provided in a real cooling channel, for example 4 pieces at a respective angle of 90 °. An insulating strip 20, 22, 24, 26, 28, 30, 32 need not necessarily extend over the entire axial length of a transformer winding, for example 1, 5m to 3.5m, it may well be shared several times.

FIG. 2 shows a section through an exemplary second transformer winding 40 in a detailed view. A first winding module 42 and a second winding module 44 are spaced by an insulating strip 48, which has approximately the shape of a double-Y. Radially inwardly and radially outwardly provided contact areas 56, 58 to the adjacent winding modules 42, 44 are flattened, wherein they are also adapted to the cylindrical shape of the winding modules. In this way, the risk of electrical discharges in the area of the contact surfaces is largely reduced. The insulating strip 48 has a first inclined surface area 50, a second radially extending surface area 52 and a third inclined surface area 54. An increase in the dielectric strength over a rectangular profile is in the reached obliquely extending areas 50, 54. This can also be illustrated by the extended creepage path 60 along the surface.

LIST OF REFERENCE NUMBERS

Section through an exemplary first transformer winding first winding module

second winding module

winding axis

first cooling channel

first insulation strip

second insulation strip

third insulation strip

fourth insulation strip

fifth insulation strip

sixth insulation strip

seventh insulating strip

first radial vector

Inner cavity of first insulation strip

Inner cavity of third insulation strip

Section through exemplary second transformer winding first winding module

second winding module

second cooling channel

seventh insulating strip

first inclined surface area

second radially extending surface area

third oblique surface area

flattened shape at radially inner end of the insulating strip flattened shape at the radially outer end of the insulating strip

Creepage along the surface

second radial vector

Claims

claims

1. Transformatorwickiung (10, 40) with at least two hohizyiincirisch nested around a common winding axis (16) extending winding modules (12, 14, 42, 44), said within at least one interposed hollow cylindrical cooling channel (18, 46) by means of insulating strips ( 20, 22, 24, 26, 28, 30, 32, 48) are spaced apart radially (32, 62), wherein the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) have a cross-sectional shape, which predominantly avoids a surface profile (50, 52, 54) radially (32, 62) to the winding axis (16), characterized in that

the insulation strips (20, 22, 24, 26, 28, 30, 32, 48) are made of a fiber-reinforced epoxy or polyester resin or of an unreinforced thermoplastic material.

Second transformer winding according to claim 1, characterized in that the at least one cooling channel (18, 46) has a radially inner and a radially outer wall.

3. Transformer winding according to one of claims 1 or 2, characterized in that the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) have a diamond-like (20) or a round (24, 26) cross-section.

4. Transformer winding according to claim 3, characterized in that the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) with an inner cavity (36, 38) are executed.

5. Transformer winding according to one of claims 1 or 2, characterized in that the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) has an S (22) -, X (30) -, V (28 ), or Y (34) - shaped cross section.

6. Transformer winding according to one of claims 1 or 2, characterized in that the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) have a cross section with sawtooth-like outer edges.

7. Transformer winding according to one of the preceding claims, characterized in that the insulating strips (20, 22, 24, 26, 28, 30, 32, 48) at its radially inner (56) and / or radially outer (58) end a flattened Have shape.

8. Transformer winding according to one of the preceding claims, characterized in that the winding modules (12, 14, 42, 44) are galvanically connected to each other.

9. Transformer, comprising at least one transformer core and a transformer winding (10, 40) according to one of claims 1 to 7.