EP3574510B1 - Electric contact arrangement - Google Patents

Description

The invention relates to an electrical contact arrangement having a first phase conductor run and a second phase conductor run, which are connected to one another in an electrically conductive manner via a coupling point.

Such an electrical contact arrangement is for example from the international publication WO 2011/113479 A1 known. The contact arrangement there connects a first phase conductor run with a second phase conductor run via a coupling point in an electrically conductive manner. For this purpose, the coupling point has two pairs of sockets and bolts which are each slidably inserted into one another, the sockets in turn being in electrical contact with one another via current bands. In this way, thermally induced changes in length can be compensated. However, the known arrangement has the disadvantage that a large number of contacting points are provided, which increase contact resistances and thus increase the problem of thermal stress. In addition, due to the unfavorable arrangement of sockets, bolts and current bands, an electrical contact arrangement with limited current carrying capacity is created.

The pamphlet DE 15 40 147 A1 shows an electrical contact arrangement having a first phase conductor run and a second phase conductor run, which are connected to one another in an electrically conductive manner via a coupling point, the first phase conductor run having a plurality of subconductors.

The pamphlet JP S59 36909 A discloses an electrical contact arrangement for conductors connected to a winding.

The object of the invention is thus to provide an electrical contact arrangement which has an improved current-carrying capacity while reducing installation space.

According to the invention, this object is achieved in an electrical contact arrangement of the type mentioned at the outset in that the first phase conductor run has several subconductors and the second phase conductor run has several subconductors which are alternately connected to a contact plate.

An electrical contact arrangement is used to form an electrically conductive connection between a first phase conductor run and a second phase conductor run. Such contact arrangements can be used, for example, in transformer construction, for example to electrically connect electrical windings to outlets of a transformer or to lengthen lines. Transformers preferably have a transformer tank, in the interior of which an active part of the transformer is arranged. The active part comprises, for example, electrical windings which can be arranged on the high or low voltage side. To guide a magnetic flux, the active part can have a transformer core which, for example, is designed to be ferromagnetic in order to reduce scatter losses. The transformer tank, for its part, can be flooded with an electrically insulating fluid, preferably a liquid, so that the electrically insulating fluid flows around the active part of the transformer. The electrical contact arrangement can also be washed around by the electrically insulating fluid. The contact arrangement can advantageously be arranged completely in the electrically insulating fluid. For example, electrically insulating oils or electrically insulating esters have proven to be suitable as electrically insulating fluids.

The phase conductor runs can preferably be split into several subconductors at least in the area of the coupling point be. On the one hand, this has advantages in terms of assembly, since the sub-conductors are easier to handle. In particular in the case of power transformers in the high and extra-high voltage range, which on the one hand are subject to high dielectric stress and on the other hand are used to conduct a high electrical current, the mechanical workability of the phase conductors and their ease of laying can be improved. In addition, a division in the subconductor has the advantage that the subconductors can each carry a partial current of an electrical current to be transmitted across the phase conductor line, whereby improved heat dissipation is possible due to the enlarged surfaces on the subconductors. In particular when it is flushed with an electrically insulating fluid, the fluid can also flow between the subconductors and promote a dissipation of thermal energy from the subconductors. The number of sub-conductors can be determined as required. A division into an even number of sub-conductors, e.g. B. 4, 6, 8, 10 sub-conductors.

The phase conductor runs can be aligned essentially coaxially to one another, the subconductors being arranged striving towards one another. The sub-conductors can be deflected out of the alignment of the phase conductor tracks and thus increase the available assembly space (and flow space for the fluid) between the sub-conductors. By using a contact plate, the sub-conductors can be connected to the contact plate. The contact plate can, for example, be an essentially ring-shaped contact plate which is formed from electrically conductive material. A ring shape cools the contact plate and sub-conductors. The installation space for the contact arrangement can thus be reduced. The sub-conductors can be mutually electrically conductively connected to the contact plate, so that electrical contacting of the respective sub-conductors of the respective phase conductor train preferably essentially comes from one direction is carried out on the contact plate, preferably with a substantially opposite sense of direction. For example, the sub-conductors of the first phase conductor run can be arranged on a first side of the contact plate and the sub-conductors of the second phase conductor run can be arranged on a second side of the contact plate. The two sides of the contact plate, on which sub-conductors are respectively arranged, can be oriented in opposite directions on the contact plate. The contact plate can, for example, be an essentially flat plate, in the plate surfaces of which there can be respective receiving points for fastening the sub-conductors. The contact plate can, for example, have recesses, in particular through recesses, through which parts of the subconductors or of fitting bodies of the subconductors can protrude. The sub-conductors can preferably be screwed, riveted, soldered, pressed, etc. to the contact plate. The contact plate can, for example, also have a profiling, as a result of which dielectric shielding of the sub-elements, in particular their contacting points on the contact plate, can take place. For example, the contact plate can be a copper plate or a brass plate to which the sub-conductors are attached. The sub-conductors can be arranged on the contact plate, for example, distributed on a circular path. This supports a radial deflection of the sub-conductors from the alignment of the phase conductor runs and stabilizes the position of the sub-conductors. The subconductors of the first phase conductor run and the subconductors of the second phase conductor run can be arranged so as to be distributed on mutually different circular paths. For example, these two circular paths can be arranged concentrically to one another and have different diameters. However, it can also be provided that the sub-conductors of the first phase conductor run and the sub-conductors of the second phase conductor run are distributed on one and the same circular path. For example, in one direction of rotation of the circular path, the sub-conductors of the first phase conductor run can alternate with the sub-conductors of the second phase conductor run be positioned. The contact plate can optionally be designed to be elastically deformable, so that forces emanating from the subconductors, for example as a result of thermal stresses or current forces, can be absorbed in the contact plate and at least partially compensated for.

A further advantageous embodiment can provide that the contact plate is assigned to a mouth opening of a guide channel of the first and / or second phase conductor run.

A guide channel of the first phase conductor run or of the second phase conductor run can serve to guide, direct or direct the sub-elements. In addition, the guide channel can also be used to direct a fluid flow. This improves the cooling of the contact arrangement, in particular of a phase conductor run. The guide channel can encompass the sub-elements and prevent unintentional kinking or deflection of the sub-conductors. The guide channel can thus bring about mechanical stabilization for the sub-conductors. For example, mechanically unstable sub-conductors can be stabilized in their position. The guide channel can, for example, have an essentially cylindrical shape. In particular in the case of a circular cross-section of the guide channels of the first and the second phase conductor, the guide channels can be aligned essentially in alignment, in particular essentially coaxially to one another, wherein the mouth openings of the guide channels can be arranged opposite one another at the end. The guide channel can be designed as an electrode, so that in addition to mechanical guiding of the sub-conductors due to the shape of the guide channel, a dielectrically shielding or homogenizing effect can also emanate from the guide channel. For this purpose, the guide channel can advantageously be designed to be at least partially electrically conductive, the electrically conductive sections of the guide channel preferably having the same electrical potential as the subconductors guided by it. Advantageously can the guide channel can be metallic at least in sections. However, it can also be provided that a non-metallic guide channel is used, with, for example, surface sections of the guide channel being designed to be electrically conductive in order to bring about a dielectric homogenization of an electrical field around the sub-conductors. The guide channel can, for example, have a substantially hollow cylindrical structure, optionally with varying wall thickness or varying wall profile. In a preferred embodiment variant, the guide channel can have a metallic tube which, in particular, is provided with an electrically insulating coating on the outer jacket side. The wall thickness can advantageously be varied by varying the thickness of the electrically insulating coating. A metallic tube can have a substantially constant cross section. Cellulosic insulation materials have proven themselves as insulation materials. The guide channel can also have recesses in its course in order to enable access to the sub-conductors guided in the interior of the guide channel.

A guide channel has an opening to allow the subconductors to emerge from the interior of the guide channel and to enable electrical contacting of the subconductors of the first phase conductor run with the subconductors of the second phase conductor run. A mouth opening can be delimited, in particular surrounded, by a mouth opening flange. A mouth opening can, for example, be arranged at the end of a tubular guide channel. The mouth opening can, for example, preferably have a circular cross section, the cross section of the mouth opening preferably being designed to correspond to the cross section of the guide channel. The contact plate can be arranged in the vicinity of the mouth opening in order to lead partial conductors emerging from the mouth opening to the contact plate over the shortest possible path. Thereby a common Contact plate can be provided, which is assigned both to an opening of the mouth of a first guide channel of the first phase conductor run and to an opening of the mouth of the guide channel of the second phase conductor run.

A further advantageous embodiment can provide that the contact plate is supported on a guide channel of the first and / or second phase conductor run.

The contact plate can preferably be mechanically connected to a guide channel and supported on a guide channel. As a result, the mechanical stability of the guide channel, which also serves to guide or line corresponding sub-conductors, can be used to fix the contact plate relative to the guide channel. For example, it can be provided that the contact plate is supported at a rigid angle on one of the guide channels, with relative mobility being maintained with respect to the other guide channel of the remaining phase conductor train. This enables, on the one hand, a mechanically simple and stable positioning of the contact plate in a simple manner. On the other hand, the contact arrangement is designed to be movable in itself and thus able to react to thermal changes. Preferably, the support on one of the guide channels can also be used to transfer an electrical potential from the guide channel to the contact plate. This achieves dielectrically stable conditions which counteract the creation of undefined (floating) electrical potentials.

Advantageously, it can further be provided that the contact plate is arranged in front of an opening of the guide channel in particular via at least one spacer device.

A spacer device makes it possible to position the contact plate at a distance from the mouth opening. The distance device can, for example, connect an orifice flange delimiting an orifice opening to the contact plate. It can advantageously be provided that, in the case of a circular mouth opening and a circular ring-shaped contact plate, a coaxial alignment of the mouth opening and contact plate takes place via the spacer device. The spacer device can, for example, have one or more stud bolts which connect / connect an orifice flange directly or indirectly to the contact plate. The spacer device can also serve to effect a potential transfer of the electrical potential from the guide channel to the contact plate (and vice versa). The plane in which the mouth opening lies can be aligned essentially parallel to the plane in which a contact plate lies, the distance between the contact plate and the mouth opening being fixed by the spacer device.

A further advantageous embodiment can provide that the guide channel carries a screen hood that encompasses the contact plate.

The contact plate can be arranged in the shield shadow of a shield hood, wherein the shield hood can bring about a dielectric homogenization of the contact plate, in particular of the sub-conductors connected to the contact plate. The shield hood can preferably encompass the contact plate so that the contact plate is arranged completely in the shield shadow, for example in the interior of the shield hood. For this purpose, the shield hood can preferably be configured essentially as a hollow cylinder, the phase conductor tracks preferably protruding into the shield hood at the end faces of the hollow cylindrical shield hood and being aligned essentially coaxially with one another and with the shield hood. The screen hood, for its part, can preferably have electrically conductive surfaces, for example the screen hood can be in a simple one Design variant be formed from an electrically conductive material.

A further advantageous embodiment can provide that the contact plate is arranged essentially transversely to an axial extension of the shielding hood, the contact plate being positioned asymmetrically.

The contact plate can be oriented essentially transversely to the axial extent of the shield hood. Thus, in the axial course, in particular in the case of an essentially hollow-cylindrical configuration of the shield hood, there is a barrier in the interior of the shield hood which is arranged essentially transversely. The position of the barrier or the position of the contact plate within the shield hood can be aligned asymmetrically. This has the advantage that the shielding hood on the one hand effects a shielding of the asymmetrically arranged contact plate, an asymmetrically enlarged area being made possible for the arrangement or deflection of sub-conductors of a phase conductor run. This asymmetrical arrangement should preferably be designed such that when the contact plate is supported on one of the guide channels, the distance from the guide channel which carries the contact plate is less than the distance from the contact plate to the guide channel to which the contact plate is relatively movable. A construction space is thus created in order to be able to easily bend out or compensate the positions of the sub-conductors.

A further advantageous embodiment can provide that the screen hood is carried by at least one electrically insulating spacer.

An electrically insulating spacer enables the shield hood to be supported on one of the guide channels. The storage can be provided directly on one of the guide channels, but it can also be indirect Storage of the canopy can be made. For example, the electrically insulating spacer can enable the shield hood to be supported via the contact plate, which is connected to a guide channel at a fixed angle. However, the electrically insulating spacer should preferably be connected directly to at least one of the guide channels. For example, an orifice flange of an orifice can also serve to support or attach an electrically insulating spacer. The advantage of this construction is that a defined electrical contacting of the shield hood or the application of potential to the shield hood can take place, since undifferentiated stray currents via a spacer are prevented. At the same time, for example, an electrically conductive connection (e.g. equipotential bonding line) between the shielding hood and one of the phase conductors can be resolved for test and inspection purposes, so that the shielding hood and phase conductor or guide channels are electrically isolated from one another.

A further advantageous embodiment can provide that the contact plate and the shielding hood are connected to one another via a potential equalization line.

A potential equalization line enables the shielding hood positioned via at least one electrically insulating spacer to be subjected to the electrical potential of one, in particular both, phase conductor tracks that are coupled to one another. For example, the contact plate can have a first contact point for the equipotential bonding line and the shielding hood can have a second contact point for the equipotential bonding line. Correspondingly, direct contacting or application of potential to the shielding hood is made possible, starting from the contact plate. This contact can also be separated in a simple manner, so that an electrically isolated spacing of the There is a shielding hood to the phase conductors after disconnecting the equipotential bonding line.

A further advantageous embodiment can provide that at least one sub-conductor is connected to the contact plate via a wire end fitting.

Several, in particular all of the sub-conductors of the first and / or the second phase conductor run preferably have a similar cross-sectional configuration. The sub-conductors can protrude at the front in the direction of the contact plate. In order to connect the subconductors to the contact plate in a simplified form, the subconductors can have wire end fittings with which the subconductors are terminated in a mechanically stabilized manner. The wire end fittings can be designed, for example, in the form of cable lugs, which enable a suitable connection to the contact plate. For example, the wire end fittings can be designed to be pluggable, screwable, solderable, pressable, clampable, etc. in order to connect the subconductors to the wire end fittings in an electrically conductive manner. The wire end fittings in turn can have various shapes, for example a wire end fitting can have a threaded bolt in order to enable the wire end fitting to be screwed to the contact plate. The wire-end fitting can, for example, also be equipped in the form of a cable lug with an eyelet, a tab, with a pin for clamping or bolting, screwing, pressing, etc. A wire-end fitting can also advantageously make it more difficult to damage a free end of the sub-conductor and thus serve to cap a sub-conductor of a phase conductor run.

It can advantageously be provided that at least one sub-conductor is a flexible sub-conductor.

The use of a flexible sub-conductor makes it possible to further simplify the assembly of the electrical contact arrangement. In addition, a heat dissipation from a flexible sub-conductors are positively influenced. For example, the sub-conductors can be formed from a leafed bundle of conductors, whereby an additional enlargement of the heat-emitting surface of the sub-conductor is made possible. Furthermore, a flexible sub-conductor can also be, for example, a stranded sub-conductor, as a result of which the flexibility of the deformability of the sub-conductor is additionally supported and a further improved heat dissipation is provided. Particularly when using flexible subconductors, which are in particular multi-stranded or multi-stranded, the end of the flexible subconductor can be stabilized by means of a wire end fitting, so that simplified electrical contacting of a flexible subconductor with the contact plate is also made possible.

A further advantageous embodiment can provide that the guide channel has a reduced cross section in a section encompassed by the screen hood.

A guide channel can preferably be designed as a hollow cylinder, the cross section of the guide channel being variable. A guide channel can advantageously have a metallic tube as a support element, which is surrounded by an electrically insulating layer. At least in the area of the electrically insulating layer, the tube has an essentially constant cross section. The cross section of the guide channel can preferably be varied by changing the thickness of the electrically insulating layer. The electrically insulating layer preferably has cellulose fibers. For example, the guide channel can experience a cross-sectional reduction in the area of the screen hood, as a result of which a shoulder is formed in the course of the guide channel. The shoulder can preferably dielectrically close an opening in the shield hood, with a sufficient gap between the guide channel and the shield hood to allow a fluid into the interior of the shield hood and thus a contact plate due to the reduction in cross section to allow flowing fluid flow. A shoulder can be produced, for example, by reducing the thickness of an electrically insulating layer. The shoulder can form a termination of an electrically insulating layer. For example, the screen hood can have an essentially hollow-cylindrical shape, the guide channels each protruding into the interior of the screen hood at the end. For improved dielectric shielding, the shielding hood can have a flange at the end. In cooperation with the cross-sectional reduction of the guide channel made there and the shoulder formed in this way, adequate dielectric shielding in connection with the guide channel is also ensured at the end face in the area of a shield hood opening. Furthermore, sufficient flow of an electrically insulating fluid through the contact arrangement via the end faces of the shield hood is ensured.

A further object of the invention is to find a suitable use for a contact arrangement of the type described above.

The object is achieved in that, in a transformer arrangement with an electrical winding, the electrical winding is electrically contacted by a contact arrangement of the type described above.

A transformer arrangement has a transformer which has an active part. The active part has at least one electrical winding which is used to generate an electromagnetic field. As a rule, several electrical windings are coupled via electromagnetic fields in order to carry out a voltage conversion, ie essentially a change in the voltage level of an alternating voltage. In order to guide and direct the electromagnetic fields and thus avoid scatter losses, the use of a transformer core is provided, which has a magnetic flux guides and directs with little resistance. The electrical winding (windings) or the transformer core are part of an active part of the transformer. The active part is preferably arranged within a transformer tank which mechanically protects the active part. In addition, the transformer tank can be used to separate an electrically insulating fluid from the environment around the active part. The electrically insulating fluid can preferably completely flow through and enclose the active part. For example, insulating oils or insulating esters are suitable as electrically insulating fluids. As part of the active part, the contact arrangement can be used, for example, to integrate an electrical winding of the transformer into an electrical energy transmission network. For this purpose, for example, outdoor bushings can be provided on the transformer arrangement, via which electrical contact can be made with the winding with the interconnection of the contact arrangement. An outdoor bushing is used, for example, for a dielectrically stable, electrically insulated passage of a phase conductor line through a wall of a transformer tank. This wall of a transformer tank can, for example, be designed to be electrically conductive and carry ground potential. A contact arrangement can in particular serve to connect or integrate an outdoor bushing with an electrical winding of the transformer.

Figur 1:

einen Querschnitt durch eine elektrische Kontaktanordnung; die

Figur 2:

eine perspektivische Ansicht einer Kontaktplatte wie aus der Figur 1 bekannt.

In the following, an embodiment of the invention is shown schematically in a drawing and described in more detail below. The

Figure 1:

a cross section through an electrical contact arrangement; the

Figure 2:

a perspective view of a contact plate as from FIG Figure 1 known.

In the Figure 1 a first phase conductor line 1 and a second phase conductor line 2 of an electrical contact arrangement is shown in section. The first phase conductor run 1 and the second phase conductor run 2 extend essentially along a main axis 3. The first phase conductor run 1 and the second phase conductor run 2 are essentially aligned with the main axis 3 and thus aligned with one another, in particular substantially coaxially with one another. Both the first phase conductor run 1 and the second phase conductor run 2 each have a plurality of subconductors 1a, 1b, 1c, 2a, 2b, 2c. The sub-conductors 1a, 1b, 1c, 2a, 2b, 2c are each designed as flexible sub-conductors, which in the present case are each multi-stranded, in particular multi-stranded. This enables the subconductors to be stranded together and the subconductors to one another. The sub-conductors 1a, 1b, 1c, 2a, 2b, 2c are spliced at the mutually facing ends of the first phase conductor run 1 and of the second phase conductor run 2, so that there is a radial increase in the area of the electrical contact between the first phase conductor run 1 and the second phase conductor run 2.

The first phase conductor run 1 is surrounded by a first guide channel 4. The second phase conductor run 2 is surrounded by a second guide channel 5. The guide channels 4, 5 are essentially constructed in the same way. The guide channels 4, 5 each have a tube made of an electrically conductive material, for example copper or aluminum, and surround the first phase conductor 1 and the second phase conductor 2, in particular in the area in which a combination of the sub-conductors 1a, 1b, 1c or 2a, 2b, 2c is present. The guide channels 4, 5 act as electrodes for the first and second phase conductor tracks 1, 2. As such, the guide channels 4, 5 each have the same electrical potential as the phase conductor tracks 1, 2. On the respective tube (support tube) of the guide channels 4 , 5 a coating of electrically insulating material is applied. The guide channels 4, 5 each have at the ends facing one another an orifice 6, 7. The mouth openings 6, 7 are each provided with a circular cross section, the mouth openings being arranged coaxially opposite one another. The mouth openings 6, 7 are also aligned coaxially to the main axis 3. Channel axes of the first and second guide channels 4, 5 are also aligned coaxially to the main axis 3. The mouth openings 6, 7 face one another and are spaced from one another. To delimit the respective mouth openings 6, 7 of the first and second guide channels 4, 5, one mouth opening flange 8, 9 is arranged on the facing end faces of the first and second guide channels 4, 5, respectively. Via the respective mouth opening flange 8, 9, it is possible to support further assemblies on the first or second guide channel 4, 5. In the cross section it can be seen that at the ends of the guide channels 4, 5 facing one another, a cross-section reduction of the first and second guide channels 4, 5 has been made. The cross-sectional reduction is designed in such a way that the wall thickness of the guide channels 4, 5 is reduced on the mutually facing sides, specifically reduced in such a way that the cross-section 5 of the recess in the interior of the first or second guide channel 4, 5 is kept constant, so that a shoulder is formed in each case on the guide channels 4, 5 on the outer jacket side. To reduce the cross-section of the guide channels 4, 5, coatings made of electrically insulating material are reduced in their thickness.

The area of the cross-section reduction of the first or second guide channel 4, 5 protrudes into a screen hood 10. The screen hood 10 is designed essentially as a hollow cylinder, with inwardly projecting flanges being arranged on the front ends of the hollow cylinder. As a result, the front sides are rounded, as a result of which a curved ring structure is provided on the front side of the screen hood 10. This rounded contour interacts with the respective shoulder in the area of the cross-sectional reduction of the first or the second guide channel 4, 5 is used to shield the frontal openings of the screen hood 10, into which the first and the second guide channel 4, 5 protrude. In order to achieve mechanical stabilization of the end faces of the screen hood 10, an engagement formed by the flanging is filled with a filling compound 11. This filling compound 11 can be, for example, an electrically insulating resin which is let into the interior of the flange in fluid form and hardens there.

A plurality of ribs in the form of rings are arranged in the interior of the screen hood 10. A positioning of the screen hood 10 relative to the guide channels 4, 5 is made possible via the ribs. For example, at least one electrically insulating spacer can be arranged on a rib in order to ensure a coaxial alignment of the screen hood 10, in particular with the guide channels 4, 5. This spacer can be, for example, an elastic plastic element which is fastened to a rib, for example, and in turn rests, for example, on an orifice flange 8, 9, snapped onto it or fastened in some other way. In particular, the electrically insulating spacer can also be used to axially displace the screen hood 10, which enables access to the area between the mouth openings 6, 7 between the first and second guide channels 4, 5.

To make electrical contact between the first phase conductor 1 and the second phase conductor 2, a contact plate 12 is arranged in the interior of the shielding hood 10. The contact plate 12 is designed here, for example, as an annular disk which is arranged coaxially to the main axis 3. The contact plate 12 is oriented essentially transversely to the main axis 3. Furthermore, the position of the contact plate 12 between the mouth openings 6, 7 of the first and second guide channels 4, 5 is selected asymmetrically, so that the distance between the contact plate 12 and the mouth opening 6 of the first guide channel 4 is less than the distance between the contact plate 12 and the mouth 7 of the second guide channel 5. If the electrical contact arrangement is used in an outlet on a fluid-insulated transformer, the outlet extending between a bushing and a winding of the transformer, the first phase conductor would be 1 turned towards the implementation. The second phase conductor run 2 would be assigned to the winding of the transformer. In the case of an essentially vertical arrangement, that is to say also in the case of an inclined arrangement of the electrical contact arrangement, heated fluid would be able to flow away in a simplified manner in the interior of the shielding hood 10 above the contact plate 12. However, it is also possible to swap the assignment of the bushing side and winding side on the contact arrangement.

The contact plate 12 is connected at a fixed angle to the mouth opening flange 8 of the first guide channel 4 via a spacer device 13. The spacer device 13 has an annular adapter plate 13 a, which is flanged to the mouth opening flange 8 of the first guide channel 4. A plurality of stud bolts 13b, which are distributed on a circular path, are placed on the adapter plate 13a. Preferably, four stud bolts 13b, in particular distributed in a square, can be arranged distributed on a circular path of the adapter plate 13a. The stud bolts 13b extend essentially parallel to the main axis 3 and form a cage between the adapter plate 13a and the annular contact plate 12 arranged at the other end of the stud bolts 13b carried. The contact plate 12 is held at a distance from the mouth opening 6 of the first guide channel 4. The mouth opening 6 of the first guide channel 4 and the contact plate 12 are aligned coaxially with one another. The first phase conductor line 1 or the sub-conductors 1a, 1b, 1c of the phase conductor line 1 penetrate the central opening of the annular adapter plate 13a and protrude in the direction of the Contact plate 12. The stud bolts 13b are distributed in a cage-like manner outside the circular path on which the subconductors 1a, 1b, 1c of the first phase conductor train 1 are distributed. Two circular paths are provided on the ring-shaped contact plate 12, a first circular path with a smaller diameter being provided in order to define receiving points for the sub-conductors 1 a, 1 b, 1 c of the first phase conductor train 1. A second circular path with a larger diameter is provided on the contact plate 12 in order to define positions for the sub-conductors 2a, 2b, 2c of the second phase conductor train 2 on the contact plate 12. The contact plate 12 has through-bores on the respective circular paths into which threaded bolts protrude (see also FIG Figure 2 ). The threaded bolts are each connected to wire end fittings 14 which terminate the subconductors 1a, 1b, 1c, 2a, 2b, 2c of the first and second phase conductor train 1, 2 at the end. For this purpose, the wire end fittings 14 are pulled over the front ends of the subconductors 1a, 1b, 1c in the manner of a cap and connected to the subconductors in an electrically conductive manner by means of suitable methods. For example, the subconductors 1a, 1b, 1c, 2a, 2b, 2c of the phase conductor tracks 1, 2 can be connected to the wire end fittings 14 in a materially bonded manner, for example by a soldering process. The wire end fittings 14 each have wrench surfaces in order to fix them to the contact plate 12 and to clamp the threaded bolts with a corresponding nut on the front side. The threaded bolts are attached to the end face of the capping wire end fittings 14, so that the wire end fittings 14 can be aligned essentially parallel to one another and to the main axis 3.

In order to apply a defined potential to the screen hood 10, a potential equalization line 15 is provided. The equipotential bonding line 15 is electrically conductively connected to the contact plate 12 on the one hand and to the shielding hood 10 on the other hand by means of releasable connections. For contacting the shielding hood 10 via the equipotential bonding line 15 are particularly suitable the annular ribs inside, ie within the screen area of the screen hood 10. The potential equalization line 15 enables the electrical contacting of the screen hood 10 to be released, whereby the screen hood 10 can be removed for assembly purposes. Depending on the shape, it can be provided that the shielding hood 10 is removed by axially displacing the equipotential bonding line 15 with a correspondingly long configuration. However, it can also be provided that the screen hood 10 is divided in the form of a shell.

In the Figure 1 a barrier 16 is also shown, which has an essentially hollow-cylindrical configuration. The barrier 16 is formed from an electrically insulating material, for example pressboard. The barrier 16 is used for electrical insulation of the electrical contact arrangement surrounded by the barrier 16. The barrier 16 for its part is exposed to an electrically insulating fluid and also serves to conduct or influence the flow of an electrically insulating fluid which flows around and through the electrical contact arrangement.

In the Figure 2 the spacer device 13 is shown together with the contact plate 12 attached to it. The enlargement is intended to describe the manner in which the stud bolts 13b and adapter plate 13a are fastened. The stud bolts 13b are fixed to the adapter plate 13a by means of screw connections. The screw connections are arranged in through bores of the adapter plate 13a, with screw heads being countersunk in order to screw the adapter plate 13a with its side facing away from the contact plate 12 flush with the mouth opening flange 8 of the first guide channel 4. The outer diameter of adapter plate 13a and contact plate 12 have approximately the same dimension. However, the ring width of the contact plate 12 is greater than the ring width of the adapter plate 13a. The subconductors protrude through the ring opening surrounded by the adapter plate 13a 1a, 1b, 1c of the first phase conductor run 1 in the direction of the contact plate 12. There, the wire end fittings 14 of the subconductors 1a, 1b, 1c of the first phase conductor run 1 are distributed on a circular path. The circular path on which the subconductors 1a, 1b, 1c of the first phase conductor run 1 are distributed, has a smaller diameter than the circular path on which the wire end fittings 14 of the subconductors 2a, 2b, 2c of the second phase conductor run 2 are distributed. The subconductors 1a, 1b, 1c, 2a, 2b, 2c of the first and second phase conductor line 1, 2 are each arranged exclusively on one side of the contact plate 12 and aligned in the same direction so that the threaded bolts of the wire end fittings 14 protrude through the contact plate 12 in opposite directions and can be braced against the contact plate 12 in opposite directions. The position of the contact points of the wire end fittings 14 of the subconductors 1a, 1b, 1c, 2a, 2b, 2c is selected such that subconductors 1a, 2a, 1b, 2b, 1c, 2c of the first and second phase conductor tracks 1, 2, respectively, assigned to one another lie on a radius.

Claims (12)

1. Electrical contact arrangement having a first phase conductor run (1) and a second phase conductor run (2) which are electrically conductively connected to one another via a coupling point, wherein the first phase conductor run (1) has a plurality of conductor elements (1a, 1b, 1c),
   characterized in that
   the second phase conductor run (2) has a plurality of conductor elements (2a, 2b, 2c), wherein the conductor elements (1a, 1b, 1c) of the first phase conductor run (1) and the conductor elements (2a, 2b, 2c) of the second phase conductor run (2) are alternately connected to a contact plate (12).
2. Electrical contact arrangement according to Claim 1,
   characterized in that
   the contact plate (12) is associated with a mouth opening (6, 7) of a guide channel (4, 5) of the first or/and second phase conductor run (1, 2).
3. Electrical contact arrangement according to Claim 1 or 2,
   characterized in that
   the contact plate (12) is supported on a guide channel (4, 5) of the first or/and second phase conductor run (1, 2).
4. Electrical contact arrangement according to Claim 2 or 3,
   characterized in that
   the contact plate (12) is arranged in front of a mouth opening (6, 7) of the guide channel (4, 5) in particular by means of at least one spacing device (13).
5. Electrical contact arrangement according to one of Claims 2 to 4,
   characterized in that
   a shielding hood (10) which encompasses the contact plate (12) is carried by the guide channel (4, 5).
6. Electrical contact arrangement according to Claim 5,
   characterized in that
   the contact plate (12) is arranged substantially transversely to an axial extent of the shielding hood (10), wherein the contact plate (12) is positioned in an asymmetrical manner.
7. Electrical contact arrangement according to Claim 5 or 6,
   characterized in that
   the shielding hood (10) is carried by at least one electrically insulating spacer.
8. Electrical contact arrangement according to one of Claims 5 to 7,
   characterized in that
   the contact plate (12) and the shielding hood (10) are connected to one another by means of a potential equalization line (15).
9. Electrical contact arrangement according to Claims 1 to 8,
   characterized in that
   at least one conductor element (1a, 1b, 1c, 2a, 2b, 2c) is connected to the contact plate (12) by means of a core end fitting (14).
10. Electrical contact arrangement according to one of Claims 1 to 9,
    characterized in that
    at least one conductor element (1a, 1b, 1c, 2a, 2b, 2c) is a flexible conductor element (1a, 1b, 1c, 2a, 2b, 2c).
11. Electrical contact arrangement according to one of Claims 2 to 9,
    characterized in that
    the guide channel (4, 5) has a reduced cross section in a section which is enclosed by the shielding hood (10).
12. Transformer arrangement comprising an electrical winding,
    characterized in that
    the electrical winding is electrically contacted by a contact arrangement according to one of Patent Claims 1 to 11.

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