DE1513956B2 - ARRANGEMENT FOR THE FORMATION OF ELECTRIC AEQUIPOTENTIAL AREAS IN ELECTRIC DEVICES - Google Patents

Description

In electrical apparatus, especially those for high voltage, electrical fields are used to control or electrically conductive screens are often used to control the surge voltage distribution. The most popular An example of a field control is the condenser implementation in the form of a Lead-through bolt wound on a hard paper body, which has a mostly earthed mounting flange and in which the field distribution is controlled by the so-called capacitor inserts.

Such electrically conductive screens are also used in oil-filled high-voltage transformers and measuring transducers and reactors arranged. An example of an electrically conductive screen in the main scattering channel of a high-voltage transformer, for example to improve the surge voltage distribution of a Layer winding, the network connection of which takes place in a layer lying in the main scattering channel, is shown in FIG. 1 shown in a detail (German patent 1 203 382). The winding layer is denoted there by 1, which is connected to the outlet 7. With 2 is the conductive coating of the electrically conductive screen designated, 3 and 4 represent two shield rings, which by means of the connecting lines 9 and 10 also are connected to the outlet 7. With 5 and 6 the insulation of the shield rings 3 and 4 is designated. The guide coating 2 is connected to the diversion line 7 by means of the diversion line 8. The layer insulation following the winding layer 1 is denoted by 11. 12 is then part of the stray channel insulation lying on the other side of the conductive coating 2. At its ends is that Guide lining 2 formed into angled and folded flanges 13.

The production of the electrically conductive screen has so far been carried out in such a way that the conductive coating 2 follows wound onto the main litter channel insulation 12 in the form of an initially purely cylindrical layer of conductive paper and this is followed by the insulating layer 11, to which the winding layer 1 is again applied will. After completion of the winding, the initially purely cylindrical winding body is removed from the winding bench taken. Starting from the innermost insulating layer, in this case the layer 11, the protruding Ends of the wound insulating cylinder in the well-known "tear technique" by tearing in narrow strips formed into flanges that are approximately at right angles to the winding axis. The elaborate one Tearing of the insulating cylinder can be avoided by using crepe paper (German patent specification 1 066 662, German patent specification 1 189 197), but the low conductivity of one makes it conductive made crepe paper, the use of such a paper in the present case is not straightforward. Flanges 13 protruding at right angles are also attached to the cylindrical part of the guide lining 2 in this way integrally formed, which are tipped over inwards again to avoid sharp edges. To this The sharp edges are made wise by the two having the same electrical potential Shield rings 3 and 4 completely relieved of electrical load.

As far as necessary, for example when the electrically conductive shield for surge voltage control is a To serve winding, the above-mentioned guide paper screen can be replaced by a more or less dense one Framework of mutually correspondingly connected metal strips, mostly copper strips, in terms of conductivity be sufficiently amplified even for high surge currents. The former is useful Leitpapierschirm then executed in two layers and the metal strips between the two Leitpapierlagcn

arranged. In this way, a triple guide layer is then formed.

Although such a shield is extremely beneficial in terms of improving the surge voltage distribution, with the specified type of manufacture there is a risk that the insulation will break through Conductive particles, which can form when the conductive paper tears, is weakened, causing it to become premature Discharges during testing or premature destruction of the insulation due to partial discharges can come in operation.

Furthermore, it is to be feared in the production of the electrically conductive shield described above that in the axial compression of the winding, which with very large forces in the order of magnitude of 10 to 100 t and even higher pressures takes place, the conductive lining in the cylindrical part is very strongly deformed and, under certain circumstances, in the worst case it also tears. In such cases must come back with premature partial discharges and premature Destruction of the transformer's insulation can be expected.

The task is to create a conductive coating that, while avoiding the disadvantages mentioned above, a Unproblematic production of end flanges protruding at right angles allows and the very strong ones axial deformations - e.g. B. as a result of the winding compression - can follow without damage.

The invention relates to an arrangement for the formation of electrical equipotential surfaces in electrical devices, in particular oil-filled high-voltage transformers, transducers and reactors, in which another layer with between two layers of non-metallic, weakly conductive material metallic conductors are introduced and where there are cylindrical shielding surfaces facing outwards or inwards Continuing electrically shielding flanges are connected (proposed in German patent 1 203 382). In such an arrangement, the object set is achieved according to the invention in that that the layers of the weakly conductive material consist of creped paper, which made conductive and that the middle layer is formed by a strip web as a strip web intermediate layer, in the case of the metallic cross belts alternating with insulating cross belts in continuous succession on longitudinal belts are attached, the formation of the screen flanges by stretching the creped guide paper and continuation of the individual metallic strip web transverse strips into the flanges takes place.

Known arrangements made of metallic foil strips are only for the formation of cylindrical Shields are suitable because their edges cannot be formed into flanges (German patents 1056 259, 1049 971, 1057 218).

In Fig. 2 is the section perpendicular to the axis through an electrically conductive triple conductive coating according to FIG of the invention shown. With 14 and 15 the two outer ones are made of conductive crepe paper Layers denoted by 16 and 18 are selected from the evenly repeating sequence, two metallic transverse strips are shown, which in this example with the two insulating material transverse strips 17 are overlapped in scales so that they initially have no metallic contact with one another. 19th is a longitudinal carrier tape to which the transverse tapes are attached. The aforementioned scale-like arrangement of the metallic and insulating transverse strips is, as explained below, with triple guide linings particularly advantageous for purposes of surge voltage control.

According to a further concept of the invention, the longitudinal carrier strips, at least in the area of Ends of the transverse tapes, designed as self-adhesive insulating tapes with tack glue, which, if necessary, can be withdrawn from the conductive lining strip path again without difficulty.

The above-described structure of the triple guide lining now allows production of the in one Angle of about 90 ° to the winding axis protruding end flanges without the formation of conductive ones Particles would be to be feared, which practically hardly arise when conductive coatings are torn or cut let avoid.

After the layer insulation 11 between winding layer 1 and conductive layer 2 in the known tear technology has been formed into flanges at the winding ends, the first outer layer is made of conductive Crepe paper simply cranked roughly at right angles without any damage, with the expansion is made possible at the outer edge by stretching the crepe paper. The »interconnecting layer« with the conductive metal transverse strips is attached by peeling off the with a tack glue Longitudinal straps dissolved in their edge part in individual strips, which can now be without any difficulty to be spatially deformed. Then the second layer of crepe paper is cranked over.

The technique described above not only results in a spatial deformation of the edge parts of the originally cylindrical triple guide lining made possible, but the triple guide lining formed in this way can because of the elasticity of the crepe paper layers and the easy deformability of the thin strips of the central conductive lining path without any damage and also very strong axial deformations that result from the winding compression could follow.

For the purpose of surge voltage control of windings, it may be necessary that the metallic transverse strips of the conductive lining strip strip are connected to one another to guide the surge currents and to be connected to an impact point, usually the winding connection on the mains side. This interconnection of the metallic transverse belts is expediently carried out in that one of the longitudinal support belts is also designed as a metallic belt, which is then metallically connected to the metallic transverse belts by soldering or in some other way. In spite of this metallic through-connection of all metallic transverse strips, in many cases the insulation of the transverse strips by means of the flaky transverse strips of insulating material is retained in order to prevent inadmissibly high eddy currents and the associated power losses or heating of the electrical insulation in the conductive layers, which are usually interspersed with strong electromagnetic alternating fields avoid. On the other hand, especially when it comes to the surge voltage control of windings, the metallic transverse strips are made so wide and so close together that the projection of the metallic transverse strips is covered in the strip path. The two outer layers of conductive crepe paper, which is usually only very weakly conductive, are then practically completely relieved of the conduct of surge currents that could lead to contact problems.
In order to achieve the latter goal as completely as possible

One way to achieve this is to use the two crepe paper outer coverings of the three-layer conductive covering, backing the conductive covering strip as covering as possible and if necessary, fold in the crepe paper webs at the edges around the conductive covering web.

F i g. 3 shows a section of the strip track. With 16 and 18 are again two of the consecutive ones metallic transverse strips, with 17 two lying between these metallic transverse strips Insulating strip. 19 shows an outer longitudinal strap which, as already mentioned, is expedient is designed as a self-adhesive insulating tape with tack glue. The metallic longitudinal belt 20 is galvanically connected to the metallic transverse strips by soldering, for example, as before described above.

According to a further proposal of the invention, either the metallic or the insulating material transverse strips or both are hollow or at least designed so that there is one in the strip path of the triple guide lining Can form coolant flow. It is then by using triple conductive linings designed in this way possible, thicker layers of solid insulating material in several insulating layers cooled on one or both sides and thus the strength of such a multiple-subdivided insulation against the thermoelectric Significantly increase penetration.

An example of a strip track designed in this way is shown in FIG. 4 reproduced. The metallic cross band 21 here consists of a thin metal tube, such as a copper tube, which is pressed against the next metallic cross band is isolated by an insulating material cross band (22) designed as a thin insulating tube is. One of the longitudinal straps 23 is shown in section.

In order to also make a strip web designed in this way elastic in the direction of the transverse belts, it is possible the transverse bands in the plane of the strip web with deflections perpendicular to their longitudinal direction waves slightly.

In the case of the FIG. 4 shown example of a coolant-carrying strip web are the transverse belts formed from thin tubes. However, other solutions to this idea are also possible, for example in the shape that the insulating material cross strips as thin "bridge profiles with short pillars" - height of the Pillars on the order of a few millimeters - are formed, the distance between the pillars is chosen so that coolant channels are formed in the case of a scale-like overlap.

When using the triple guide coverings described, it must be ensured that when using In transformer, measuring transducer and inductor construction, these conductive linings do not have a short-circuit winding form. This is achieved by inserting appropriate isolating distances and, if necessary, a corresponding one Overlap of the guide linings.

Through the joint use of crepe paper made conductive, as proposed according to the invention and a strip strip consisting of metallic transverse strips, the production is spatially deformed Equipotential surfaces possible without great difficulty. This allows the use of the conductive Crepe paper a formation of the required flanges on the winding ends, with the previously necessary Tearing can be dispensed with, while the only weakly conductive due to the metallic strips Crepe paper is protected from excessive electrical loads.

The patent protection extends only to the joint application of all features of claim 1, Protection of elements is not desired.

1 sheet of drawings

Claims (9)

Patent claims: 1. Arrangement for the formation of electrical equipotential surfaces in electrical devices, in particular oil-filled high-voltage transformers, transducers and reactors, where between two layers of non-metallic, weakly conductive material, another layer is introduced with a metallic conductor and where on cylindrical shield coverings to the outside or internally continuing electrically shielding flanges are connected thereby characterized in that the layers (14,15) of the weakly conductive material made of creped Consists of paper that is made conductive and that the middle layer is covered by a strip of paper Strip web intermediate layer is formed, in which metallic transverse strips (16,18) alternate with insulating transverse straps (17) are attached in a continuous sequence on longitudinal straps (19), wherein the formation of the shield flanges by stretching the creped guide paper and continuing the individual metallic strip web transverse strips into the flanges takes place. 2. Arrangement according to claim 1, characterized in that the metallic transverse strips (16,18), which overlap with the insulating transverse strips (17) in a scale-like manner, against each other are isolated. 3. Arrangement according to claim 1 or 2, characterized in that the longitudinal straps (19) at least in the area of the ends of the transverse strips (16, 17, 18) as self-adhesive insulating strips are executed with tack glue. 4. Arrangement according to one of claims 1 to 3, characterized in that at least one of the longitudinal straps (19) consists of metal that is metallically connected to the metallic transverse bands (16,18). 5. Arrangement according to one of claims 1 to 4, characterized in that between two metallic transverse bands (16, 18) at least two insulating strips (17) are inserted. 6. Arrangement according to one of claims 1 to 5, characterized in that the metallic transverse strips (16, 18) follow one another so closely that that they overlap in the projection. 7. Arrangement according to one of claims 1 to 6, characterized in that the strip web intermediate layer covers the two outer layers deposited. 8. Arrangement according to one of claims 1, 4, 5 or 7, characterized in that the strip web intermediate layer allows a coolant flow between the two weakly conductive cover layers. 9. Arrangement according to one of claims 1, 4, 5, 7 or 8, characterized in that the Cross bands of the strip web intermediate layer are hollow.