DE490834C - High-voltage transformer with a high-voltage winding applied to a carrier made of insulating material that surrounds the low-voltage winding - Google Patents

Description

High voltage transformer with one on one the low voltage winding surrounding carrier made of insulating material applied high-voltage winding It is already known in high-voltage transformers, the low-voltage winding To wind an insulating tube placed around the iron core and concentrically with the high-voltage winding also to be arranged on an insulating tube. Between the surface of the low voltage winding and the inner surface of the insulating tube for the high voltage winding there is a gap that is flushed with air or oil. These pipes are through Spacers stiffened against each other so that they are a fixed distance from each other maintained. The ends of the high-voltage insulating tube cut in a straight line from and are on the transformer core. For this reason there must be enough for one long creepage distance, the creation of which is an enlargement of the core window makes necessary, so the transformer enlarged.

In order to increase these creepage distances, you have to use these insulating tubes further insulating tubes are set between their ends and the iron body Leave the air or oil gap and move from the center of the core window Spacers are worn. Such a design of a high voltage transformer but has the disadvantage that the high voltage winding as a result of the electrical evoked or purely mechanical forces acting on them with their insulating cylinder on the fastening insulation pipe begins to rotate over time and the connecting cables thereby tear off the high-voltage winding.

The present invention seeks to remedy these inconveniences by that the insulating support of the high-voltage winding at the extreme ends of the wound Leg of the iron core is held self-supporting on both sides.

Compared to the known arrangement outlined first, there is the advantage that that there is no immediate creepage distance after the transformer travel in the core window, but only an air or oil penetration path, and compared to the second previously known Execution of that the creepage path without cumbersome and disadvantageous Isolierrohrbefestigungen can be increased significantly. There is also another advantage over both known arrangements in that no supports between the low and high voltage winding are required and there is a homogeneous dielectric (air or oil) everywhere. All these advantages are brought about by the suspension of the insulating girder, so to speak, like an overhead crane with himself. For this purpose, the ends of the insulating support are such educated, that the edges of the part pulled over the core leg the transformer iron do not touch. This ensures that all points between the insulating support edge and the iron a sufficiently large oil penetration path is achieved and due to the special arrangement the bolt at the extreme ends of the iron core has a very long creepage distance the insulating support achieved by the high-voltage winding towards the bolt.

In the figures, exemplary embodiments according to the invention are shown.

Fig. X shows a section in its left half and a section in its right Half a view of the arrangement of the windings in relation to the iron body of the transformer. Fig.2 shows a side view of Fig. I.

The low-voltage winding 12 located on an insulating tube is arranged around the transformer core = i. The insulating cylinder 13 , which is concentric to this, carries the high-voltage winding which is divided into two windings = q .. Within the core window 15, the ends of this insulating tube almost cut off with the high-voltage winding. The ends of the exposed part, which are hatched in cross section in the side view according to Fig. 2, are drawn on all sides over the cross-shaped core = i. The edges of the tube 13 run along a curved line 16 drawn in the right half of Fig. I and dashed in the left half Penetration path 17 only of the creepage distance = g, which is particularly long compared to the previously known designs, on the high-voltage insulating tube towards the fastening bolts 2o. The bolts run in the diameter of the high-voltage insulating tube 13 and carry spacers 21, through which a certain oil path 22 is maintained from the edge 16 of the high-voltage insulating tube 13 after the legs 18 of the transformer iron. These bolts 2o can serve at the same time to hold the metal sheets of the iron core = i or to connect the core = i to the legs 18. In the case of the production of the bolt from insulating material, of course, the creepage distance is also used = g essentially v lengthened.

Finally, Fig. 3 shows a modification of the insulating tube for the high-voltage winding = q., Insofar as the insulating support is formed from two parts 23, 24 of a cylinder which have square cutouts 25, 26 in their center. In the middle of the narrow sides are the holes 27 through which the bolts 2o for attaching these insulating parts 23, 24 to the outermost ends of the iron core (not shown) of the transformer are inserted. The insulating support no longer needs to extend into the core window. When combining the two insulating support designs, the normal insulating cylinder could also be used, but with approaches in the sense of the two ends 23, 24 according to Ab '. 3, which then take the place of the coated parts according to Fig. =. Cut-outs can also be made in the version according to Fig. Z, as shown there by dash-dotted lines. In all these cases, there is not a straight, on the surface of the insulating parts 23, 2q., But a curved to half the narrow side enlarged a rectangle leakage path 28. In the in fig example shown. 3 it starts at the bent edges 29 of a slotted metal cylinder 3o and leads to the arranged in the holes 27 bolts 2o. This design also has the advantage that, as a result of the use of such a metal cylinder, there is good electrical shielding of the high-voltage winding from the iron core and also better dissipation of the heat from the high-voltage winding is made possible.

The figures only show the application of the invention to single-phase transformers or core transformers. Naturally, the invention is also applicable to multiphase, e.g. B. three-phase transformers and jacket transformers usable.

Claims (5)

PATENT CLAIMS: i. High voltage transformer with one on one the low-voltage winding surrounding carrier made of insulating material applied High-voltage winding, characterized in that the carrier of the high-voltage winding cantilevered at the two extreme ends of the wound leg of the core on both sides is held. 2. High-voltage transformer according to claim i, characterized by such a design of the ends of the insulating tube serving as a carrier that the part lying within the core window is almost cut off with the winding and the exposed part is pulled over the core on all sides. 3. High voltage transformer according to claims i and 2, characterized in that the edges of the coated Part of the insulating tube does not touch the core and the ends through in diameter of the insulating tube extending bolts are fastened with spacers. q .. High voltage transformer according to claims i to 3, characterized in that the covered part of the insulating tube of two, possibly connected in one piece Support parts consists of a slotted metal cylinder bent at the edges, on which the high-voltage winding is applied. 5. High voltage transformer according to claims z to q., characterized in that each part of the insulating tube has a cutout in its center and the holding devices in the extended Center line of this section are arranged.