DE514430C - Putty-free attachment of fittings to insulating bodies, especially for transducers, in which the fitting is pressed onto the insulating body by means of clamping devices located at both ends of a curved flat strip running inside the insulating body and having only one counter-bearing - Google Patents

Description

Putty-free fastening of fittings to insulating bodies, in particular for transducers in which the valve is connected to an inside of the insulator only one counter bearing, curved flat band by means of at both of its ends clamps located on the insulator is pressed It is already known to attach fittings to insulators without putty. This is done by that the valve is constructed in several parts and individual parts by cones or Press rings pressed against the insulating body - earth. Bushing insulators are also already used the straight through bolts are used to secure the two-sided To press fittings against each other and thus on the insulator. Further are composed of individual parts, hollow insulating bodies through in their Inner joint rods, which are attached with their ends to the outer fittings are held together. In the first type of attachment, however, are specially trained Fitting parts or insulating body required, which significantly increases the cost of the Result in fastening of the fittings. The attachment of the fittings in the second and the third case can only be used when the interior of the insulator is completely free.

So that fittings can be fastened without putty, even in the case of insulating bodies to be carried out, in which the valve has a only one counter-bearing, curved flat band by means of at both ends located clamping devices is pressed onto the insulating body, is according to the invention the counter bearing by one in the insulator or outside the open on one side The bridge located on the isolator is formed around which the ribbon is looped laying around. An existing or specially provided counter bearing can be used as a counter bearing simple isolator or apparatus part can be used, as shown in the figures show the illustrated embodiments.

In Figs. I and 2 the upper part of a post insulator is i i in two mutually perpendicular sections shown. The counter bearing is in In this case, formed by a bridge 1a around which the flexible part 13 is looped laying around. The web 14 can then be used as a counter bearing when between the the lower end of the loop and the foot fitting lying on the ground, further webs to prevent this an internal flashover are provided.

The flexible part can consist of a ribbon or wire, the Ends attached to the fitting 15 or in slots of fastening screw bolts 16 are soldered or riveted. The screw bolts are through the valve plate 15 passed through and cause when tightening their nuts that the valve plate 15 is pressed against the post insulator i i.

Instead of the bridge 12, two laterally present projections can also be used be used on the insulator, around which such a flexible part is then wrapped. As an effective means of preventing the flexible parts from slipping down, these Projections at their ends still received bulges.

In Fig. 3 and a. are all known bushing current transformers with a passage 18 extending transversely through the insulating body 17 in two sections shown.

The counter bearing for the flexible part 13 is in this case the cross-circuit 18 is formed, uni which the primary winding i9 is used.

As these figures show, they are essentially paler Metal bands attached around the primary winding of the as in Fig. I and 2 Current transformer alternately. By tightening the screw bolts 22, 23 the fittings 20, 21 are pressed against one another in the axial direction of the insulating body.

If the flexible parts 13 are made of an electrically conductive material, in this way they can be used as lines from one valve 2 "to the other 21 used «-erden. For this purpose, the ends of the are connected to one another in an electrically conductive manner Flat strips 13 isolated from deal fittings, namely those on the screw bolts 23 fastened ends by jointed insulating pieces 28 and the au the bolts 2z fastened ends by insulating sleeves 25. In this way, a bridging resistor or a spark gap between the fitting 2o or 21 via the screw bolt 2: 2, flat strips 13, screw bolts 22, a line and the other fitting 21 or 20 can be used. It is then irrelevant to which valve the bridging resistor is connected or the spark gap can be laid.

Figs. 5 and 6 show pot-type current transformers in which the fitting 29 must be designed in two parts because of the connections. In this case, the insulating body 30 is formed like a bottle, and the flexible part 13 lies down in a manner similar to that of the bushing current transformers according to FIGS. 3 and d. around the cross passage i $. In order to prevent a conductive connection between the two fitting parts via the flexible part, either the screw bolts are insulated from one another, or an insulating intermediate piece 28 is again inserted into the conductive flexible part. The two parts of the armature are combined into one piece with the interposition of insulating material 31 and can therefore be pressed together with a fastening according to the invention on the bottle-shaped insulating body 3o.

Fig. 7 shows a current transformer, the windings of which are arranged in a pot 32. The supply lines are introduced through an insulator 34 which is open at the bottom and is inserted into the lid 33 of the pot. In this case, the counter-bearing for the flexible part 13 is formed by the core 35 of the current transformer, around which the winding 36 is wrapped. The flat strip lies over the winding and thus wraps around the core with the winding. By tightening the screw bolts, the armature 29 is in turn fastened to the lead-in insulator 34 without cement.

Finally, a voltage converter is shown in Figure 8, in which the attachment of the fittings 37 to the inlet insulators 38, 39 is also carried out in the manner according to the invention. In this case, the counter bearing for the flexible part 13 is formed by the core or the windings, on which there is also a metallic protective ring 4.o against overvoltages. In this case, the supply lines to the windings can be formed by the flexible flat strips 13 themselves, so that special supply lines are unnecessary. The fittings 37 are fastened to the inlet insulators 38, 39 again in the manner already described above.

Finally, in Fig. 9 and io there is another type of fastening of the flexible flat belt 13 shown in two views. The ends of the ribbon are rolled in a circle and are inserted into grooves 41 of the screw bolts q.2 and held in this by pins q.3. With such a fastening is opposite the first described achieves the advantage that an easily detachable arrangement is created which does not result in a shear stress on the fastening pin Has. Another advantage of this attachment ordered is that a subsequent Attachment or removal of the screw bolts at the ends of the ribbon is possible even if the ribbon has already been drawn into the insulating body. i That Flat belt can for example consist of spring steel, so that in addition to the light Flexibility also ensures sufficient strength. The flexible part can naturally have any rectangular or circular cross-section Lind also consist of several wires, the ends of which in a known way are prepared for attachment. How the flexible part is attached to the fitting is of course irrelevant to the invention. ..

Claims (1)

PATENT CLAIMS: i. Putty-free fastening of fittings to insulating bodies, especially for converters in which the armature has an inside of the insulator running, curved flat band with only one counter bearing by means of its clamping devices located at both ends is pressed onto the insulating body, characterized in that the counter bearing by one in the insulator or outside of the open insulator located on one side bridge is formed around which puts the ribbon around like a loop. z. Fastening according to claim i for transducer insulating bodies with a passage traversing the insulating body transversely, characterized in that that the counter bearing or the bridge through the looped around the outside of the passage Primary winding of the converter is formed. 3. Attachment according to claim i and 2, characterized in that the ribbon is attached to the armature in an insulated manner. 4 .. Attachment according to claim i to 3, characterized in that when used a conductive flat strip this with the one fitting or one fitting part is conductively connected, but isolated from the or the other, to connect a bridging resistance located on this fitting or other fitting part or a spark gap. 5. Fastening according to claim i to 3, characterized in that that the conductive ribbon is electrically interrupted by inserting an insulating piece is. 6. Fastening according to claim i to 5, characterized in that the ends of the ribbon are held in slots by screw bolts. 7. Attachment after Claims 1 to 6, characterized in that the ends of the flat strip are rolled inserted into a groove of the screw bolt and inserted into these are held.