DE1184390B - Multiple-acting resilient tensioning device for high-voltage cables, especially busbars in outdoor switchgear - Google Patents

Description

Multiple-acting resilient tensioning device for high-tension ropes, especially of busbars in outdoor switchgear to avoid the changes in sag the ropes of high-voltage systems, especially busbars in outdoor switchgear, at all occurring rope temperatures including exposure to ice, To compensate for wind or short circuits, resilient bracing is advantageously used built-in. In open-air switchgear, for example, the resilient bracing is responsible that the mating contacts hanging on the ropes from the scissor-like grippers the disconnector is gripped and held securely in the event of any sagging can be.

In general, normal coil springs come with linear, more or more slightly inclined characteristic or disc springs with, if possible, in the working area slightly inclined characteristic to apply. These springs must be proportionate soft for the advantageous compensation of the change in length of the ropes due to the temperature change be. They cause additional loads due to short-circuit stress, wind or ice load a considerable and possibly inadmissible increase in sag.

The change in sag due to the additional loads in the permissible To keep within limits, the use of a harder spring is necessary. This execution again has the disadvantage that the desired compensation for the change in length of the rope fails due to the temperature change.

In order to prevent the change in slack in the rope as much as possible, refers the invention is based on a multiple-acting resilient tensioning device to compensate the sagging of high-voltage cables, especially busbars in outdoor switchgear, which avoids the disadvantages outlined above and thereby the previously known improved that two or more springs with different spring constants and the same or different heights in a common housing, frame or the like. like that are arranged that they change the cable sequentially or simultaneously be effective.

By combining a soft and a hard spring it is achieved that the change in sag due to temperature changes in the rope by the soft spring is kept as low as possible and that when the additional load occurs which a harder spring becomes effective. The spring housing is designed so that the spring with the greatest overall height occupies the entire length of the same, while the Springs with a lower overall height only take up part of the length of the spring housing, so that the springs one after the other when changing the cable pull or in the case of a large preload take effect at the same time.

The advantages of this arrangement are as follows: The change in sag, caused by the thermal expansion or additional loads due to wind, ice load or Short circuit, can be less with the combination of two or more springs according to the invention be held than is possible with a spring of great length.

The additional loads essentially act on the harder spring. By suitable adjustment of the spring constant can be achieved that the slack with additional load is about the same as that at the highest rope temperature. When occurring the soft spring mainly acts in the event of sudden loads in the event of a short circuit and thus dampens the shock better than if this shock also came from the harder one Spring would have to be intercepted in the event that only one spring for both loads would be provided.

The advantage of using a spring combination is in particular in it, that with lower maximum tensile stress than before with the resilient bracing can be expected from busbars.

In the drawing is a possible embodiment of the invention shown.

A soft spring 1 is located with a shorter, harder spring 2 in a common housing 3. This consists of a spring support 4, two spacer bolts 5 and an end plate 6 with a hanging loop. A tension bolt 7 transmits the rope force acting on it via a plate 8, which is guided into the bolt 5 and on which there is a spring centering 9 with a fitting of the spring 1, to the spring 2. The spring 1 is compressed until the plate 8 hits the spring 2. The spring 2 is centered by a tube 10. The spring 2 is fixed with respect to the tube 10 by a pin 11.

When the tensile force of the rope increases, for example by on it acting additional loads, springs 1 and 2 are compressed further. Included the spring 1 can be designed according to the respective needs so that they either with the spring 2 at the same time the state of full spring closure reached or already during the travel of the spring 2.

Claims (1)

Claims: 1. Multiple-acting resilient tensioning device to compensate for the slack of high-voltage cables, in particular of busbars in outdoor switchgear, characterized in that two or more springs (1, 2) with different spring constants and the same or different height in a housing, frame ( 3) or the like. Are arranged in such a way that they become effective when the cable pulls one after the other or at the same time: 2. Bracing device according to claim 1, characterized in that the spring with the greatest overall height and the spring with the lower overall height only one Occupies part of the length of the common housing. 3. Bracing device according to claim 1 and 2, characterized in that one of the springs has a softer characteristic and therefore becomes effective first. 4. Bracing device according to claim 1 to 3, characterized in that the springs are arranged concentrically to one another. 5. Bracing device according to claim 1 to 4, characterized in that the housing (3) consists of a spring support (4), two spacer bolts (5), an end plate (6), a tension bolt (7) and one through the spacer bolts (5) guided plate (8) consists.