DE4225989A1 - Field distance holder for HV overhead cables with bunched conductors - comprises distance piece holding conductor cables apart and having end clamps and two clampable half shells - Google Patents

Abstract

An elastomer inlay (12,12') is positioned between the distance piece (2) and the conductor cable (14). The half shells (6,6') are clamped rigidly to the distance piece variable as to length, number of distance ends and their positioning. The elastomer inlay is also positioned between the half shells and a conductor cable. A tensioning bolt (7) with two nuts (8) engages through the distance piece transversely and fits captively into projections (5,5') on the half shells. The distance piece, at least in its accommodation area for the clamps (3,3'), has non-circular, pref., multi-angled cross-section, and the clamps with corresp. projections (5,5') engage around the accommodation area (4) of the distance piece. ADVANTAGE - Adaptable to varying applications, more resistant to stresses.

Description

The invention relates to a field spacer for high-voltage overhead lines gene with bundle ladders with the features of the preamble of claim 1.

In the case of high-voltage overhead lines, it is common to transmit larger lei per phase, several lines connected in parallel and running in parallel Arrange the ropes. These ladder ropes must be in one another in certain Distances are connected by field spacers to the sub-conductor to ensure and especially to avoid that the ropes touch and involve each other. In the event of a short circuit, the occurring Pressure and tensile forces do not lead to deformation of the spacer. Around To be able to fulfill this task, the field spacers must be sufficient firmly connected to the conductor ropes and even a high inherent rigidity show speed. The field spacers also contain several Elasto inserts to ensure an articulated connection between conductor cables and Manufacture field spacers. The elastic mobility leads to low mechanical loads on the spacers.

Such field spacers are such. B. from DE-GM 78 07 393 and DE-GM 75 22 764 known.

The sub-conductor spacing at which the parallel-connected conductor cables to be relocated is standardized; however, it is not the same in all countries. So this distance is 400 mm in the old Federal Republic, after earlier DE East standard it was 500 mm; according to international standards it is z. B. 450 mm. These standards, which differ considerably from one another, make it so required, suitable for any special construction or repair purpose to have standard-compliant and different field spacers available.

The field spacer known from DE-GM 78 07 393 is to adapt to Different standardized conductor spacings are not suitable. Because the ladder rope-encompassing clamps in one piece on the spacer of the field  are molded on, the ge entire field spacers can be replaced. Therefore, the in the Practice occurring different sub-conductor spacing according to di dimensioned field spacers are manufactured and kept ready. This he however increases manufacturing and logistics costs as well as storage costs.

In addition, if there is a change in the distance between the partial conductors or another conductor rope diameter the entire field spacer is unusable.

These disadvantages are avoided by the field spacing known from DE-GM 75 22 764 holder. The spacer and the clamps are separate with each other there braceable parts. In this way, when the partial conductor is changed stood or at least parts of the Continue using the field spacer. Separate components also allow the easier manufacture of the field spacer. However, it is disadvantageous due to the special arrangement of the elastomer insert, the design the spacer and the half shells. The elastomer insert is from Di punched piece and the half shells. To the elastic mobility of the To ensure conductor cables in relation to the field spacer, the two half-shells can be moved relative to the spacer. The one for this necessary shaping of spacer and half shells complicated the manufacture of the field spacer. Due to the mobility of the half-shells compared to the spacer also considerable deformation and Transfer shear forces to the elastomer insert. It is therefore becoming rapid damaged or destroyed so that their function is not guaranteed. Also are due to the mobility of the spacer and half shells mechanical Damage to these parts to be expected. Furthermore, the field spacer only suitable for two partial conductors.

The invention has for its object the known field spacers to further develop in such a way that, depending on the intended use of the fulfilling standard can be adapted. Furthermore, the mechanical Strain on the spacer is reduced and the mode of action the elastomer insert can be improved.

This object is achieved by the combination of features of claim 1.

It is only necessary to use spacers of different lengths with an ent to keep the appropriate number of distance ends ready, which can be used as required  the terminals and can then be used in accordance with standards. However, it is essential that the parts can be assembled in such a way that the resulting field spacer is completely rigid and in particular none Relative movement between the terminals and the spacer allows. This is particularly simple and is therefore proposed here if the spacer and the half shells are rigidly clamped together. Me Chan damage to the field spacer by mutual rela tive movements of the individual parts are therefore excluded. The rigid one Connection of spacer and half shells reliably ensures the required sub-conductor spacing between the conductor cables. The elastomer must therefore not be a coupling link between the spacer and the terminal be installed in the field spacer. Rather, it does this here proposed arrangement of the elastomer insert lower mechanical loading stresses on the areas of the lei within the half-shells ropes. In addition, the assembly and eventual replacement of the Elasto Mer insert in the inventive field spacer simplified. The arrangement tion of the elastomer insert between half-shells and conductor rope causes that the former has a larger volume and thus a greater mass. So is the elastic mobility of the conductor ropes is also improved.

Claim 2 relates to a preferred embodiment for the production of the star interlock between the half shells and the spacer.

According to claim 3, the clamping means provides sufficient position security the half shells on the spacer. Relative movements of the half shells both in the longitudinal direction of the spacer and in its circumferential direction are prevented.

Claim 4 relates to a preferred embodiment of the clamping means.

According to claim 5 is a rotational movement of the terminals in the circumferential direction of the Spacer excluded. In this way, the position is fixed Clamps also improved. The non-rotatable positive connection between Clamps and spacer are explained using an example: To build a Field spacer with two terminals, that is, with a two-part bundle is used, the spacer must be in the form of a straight rod point. The bar can have any cross-section; only in its end areas (recording area) should be square, for example. The  In this case, clamps must have protrusions, so-called neck pieces, be provided, which also has a square opening with such Ab have measurement that they overlap the end portions of the spacer can. In another arrangement, the end pieces can e.g. B. triangular, to be pentagonal or hexagonal. It is also an elliptical cross cut the end pieces conceivable. In any case, the terminals must be ent speaking projections the receiving area of the spacer can grasp positively.

The elastomer insert according to claim 6 generally consists of a electrically non-conductive material with high weather resistance. she has the Task, the mechanical clamping voltage, which during assembly of the Terminal on the conductor rope is transferred unchanged for a long time right and at the same time a certain mobility of the leader to ensure rope relative to the clamp. The elastomer insert is about this Purpose divided into two half shells, which inside the clamp half shells attached, for example glued, screwed, riveted, etc. are. It is also possible to attach the two half-shells to the elastomer insert to connect one place, for example like a film hinge. Such an arrangement then holds the parts that belong together, including the clamp half-shells in a ready-to-install state men and thus facilitates the assembly process.

An elastomer insert designed according to claim 7 causes its ver better fixation on the conductor rope. Accidental rotation between Elastomer insert and conductor rope are prevented. The grooves continue to serve ventilation and also ensure a certain desired compression Miscibility or elasticity in the clamping shell system area. Continue to effect the grooves are a gentle insert of the conductor rope.

The elastomer insert according to claim 8 also improves its com pressibility. At the same time, it enables ventilation of the conductor rope.

To keep the field spacer at line potential, according to An Say 9 suggested that the elastomeric inserts at least one elec tric conductive area, the conductor for equipotential bonding connects to the terminals. This electrical area can e.g. B. a zone in the elastomer shell, which can be caused, for example, by metallic additives  has been made conductive or at least semi-conductive. In this way it is necessary equipotential bonding guaranteed without additional components.

Claim 10 relates to a preferred embodiment of the electrically conductive Area. Because of the fixed arrangement of the elastomer insert in the Monta In the final state, the metal spring is also fixed between a half-shell and the conductor rope. This way there is permanent electrical contact guaranteed between the terminal and the associated conductor rope.

An elastomer insert designed according to claim 11 facilitates bending movement between clamp and rope without pressure peaks on the clamp menrand is coming.

According to claim 12, the invention is not on rod-shaped spacers limits what is required for field spacers for two parallel conductors the. Rather, it can also be applied when the spacer is a Triangle, is a quadrangle or polygon, with at the ends or corners of each because a clamp can be attached and locked. Field spacer with derar term spacers can be used, for example, for assembly of high-voltage lines, each with three parallel in-phase conductors; Field spacers with square spacers for use with four similar parallel partial conductors.

The invention is described below with reference to the accompanying drawing purifies. They represent:

Figure 1 is a side view, partially in cross section of an embodiment of a field spacer according to the invention.

Fig. 2 and 3 are cross sections of a clamp according to Fig. 1 with differently designed inserts elastomer.

The field spacer shown in Fig. 1 is designated as a whole by 1. It consists of the spacer 2 and the two terminals 3 and 3 '. The Di punch 2 is a straight rod with polygonal profile in the illustrated embodiment. The parts, i.e. the spacer and the clamps, are separate parts that can be assembled as a kit to form a field spacer.

As a result of their shape and accuracy of fit, the parts can be plugged into one another in a form-fitting manner and fixed in their mutual position by means of a form-locking means. This positive locking comes in the game shown Ausführungsbei that the spacer 2 at least in the accommodation area 4 has a polygonal cross-section and the clamps with accordingly shaped projections 5 encompass the receiving area 4 of the spacer 2 . Each terminal 3 , 3 'consists of two half-shells len 6 , 6 ' with molded projections 5 , 5 ', the projections have Spannmit tel 7 , which are captive in the respective half-shells. In the illustrated embodiment, these clamping means are a screw 8 with a lock nut 9 . The screw 8 rests with its screw head on a washer 10 ; her shaft is secured with the aid of a Si washer 11 , so that the screw can not be removed from the bore of the half-shell 6 . The lock nut 9 is captively pressed into a corresponding opening of the half-shell 6 '. The arrangement be acts that when mounting the half-shells 6 and 6 'the required clamping medium is immediately captive at hand.

Fig. 1 shows that the terminals 3 , 3 'in the region of the half-shells each have an elastomer insert 12 , 12 ' which is captively connected to at least one half-shell. In the elastomeric inserts 12 , 12 'at least one electrically conductive region 13 , 13 ' is incorporated, which connects the conductor cable 14 to the terminal for potential equalization. The electrically conductive areas 13 , 13 'contain in the simplest case a metal spring 15 , 15 ', which produces the necessary contacts. Instead of the metal spring, other conductive areas can also be incorporated into the elastomer inlays, for example by means of metal powder inlays or the like.

Figs. 2 and 3 of the drawings show the right-hand terminal region of the enlarged views Fig. 1. The same parts are provided with the same reference numerals. According to FIG. 2, the elastomer insert in the inner region, which is in direct contact with the conductor cable 14 , has numerous grooves 16 , the longitudinal axis of which runs parallel to the conductor cable 14 . These grooves give the Ela stomer insert increased compressibility and thus improve the exercise and thus the clamping effect. In addition, they cause a protective insert of the conductor cable 14 within the elastomer insert 12 , 12 '.

In the embodiment shown in FIG. 3, larger depressions 17 are present both on the inner surface and on the outer surface of the elastomer insert, which also extend in the shape of a groove in the direction of the conductor 14 . These depressions also have the purpose of improving the compressibility of the elastomer insert; but they also serve to vent the conductor cable.

Reference list

1 field spacer
2 spacer
3, 3 ′ terminals
4 recording area
5 projection
6, 6 ′ half shells
7 clamping devices
8 screw
9 lock nut
10 washer
11 lock washer
12, 12 ′ elastomer insert
13, 13 ' electr. leading area
14 conductor rope
15, 15 ′ metal spring
16 grooves
17 wells

Claims (13)

1. Field spacer for high-voltage overhead lines with bundle conductors ( 14 )

• - a spacer ( 2 ) which keeps the conductor cables ( 14 ) at a distance,
• - At the ends of the spacer ( 2 ) arranged clamps ( 3 , 3 ') for fi xation each of a conductor rope ( 14 ) surrounded by two on the dance piece ( 2 ) braced half-shells ( 6 , 6 ') and
• - An elastomer insert ( 12 , 12 ') between the spacer ( 2 ) and conductor cable ( 14 ),

characterized,
that the half-shells ( 6 , 6 ') are rigidly braced on the variable in length and number of spacer ends and their positioning spacer ( 2 ) and
that the elastomer insert ( 12 , 12 ') between the half-shells ( 6 , 6 ') and egg nem conductor cable ( 14 ). 2. field spacer according to claim 1, characterized in that the half-shells ( 6 , 6 ') are rigidly locked by a clamping means ( 7 ) with the spacer ( 2 ). 3. field spacer according to claim 2, characterized in that the clamping means ( 7 )

• - The spacer ( 2 ) passes through transversely to its longitudinal direction and
• - In the on the half-shells ( 6 , 6 ') projections ( 5 , 5 ') is captively fitted.

4. field spacer according to claim 2 or 3, characterized in that the clamping means ( 7 ) is a screw ( 8 ). 5. field spacer according to claim 1 and 3, characterized in that the spacer ( 2 ) at least in its receiving area ( 4 ) for the terminals ( 3 , 3 ') has a non-circular, in particular a polygonal cross-section and the terminals ( 3 , 3rd ') With appropriately shaped Ausla extensions ( 5 , 5 ') the receiving area ( 4 ) of the spacer ( 2 ) positively embrace. 6. field spacer according to claim 1, characterized in that the elastomer insert ( 12 , 12 ') with at least one half-shell ( 6 , 6 ') is un captively connected. 7. field spacer according to claim 6, characterized in that the elastomer insert ( 12 , 12 ') arranged in the cable direction grooves ( 16 ) for the positive sheathing of the conductor cable ( 14 ). 8. field spacer according to claim 6 or 7, characterized in that on the outer and / or inner surface of the elastomer insert ril len-shaped depressions ( 17 ) are arranged for its compressibility. 9. field spacer according to one of claims 6 to 8, characterized in that the elastomer insert ( 12 , 12 ') has at least one electrically conductive loading area ( 13 , 13 ') which for equipotential bonding, the conductor cable ( 14 ) with the terminals ( 3rd , 3 ′) connects. 10. field spacer according to claim 9, characterized in that the electrically conductive region ( 13 , 13 ') is a metal spring ( 15 , 15 '). 11. Field spacer according to one of claims 6 to 10, characterized in that the elastomer insert ( 12 , 12 ') on the rope entry and exit side is expanded like a trumpet. 12. Field spacer according to one of the preceding claims, characterized in that the spacer ( 2 ) is a rod, a triangle, a square or a polygon, at the ends or corners of which a clamp ( 3 ) can be locked.