DE3446061C2 - - Google Patents

Description

The invention relates to a support arrangement for one in a medium voltage or high voltage switching and -distribution system accommodated tubular capsule te, with a curved cross-sectional contour sige busbar, which by means of at least one one-piece support insulator, which is the latter than a the busbar at a clear distance surrounding, insert in a recess of a bracket barer ring is formed, from the inner edge in the ring interior directed support elements go out.  

They are disc-shaped or funnel-shaped zer or intermediate supporters known, which for example wise broadening of their outer and inner ran dung, d. H. that is, at their contact surfaces with the busbar to be supported and to the contact tion surfaces of their bracket, for example within an encapsulation. The problem here is the occurrence of partial discharges in the columns at the mentioned Be contact areas. To prevent this danger the known supporters or intermediate supporters with tax equipped with electrodes or with cast in the support NEN metal fittings that have a so-called potential control. This will reduce the cost of Supporters inevitably adversely affected; are also but also quality issues to consider and especially there is a certain amount of testing for the review on a gap-free tap gate.

Became known for a tubular encapsulated power rail is also a support arrangement which is formed by isolating rods (US-PS 37 12 953). These rods are screwed at one end into threaded bushings fastened to the busbar and project with their other end through the encapsulation elements. At these led out ends they are either held with nuts and subjected to a tensile stress ( Fig. 6) or instead - in another embodiment - clamped by means of compression rings, so that there is a compressive stress ( Fig. 7). This support arrangement is very expensive in terms of the number of necessary parts and their assembly, with the added difficulty of having to seal the encapsulation at the passage points of the isolating rods if necessary.

It is also known to have a flexible conductor or a cable for high-voltage systems within one to arrange flexible encapsulation, being two or more Partial support organs added to the conductor and together be snapped (US-ZS "IEEE Transactions on Power Apparatus and Systems ", 1984, vol. PAS-103, pages 2480 to 2485). These support members have a multi-part ring sections with fine spacers are connected. The latter extend to a wrapping made of silicone rubber, which connects the current conductor to the respective Supporting point surrounds. For the in this release explained need if the present construct tion and manufacturing costs are justified, for largely rigid busbars within an egg A largely rigid encapsulation, however, is this Publication of the structural regulations too complex and also - in terms of prevention or min partial discharge - not suitable.

Another publication (DE-GM 79 34 994) is egg Ne support arrangement for a in a tubular capsule arranged arranged busbar, which is designed as a bar-shaped insulating material bridge. The This insulation bridge is on both sides of it and of of the tubular encapsulation formed tongue and groove stanchions - movable in the longitudinal direction of the encapsulation - held and carries the on it (for example by means of Screw bus fastened) busbar. The beam-shaped insulating material bridge can form gene have the course of the current collection Take outgoing field lines into account. Night egg lig, however, it is that the tubular encapsulation with be special formations (namely the said groove or Spring formation) must be provided, which results in that the installation position of the encapsulation elements - at least  for current busbars with a rectangular cross section - can not be arbitrary, but a predetermined one Rotational position, based on the longitudinal axis of the encapsulation must take. In addition, there must be between the busbar and the insulating bridge is provided for attachment be, preferably an already mentioned screw consolidation, for which purpose in the busbar Openings are to be made. The attachment of such public is complex and these openings require at the same time an undesirable reduction in the cross section of the busbar at this point.

Finally, a tubular busbar is known, which is arranged within a pipe encapsulation surrounding the busbar all around at a greater distance (US-PS 40 18 978). Support and insulators of this busbar are used for supporting insulators which, as a molded element, have an outer ring encapsulating the inner wall of the pipe, from which three ring-shaped, interlocking supporting elements extend eccentrically to the encapsulation cross-section and to the busbar. The busbar is umgrif fen by all three ring-shaped support elements of a post insulator, the support elements in this area being so shaped that the busbar is completely surrounded by their material. This is in part to the extent that - in any case when unfavorable tolerance limit values coincide and with high current load on the busbar - jamming between the busbar and the post insulator can take place. In addition, the figuration of these post insulators is costly in terms of materials and, from a dielectric point of view, by no means cheap.

Starting from a bracket for a power rail ge according to the last mentioned publication, it turns out the object of the invention, a support arrangement for Sam Melschienen for the application mentioned at the beginning create which are particularly inexpensive to manufacture and is easy to assemble and with which pouring arm can be avoided without the described Having to accept disadvantages; in addition, the Support arrangement a favorable dielectric figuration have sufficient partial discharge freedom to achieve.

This object is achieved according to the invention achieved that the busbar at least two distributed approximately evenly around their circumference, approximately U-shaped, along surface lines of the outer cross-section contoured grooves (groove-like constrictions) points, the side walls rounded in the vault th outer cross-sectional contour of the busbar pass, and that the post insulator (also as an intermediate designated support) according to the number of grooves the busbar at least two in the ring interior has directed spoke-like support arms, the free Engage the ends in the grooves and here up to the sam Melschiene - supporting this - are enough.

This will achieved that the support insulator or its support arms in an almost field-free space on the busbars close, so that a partial discharge in the non avoidable gaps on the interface between Sam Melschiene and intermediate supports or its support arms even is not to be expected. But for that it is - how already stated above - necessary, the two sides Chen surfaces or walls of said groove with a sufficiently large radius in the outer contour of the sam to let melschiene open. In this context I should like to point out that with the previously mentioned ten "strong borders" those with comparatively large ß radii are meant, but not only geome tric exact arc shapes are addressed.  

An improvement of this effect just described is to educate through a further development of the inventive idea len, after which the width of the groove base of the grooves or groove-like constrictions at least a few millimeters is designed larger than the width of the engaging Support arm end of the support insulator. Between the to the Busbar-reaching ends of the support arms and the lateral walls of said groove-like constrictions So there is a distance of two or more several millimeters.

Another advantageous embodiment of the Invention can be seen in the proposal itself flat base of the groove base of the groove-like one laces with at least one in the cross sectional shape representing raised projection and / or to be equipped with a groove-like depression and Forms in the same direction at the free ends of the support to provide arms in these first-mentioned formations intervene positively. This makes an exact defi Position of the intermediate support in said nutar constriction or groove guaranteed.

Further expedient configurations relate to the post insulator. For this purpose, for example beat the support arms in their from the inside edge of the To make the ring outgoing area relatively wide, d. H. twice or three times as wide as its free end, the support arm contour towards its free end approximately tapered or tapered hyperbolic. Here the transition from the ring part to the support arm is required to be provided with sufficiently large radii. Such Training can still work in its desired mode of action be improved if you look at the inner edge of the Ring facing area of the support arm a triangle  like outbreak with strongly rounded corner areas sees. Such a measure is beyond the knowledge that voids or air gaps or gas gaps, if they are brought in at favorable places, the can reduce electrical field strength. Furthermore an outbreak, as it was called, material savings can be achieved.

To further improve the freedom from partial discharge of the Post insulator is also suggested, at least to widen the outer ring area significantly over the ring area a little further inside and especially compared to the thickness of the support arms.

A useful design proposal is also in it to see the outside of the ring area tire-like, circumferential projection, which in a Groove can be inserted for a bracket for the post insulator is. Such a holder can, for example, a chap be a selection. In this case the suggestion is made the bracket and precise location definition for the support isolator at the joint of two encapsulation elements to provide, the tire-like projection around the Ring area of the post insulator in the corresponding recess engages at the ends of the encapsulation elements.

Based on the drawing and the description below of the individual figures in this drawing, the Er invention and its advantageous embodiments times are explained and clarified. It shows

Fig. 1 shows a section through a massive busbar having provided thereon an intermediate support alarm zer,

Fig. 2 shows a section through a substantially tubular busbars with a vapor it took intermediate supporter,

Fig. 3 shows a specially shaped support arm of an intermediate supporter,

Fig. 3a and Fig. 3b modifications of the embodiment according to Fig. 3 and

Fig. 4 shows a small longitudinal section of an encapsulation shown cut with a busbar arranged therein and an intermediate support.

Fig. 1 shows a massive bus bar 10 having a substantially circular cross-sectional contour. It can be seen that the circular shape of this cross-sectional con ture has two opposing, approximately U-shaped, groove-like constrictions 11 and 12 , the lateral walls 13 and 14 (of the constriction 11 ) or 15 and 16 (of the constriction 12 ) with strong rounds in the otherwise circular cross-sectional structure of the busbar 10 pass. Not to be left unmentioned at this point is that, on the flat ground per se, these groove-like constrictions 11 and 12 each have a recess 17 or 18 formed therein. In these recesses 17 and 18 not more specifically bezif ferte formations of an intermediate support 19 brought up on the busbar 10 (also referred to as a support insulator), or more precisely: formations on support arms 20 and 21 which go from the intermediate support 19 . This intermediate support 19 presents itself as a kind of ring, which surrounds the busbar 10 at a clear distance and from which, as he just mentioned, the support arms 20 and 21 extend. It is noteworthy here that the transitions from the ring portion of the intermediate support 19 into the inwardly directed support arms 20 and 21 are greatly rounded, and further that the width of the support arms 20 and 21 at their free ends, that is, in the groove-like constrictions 11th and 12 einrei fen, is significantly smaller than the width of the groove base of these constrictions. So there are in each case a limited mil distance between the lateral edges of these support arms 20 and 21 and the adjacent lateral walls 13 and 14 or 15 and 16 of the constrictions 11 and 12 . In addition, what is not so apparent from this Dar position, the outer region of the ring part of the intermediate support 19 is th widened after both sides, that is, in the longitudinal direction of the busbar 10th

Fig. 2 illustrates, also in cross section, a tubular busbar 25 , the wesent union contour is composed of approximately semi-tubular regions 26 and 27 and a connecting web 28 . Ge compared to a solid busbar, as has been indicated in Fig. 1, a busbar, as shown here, has significantly better heat dissipation results and thereby a higher current carrying capacity per cross-sectional area unit. The formations on the lateral edges of the semi-tubular regions 26 and 27 are irrelevant here, but of interest are the groove-like constrictions 29 and 30 also present here, the constructions of which, as far as the outer contour of the busbar 25 is concerned, the constrictions 11 and 12 in , so that further explanations are virtually identical to FIG. 1 dispensable. Free ends of support arms 31 and 32 of an intermediate support 33 also engage in these groove-like constrictions 29 and 30 .

This intermediate support 33 , which is shown broken off to both sides in the presen- tation for space reasons, corresponds (apart from a somewhat larger scale) completely to that ( 19 ) in Fig. 1, except for the fact that its support arms 31 and 32 are wider in the area of the ring part than at their free ends, ie they taper approximately conically or wedge-shaped in their course towards the free end. But also clearly the large roundings at their starting area from the ring part of the intermediate support 32 and here, too, are arranged at the free ends (not numbered) projections which engage in corresponding recesses in the groove base of the groove-like constrictions 29 and 30 .

Fig. 3 shows a smaller part of an inter mediate supporter 35 with an outgoing arm 36 from this. This support arm has, at least in this view, a hyperbolic taper towards its free end and is otherwise provided with a triangular cutout 37 , the "corner regions" of which are very rounded, however. This cutout 37 not only serves to save material, but is also capable of improving the electrical properties of the intermediate support 35 , as already indicated at the beginning. The free end of this support arm 36 extends, as can be seen in this illustration, also in a groove-like lacing 38 of an only partially indicated bus bar 39 and abuts this bus bar 39 . Here too, the groove-like constriction 38 is formed with a significantly larger internal width than is the case with the free end of the support arm 36 . In contrast to the previously shown exemplary embodiments, a projection 40 is now formed on the groove base of the constriction 38 instead of a depression (e.g. 17 in FIG. 1) and accordingly a (not numbered) recess at the free end of the support arm 36 . The effect of these shapes is the same in both cases and practically equivalent.

Modifications of the outbreak 37 according to FIG. 3 illustrate FIGS . 3a with a highly pulled-up, triangular outbreak 41 and FIG. 3b with a circular outbreak 42 .

Finally, to Fig. 4. Here is a small area of an encapsulation with encapsulation elements 45 and 46 another joint in a longitudinal section shows ge. Within this encapsulation, a busbar 47 can be seen , which is worn or supported at this point by an inter mediate 48 . Of this intermediate support 48 , however, only the lower area (in the illustration) is shown, ie it has been broken off towards the top in order to make recesses 49 and 50 more clearly recognizable, which are located at the joints of the encapsulation elements 45 and 46 . In these recesses 49 and 50 there is a projection 51 , which protrudes cher over the ring portion of the intermediate support 48 and - by inserting it into the recesses 49 and 50 - serves for the exact position fixing of the intermediate support 48 . Has been mentioned and can now also be seen in this illustration, the widening on the outer region of the ring part of the intermediate support 48 , which extends to both sides and is formed by corresponding shapes 52 and 53 .

As already said at the beginning of the description of the figures, the illustrations only illustrate execution Example of the invention. Multiple deviations of these are conceivable, in particular it is possible and in In some cases, even useful instead of just two Support arms also provide three or more support arms and these at regular intervals around the busbar to arrange. This would be the case especially with very heavy busbars in terms of weight or those the extreme electrodynamic forces are exposed can.

Claims (8)

1. Support arrangement for a in a medium-voltage or high-voltage switchgear and distribution system, tubular, encapsulated, a curved cross-sectional contour having a single-phase current busbar, which is held by means of at least one one-piece support insulator, the latter being surrounded by a busbar as a clear distance , In a recess from a holder insertable ring is formed, starting from the inner edge into the ring inside the support elements te, characterized in that the busbar ( 10, 25, 39, 47 ) at least two approximately evenly distributed on its circumference, approximately U- shaped, along Mantelli lines of the outer cross-sectional contour grooves (groove-like constrictions 11, 12; 29, 30; 38 ), the side walls of which are rounded in the curved outer cross-sectional contour of the busbar, and that the support insulator (intermediate supports 19, 33, 35, 48 ) accordingly the number of grooves on the busbar at least two spoke-like support arms ( 20, 21; 31, 32; 36 ) has, whose free ends engage in the grooves and here up to the busbar - supporting this - reach. 2. Support arrangement according to claim 1, characterized in that the width of the groove base of the grooves ( 11, 12; 29, 30; 38 ) is a few millimeters larger than the width of the engaging support arm ends (ends of 20, 21; 31, 32; 36 ). 3. Support arrangement according to claims 1 or 2, characterized in that the groove base has at least one projection ( 40 , Fig. 3) and / or a groove-like Ver recess ( 17, 18 , Fig. 1), and that these formations engage positively in the same direction at the free ends of the support arms ( 20, 21; 31, 32; 36 ). 4. Support arrangement according to one of claims 1 to 3, characterized in that the support arms ( 31, 32; 36 ) in their outgoing from the inner edge of the ring Be rich have a width which is approximately twice or more than that at its free end, the support arm contour tapering towards its free end approximately conically or wedge-shaped or hyperbolic ( Fig. 2 and 3). 5. Support arrangement according to claim 4, characterized in that the support arms ( 36 ) in their the inner rim extension of the ring facing a triangular cut-out ( 37, 41 ) with strongly rounded corner areas or instead have an at least approximately circular cut-out ( 42 ) or a combination of two or more such outbreaks. 6. Support arrangement according to one of claims 1 to 5, characterized in that its outer ring area is significantly widened compared to the thickness of the support arms extending from the ring area ( Fig. 4). 7. Support arrangement according to one of claims 1 to 6, characterized in that the annular region of the support insulator ( 48 ) is surrounded by a tire-like, circumferential jump ( 51 ), which in a groove ( 49 + 50 ) of a holder for the support insulator is insertable. 8. Support arrangement according to claim 7, characterized in that the holder for the support insulator ( 48 ) is formed at the joint of two encapsulation elements ( 45, 46 ) and is fixed by means of these encapsulation elements in that the tire-like projection ( 51 ) on the ring area in engage corresponding recesses ( 49, 50 ) at the mutually facing ends of the encapsulation elements.