DE2526671A1 - HV insulation system in two parts - has insulating element wider at ends than in middle inserted in recesses in two parts - Google Patents

Abstract

The insulating element enters into a recess in the HV carrying part with a reduced fieldstrength. The insulating element is wider at its ends than in the middle and it is inserted by its outer end in a recess of the low potential part, and its inner end has a fitting which is electrically connected with the HV carrying part. Screening electrodes cover the inner end of the insulating element on both of its sides, so that the inner end of the insulating element is inserted into a recess produced by the fitting and screens.

Description

"High Voltage Isolation Assembly" The invention relates to an isolation arrangement for high voltage with one between two on different Isolating body located at the potential of the dividers, which is on the high-voltage potential lying part protrudes into a room with reduced field strength.

There are a number of isolation arrangements have become known which isolate a high-voltage part from a part that is at ground potential. Such insulation arrangements are often used in electrical switchgears, in which one or more inner conductors are enclosed in a metal enclosure, whereby gas is used as the insulating medium between the inner conductor and the outer encapsulation or liquid, but preferably gaseous SF6, are used. When executing Such an insulating arrangement particularly depends on the distribution of the tangential field strength over the insulator, as this is the main reason for a flashover between the inner liner and the outer encapsulation on the insulating body.

If you use an insulating body with parallel side walls, then the tangential field strength runs from a high value at the joint between Inner conductor and insulating body except for a low value at the joint between Insulating body and outer encapsulation, the course being arnäFern hyperbolic. This has the disadvantage that the tangential field strength is precisely in the critical area is too high at the joint between the inner conductor and the insulating body.

Attempts have been made, particularly at the joint between the inner conductors and insulating body to reduce the tangential field strength. This is achieved through this that the support foot of the insulating body on the inner conductor was extremely widened, wherein the insulating body in the remaining area extends radially outwards in parallel Has side walls. The tangential field strength falls from the inside to the outside from a comparatively low value up to the transition from the broad foot to the parallel one Section, rises sharply at this point except for one considerably above value lying on the inside and slowly decreases from there. True is has been achieved in this way that at the joint between the insulating body and Inner conductor the tangential field strength is reduced and that because of the long distance At the transition point from the foot to the parallel outer section, creeping discharges in can be prevented to a large extent. On the other hand is the course of the field strength especially at the transition point from the foot to the parallel outer section because of the steep Incline unfavorable; the manufacture of such an insulating body is also particularly important difficult.

There is also an insulating body known as a conical Insulator is formed and its width from the inner radius, i.e. from the joint between the inner conductor and the insulating body drops continuously to the outside. This allows an essentially constant course of the tangential field strength between Inside and outside diameter can be achieved.

Although such a course compared to the course in other well-known Execution brings considerable advantages, it is still not optimal because on the joints have a comparatively high field strength.

A frustoconical insulating body has also become known, which is provided with ribs, so that this considerably extends the creepage distances will.

When considering the known insulating body can be said in summary be that the insulating body according to the point of view of either long creepage distances or given maximum values for tangential and / or normal field strengths and / or Magnitude values of the field strength were dimensioned. In addition, there is also an execution became known, at which a constant tangential field strength was achieved.

The object of the invention is the tangential field strength both at the Joint between inner conductor and insulating body as well as at the joint between Insulating body and encapsulation to be greatly reduced, so that in the area of the joints or clamping points tangential field intensities can be achieved, which considerably are lower than the mean.

This object is achieved according to the invention in that the insulating body at its inner and outer radius is wider than at the middle radius that it continues at the outer radius behind the inner surface of the low potential Part is drawn in that it has a drawn into the IsoliaF body on the inner radius, with the part carrying the high voltage electrically connected casting fitting and that the IsolieF body on the inner radius on both sides of spaced apart Shielding electrodes is included so that the insulating body with its edges in the recess formed by the sprue fitting and the shielding electrodes on both sides intervenes.

Characterized in that the insulating body on the portion lying on the inner radius has a pouring fitting and on both sides of spaced shielding electrodes is included so that the insulating body with its edges in the by the pouring fitting and the zone of reduced field strength formed on both sides of the shielding electrodes engages, and that the insulating body at its outer radius behind the inner surface of the on low Potential located part is withdrawn achieves that the tangential field strength drops at the inner or outer radius.

Through the joint application of the features mentioned, it is achieved that the tangential field strength values at the clamping points are relatively low are, while they are in the area of the mean radius, i.e. halfway between the inner conductor and the outer encapsulation, are higher than the mean value.

The two critical points, namely the joints of the insulating body with the inner conductor and the outer encapsulation considerably relieved of electrical load.

Strictly speaking, the measures just described are only valid for rotationally symmetrical arrangements of inner conductor, insulating body and encapsulation apply. But it is easily possible to use the insulating arrangement even if the switchgear is not single-pole, but three-pole, i.e. if not only a single inner conductor, but for example three inner conductors from an outer encapsulation are surrounded. Of course there is a certain mutual influence of the tangential field strength given by the three inner conductors. But it turned out that the deviations of the course that applies to a rotationally symmetrical arrangement is relatively small are.

For a calculated example, the deviations are roughly between 10 to 15%.

Further advantageous embodiment 5 forms and improvements of the invention can be found in the subclaims.

An exemplary embodiment of the invention is to be described in greater detail on the basis of the drawing explained and described.

1 shows an insulating arrangement according to the invention in cross section, 2 shows the basic course of the tangential field strength.

An encapsulated SF6 busbar has an inner conductor 1 and an outer encapsulation 2, which is insulated from one another by an insulating body 3 and are supported against each other by him. The outer enclosure 2 is divided and made of two encapsulation tubes 21 and 22 built, each in a flange 23 and 24 ends. The insulating body 3 is located between the two flanges 23 and 24. Is on the inner portion of the insulating body 3, surrounded by the insulating body 3, a pouring fitting 4 is arranged, which with its middle section 41 into the interior of the insulating body 3 protrudes. The cast-in fitting 4 now projects beyond the insulating body 3 in the axial direction. Are on both sides of the pouring valve 4, on this subsequently, mirror image and symmetrical shields 5 and 6 are provided which, as well like the pouring fitting 4, made of electrically conductive material and with the Inner conductor 1, as well as the pouring fitting 4, are electrically connected. The two cast-in fittings 5u.6bejAzen at their ends facing the insulating body 4 cylindrical projections 51 and 61, whose outer diameter Da 51 and 61, respectively, correspond to the outer diameter Da4 of the end areas of the pouring fitting 4 correspond. So that is through the means section 41 of the pouring fitting 4 and the two shields 5 and 6 have a recess 7 and 8 formed into which the side surfaces 31 of the insulating body protrude.

At its outer edge, the insulating body 3 is a ring fitting 9 surround, which increases the mechanical strength of the insulating body 3 and for Holding the insulating body 3 between the two encapsulating tubes 21 and 22 is used. The ring fitting 9 has a U-shaped recess 10 so that the inner diameter the Ring fitting 9 is stepped. The outer surface of the insulating body 3 is the inner surface the ring fitting 9 adapted; the insulating body 3 has a recess 32 which engages in the recess 10. In the area of the outer diameter of the insulator 3 circumferential annular grooves 33 are provided on its side surfaces, which for receiving a sealing ring 11 are used. Between the outer surface of the insulating body 3 and the Innau surface of the ring fitting 9 is a gap 12 during operation, which arises in the following way: The insulating body 3 is together with the cast-in fitting 4 and the ring fitting 9 made of plastic by a casting process. Included the casting temperature is above the later operating temperature. As soon as the insulator 3 cools down, the insulating body shrinks considerably more than the sprue fitting 4 or the ring fitting 9.

As a result, the insulating body 3 rests in a gas-tight manner on the casting armatw, while the gap 12 arises between the ring fitting 9 and the insulating body. The insulating body now shrinks not only radially, but also in the axial direction, so that between the axial boundary surfaces of the ring fitting 9 and the insulating body 3 forms a so-called shrinkage dimension d.

This dimension d is also advantageous because it is screwed together the two flanges 23 and 24 by means of a screw-nut connection 25 a direct Pressure loading of the insulator in its outer area is avoided and thereby a metallic connection of the encapsulation 2 is guaranteed. This metallic Connection is for conducting any currents that may occur (e.g. when grounding the Encapsulation) required. The gap 12 and the amount of shrinkage d are at low temperature the biggest. Because the operating temperature of the insulation assembly is always below the casting temperature of the insulator, there is no stress due to thermal expansion and internal mechanical (thermal) stresses cannot occur because at operating temperature the insulator 3 neither from the inside against the Rint fitting nor in the axial direction Direction towards the flanges 23 and 24 presses. Furthermore, the connection remains Sprue fitting 4 for insulating body 3 always gas-tight because of special treatment the surface, e.g. 3. Sandblasting, there is no shrinking of the sprue fitting can.

If the surface is sandblasted, then the surface adhesion becomes the insulator 3 on the pouring armature 4 improved.

The ring fitting 9 also has another advantage, provided that the bolt 25a of the screw connection 25 is screwed into the ring fitting 9 is (as shown in the example): Used when dismantling the encapsulation tube, for example 21 loosened the nut 25b located on the right in the drawing, then there is between the flange 24 and the ring fitting 9 still enne screw connection via the in the The nut 25c shown on the left and the nut screwed into the ring fitting 9 Bolzen 25. Obi1bmde encapsulation can be under insulating gas pressure (SF6) during operation one encapsulation tube, e.g. 21, can be dismantled while the other, 22, is in operation can stay. In this case, however, the insulating body 3 would be (not shown) designed as a Schotttz isolator. The insulating body 3 holds the gas pressure Encapsulation tube 22 against atmospheric pressure, since the in the drawing surface 34 of the formation 32 located on the right against the corresponding surface of the Turn 10 of the ring fitting creates. This will destroy the insulating body or at least damage from the existing pressure difference is avoided. It is also possible to design the insulating body 3 only as a support insulator. Then it has passages that allow pressure equalization from an encapsulation tube in allow the other. The inventive contour can thus be used both in the case of partition insulators as well as for suspension isolators.

I The shape of the insulating body 3 is now according to the invention in the middle Section, i.e. in the area between the inner diameter and the outer diameter in the axial direction Direction thinner than on the inside or outside diameter. The side surface runs 311 in the following also called contour 31, from the inner radius, which corresponds to the radius Da resp. Since 4 corresponds, initially a short distance in the radial direction, i.e. up to about Point a; then it runs inwards to approximately area B, starting from the point A follows a large radius up to area B; it runs in area 3 briefly again in the radial direction and then merges into one in area C. Section with a relatively small radius such that it faces outwards against the flange at the angle Cy, the angle t being approximately 900. The point, where it meets the flange is denoted by E; the radius Rm or in other words the diameter on which the point E lies is larger than the inner diameter Di 2, so that the insulating body is behind the inner surface, i.e. the inner surface 26 of the outer encapsulation 2 protrudes or is drawn in.

Due to the special design with the built-in fitting 4 and shielding body 5 and 6 formed depressions 7 and 8 and due to the evasion of the insulating body 3 in the surface 26 and the variable in the radial direction Width of the insulating body 3 is a tangential field strength distribution from the inside to the outside approximately as shown in FIG. 2 is achieved. At the inner diameter, i.e. at the diameter at which the insulating body 3 with its side surfaces or. with its contour 31 abuts against the sprue fitting (this is point F), is the Tangential field strength minimal; the value is Etmin. Then the tangential field strength increases an up to the value Etmax and from there falls again to approximately Etmin, whereby to it should be noted that Etmin on the inside diameter is absolutely a different one Can have value as Etmin on the outer diameter, since both values are strongly dependent on the Depend on geometry.

In any case, both Etmin values are below the mean value Etmittel. The area under the curve is equal to the area between the abscissa and the straight line formed by the mean.

Claims (8)

Claims che High voltage insulation arrangement with one between two on different Insulating body located near the potential, which is connected to the high-voltage potential lying part protrudes into a room with reduced field strength, characterized. that the insulating body (3) is wider at its inner and outer radius than at the middle Radius that he continues at the outer radius behind the inner surface of the on low Potential located part (2) is drawn in that it has an in the insulator retracted, with the part (1) carrying the high voltage electrically connected cast-in fitting (4) and that the insulating body on both sides at the inner radius is comprised of shielding electrodes (5,6) arranged at a distance, so that the insulating body with its edges in the through the pouring fitting and the shielding electrodes on both sides formed recess (7) engages. 2. Insulating arrangement according to claim 1, characterized in that the part (2) at low potential is rounded towards the insulating body (3) is. 3. Isolation arrangement according to claim 2, characterized gekennzeicznet that the contour (31) of the insulating body extending outward from the central radius (3) approximately perpendicular to the Side wall of the recess into which the insulating body (3) is drawn in at the outer radius, tapers. 4. Isolation arrangement according to the response 1 to 3, characterized in that that the insulating body (3) is surrounded by a ring fitting (9) into which the insulating body protrudes. 5. Isolation arrangement according to claim 4, characterized in that the Ring fitting (9) by means of a screw connection (25) each with two opposite one another Flanges of the except encapsulation is firmly connected. 6. insulating arrangement according to claim 5, characterized in that the Screw connection (25) a screw bolt screwed into the ring fitting (9) (25a), which with nuts (25b, c) on both sides with flanges (23,24) is tensioned, so that after removal of the nut (25b resp. 25c) the other, together with the screw bolt, the ring fitting and holds the insulating body (3). 1 7. Isolation arrangement according to one or more of claims 1 to 5, characterized in that the thickness of the insulating body is equal to or smaller is than the thickness of the ring fitting. 8. insulating arrangement according to claim 1 to 6, characterized in that that between the outer edge of the insulating body and the inner surface of the ring fitting a gap is provided.