DE4104922A1 - Metal clad gas-insulated HV switchgear with dielectric barrier - has supports for axial conductor protected against particulate attack by alternate plates on conductor and cladding - Google Patents

Abstract

A conductor (2) extends along the axis of the cylindrical metallic cladding (1) between insulating supports (3). Particles (4) of swarf left on the internal surface after mfr. are drawn by the effect of the radial electric field (Eo) towards the surfaces (6) of the supports (3) at which a risk of partial discharge arises. To overcome this, a barrier (7) is set up in the form of a labyrinth seal of parallel insulating plates (8) in radial planes. ADVANTAGE - All dielectrically highly-stressed points are protected with greater safety against impact of electrically conductive particles in the insulating gas.

Description

The invention is based on a metal-enclosed gas-insulated high-voltage system with one arranged in the metal encapsulation high-voltage conductor, one on the conductor attached and to the potential of metal encapsulation guided insulator and with the insulator and / or a dielectric gas line subject to high stress electrically conductive particle protective device.

STATE OF THE ART

The invention relates to a prior art, as it results, for example, from US-A-43 35 268. In this patent publication is a High-voltage line trained, metal-encapsulated gas-insulated high-voltage system described in the Inside the metal encapsulation filled with insulating gas Has openings provided electrode. This electrode has the task of capturing electrically conductive particles, which in the metal encapsulation due to the strong electrical field and a flow of insulating gas  can hike. The particles can thus in the Metal encapsulation and one high-voltage conductor supporting insulators be kept away, causing insulation faults on the dielectrically highly stressed insulators can be avoided can. The isolators from the harmful particles protective electrode must be in places of the high-voltage system be attached to the original electrical Field distribution is not adversely affected. By flowing insulating gas can then still possibly unwanted particles are led to the insulators.

SUMMARY OF THE INVENTION

The invention has for its object a metal-encapsulated gas-insulated high-voltage system from Specify the type mentioned, in which all dielectric highly stressed areas of insulation with large Protection against the deposit of electrically conductive particles are protected.

The advantage of the invention can be seen in particular in that both dielectric high stress insulating gas lines as well as dielectrically highly stressed insulators suitably designed and arranged barriers dielectric material before unwanted entry harmful particles are protected. Through the dielectric field distribution and therefore also that Isolation system not negative due to field displacement effects influencing barriers ensures that even with strong insulating gas flows, such as in  Switching can occur, the migration of the electrically conductive particles on insulation technology non-critical insulating gas areas remains limited and at the same time, however, an appropriate influencing of Insulating gas flow is guaranteed. This is from particularly advantageous for systems in which Circuit breakers are located because of their burn-up Metal particles contaminate exhaust gases into one can significantly weaken the insulation system.

Embodiments of the invention and the achievable therewith Advantages are explained in more detail below with the aid of drawings explained.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the invention are shown in the drawing represented schematically, namely:

Fig. 1 is a plan view of a section along the cylinder axis out of electrically conductive by an embodied as a cylindrical conduit portion of a first embodiment of the invention having formed as a labyrinth seal made of insulating protection device for influencing particles;

Fig. 2 is a plan view of a section along the cylinder axis out of a second embodiment of the invention, with a designed as Isolierstoffschirm protection device for influencing electrically conductive by an executed as a cylindrical portion switching particles; and

Fig. 3 a section through a cell of an insulating foam used in and consisting of foamed plastic one of the embodiments of FIGS. 1 or 2 in the protective device.

WAYS OF CARRYING OUT THE INVENTION

FIG. 12 shows a part of a gas-insulated metal-encapsulated high-voltage system which is designed as a cylindrical line. In this case, the cylindrical metal encapsulation, which is at earth potential and is designated by the reference symbol 1, is filled with an insulating gas, such as in particular SF ₆ , of a few bar pressure. In the interior of the metal encapsulation 1 , an axially extending current conductor 2 is arranged on its cylinder axis. This current conductor is supported on insulators which preferably provide insulation gas insulation, of which only one insulator 3 is shown. Production-related particles 4 of electrically conductive material, such as metal chips, located on the inner surface of the metal encapsulation 1 are in such a high-voltage system under the action of an electrical field E ₀ built up between the high-voltage current conductor 2 and the grounded metal encapsulation 1 along a trajectory 5 shown in dotted lines performed and would, after striking the insulator 3, reduce its dielectric properties and thus also its insulation capacity during operation of the system. This could lead to undesired partial discharges and possibly even to failure of the insulator 3 , such as its end face 6 exposed to the incident particles 4 , under high dielectric stress. This is prevented by arranging a protective device designed as a barrier 7 between the region of the high-voltage system forming the electrically conductive particles 4 and the insulator 3 . The barrier 7 consists of insulating material with a dielectric constant which is comparatively small compared to the material of the insulator 3 and prevents migrating particles 4 from reaching the insulator 3 .

In the embodiment according to FIG. 1, this is achieved in that the barrier 7 is designed as a labyrinth seal. The labyrinth seal contains at least two along the cylinder axis of the metal enclosure 1 of spaced apart, parallel arranged Isolierstoffscheiben 8, which are mounted alternately on the metal enclosure 1 and the current conductor. 2 When attached to the metal encapsulation 1 , they each leave an annular gap 9 formed by the current conductor 2 and its inner lateral surface. When attached to the current conductor 2 , however, they each leave an annular gap 10 formed by the metal encapsulation 1 and its outer circumferential surface. The barrier 7 acts on the electrically conductive particles 4 as a labyrinth seal, since it is avoided with great certainty that the particles 4 reach the insulator 3 to be protected. On the other hand, the barrier 7 enables the exchange of insulating gas via the columns 9 and 10 and the spaces formed by the distances between the insulating material disks 8 . At the same time, it is ensured that between the insulating material disks 8 and the metal encapsulation 1, which is at earth potential, or the current conductor 2, which is at high voltage potential, there is a gas path which has a dielectric definition.

In the embodiment shown in FIG. 2, 1 again designates an essentially cylindrical metal encapsulation filled with SF ₆ of a few bar pressure. The metal encapsulation 1 has an opening 11 through which an insulator designed as a switching rod 12 is passed in a gas-tight manner to a drive 13 arranged outside the metal encapsulation 1 . The switching rod 12 acts on a movable contact, not shown, which is surrounded by a fixed electrode 14 which is at high voltage potential and which is in the form of a circuit breaker. The electrode 14 is of essentially cylindrical symmetry. Metal encapsulation 1 , electrode 14 and switching rod 12 are arranged coaxially. An essentially funnel-shaped insulating shield 15 is also arranged coaxially with these parts. This insulating screen 15 is fastened to a part 16 of the electrode 14 which is not designated and surrounds at least part of the switching rod 12 in a funnel shape. This ensures that the gases formed in the circuit breaker during a switching operation and containing metallic impurities do not flow around the switching rod 12 . If these gases are exhausted at openings 17 from the extinguishing chamber of the switch in the direction of the arrows shown in FIG. 2, the insulating screen 15 acts as a barrier 7 for the contaminated exhaust gases and guides them with its outer surface predominantly radially outward, as a result of which in the axial direction Directionally highly stressed shift rod 12 is largely spared from the accumulation of harmful particles 4 .

Instead of a dielectrically highly stressed insulator, such as the insulator 3 or the switching rod 12 , a dielectrically highly stressed insulating gas path can be protected in a corresponding manner, since the barrier 7 prevents the access of the harmful particles 4 to the insulating gas path.

In order to avoid effects of the barriers 7 on the original electrical field distribution, the insulating material of the barriers 7 should have a dielectric constant ε _r , which goes as far as possible against 1. A particularly suitable material is therefore foamed plastic, such as. B. a rigid foam based on polyurethane, cross-linked polyethylene, polyvinyl chloride, polystyrene, silicone or epoxy. SF ₆ · CO ₂ and / or Freon are particularly suitable as propellant gases.

In addition to the plastic itself, the dielectric strength and the ε _r behavior of the foamed material are determined both by the propellant gas used for foaming and by the size of the foam cells. The dielectric strength of the material used is ensured if, in the case of a spherical foam cell shown in FIG. 3 with a diameter D and a background field strength E ₀ , which corresponds to the electrical field strength prevailing in the encapsulation, the minimum ignition voltage U _min corresponding to the Paschen curve of the filling gas enclosed in the cell is not exceeded. With ε _rM as the dielectric constant of the pure plastic used for the matrix and E _z as excessive field strength in the spherical foam cell, the condition applies to such an advantageous material

E _z D = [3ε _rM / (2ε _rM + 1)] E ₀ D <U _min .

This gives an estimate of the size of the Diameter D the inequality

D <(U _min / E ₀ ) [(2ε _rM + 1) / 3ε _rM ]

For a z. B. with SF₆ foamed polyethylene foam

(ε _rM = 2.3, U _min = 500 V)

results in a Background field strengths E₀ = 300 kV / cm a cell diameter

D <13 µm,

for a particularly safe dielectric operation of the Foam and thus also the high-voltage system after the Invention is guaranteed in one of such Foam-made barrier is used.  

Label list

1 metal encapsulation
2 conductors
3 isolator
4 particles
5 trajectory
6 end face
7 flow barrier
8 insulating washers
9, 10 column
11 opening
12 shift rod
13 drive
14 electrode
15 insulating screen
16 part of the electrode 14
17 openings

Claims (10)

1. Metal-enclosed gas-insulated high-voltage installation arranged with one in the metal enclosure (1), high-voltage-carrying conductor (2), a fixed (2) to the current conductor and the potential of the metal encapsulation performed insulator (1) (3) and with at least one said insulator (3 ) and / or a dielectric gas line which is subjected to high dielectric stress to protect against electrically conductive particles ( 4 ), characterized in that the at least one protective device is designed as a barrier ( 7 ) made of dielectric material with a relatively low dielectric constant compared to the insulator ( 3 ) and between an electrically conductive particles ( 4 ) leading area of the high-voltage system and the insulator ( 3 ) and / or the insulating gas section is arranged. 2. High-voltage system according to claim 1, characterized in that the barrier ( 7 ) is designed as a labyrinth seal. 3. High-voltage system according to claim 2, characterized in that the labyrinth seal is arranged in a cylindrical part of the metal encapsulation ( 1 ) and contains at least two mutually parallel, spaced-apart insulating material disks ( 8 ) which alternately on the metal encapsulation ( 1 ) and the current conductor ( 2 ) are attached. 4. High-voltage system according to claim 3, characterized in that the insulating washers ( 8 ) when attached to the metal encapsulation ( 1 ) each have a gap ( 9 ) between them and the conductor ( 2 ) and when attached to the conductor ( 2 ) each have a gap ( 10 ) leave between themselves and the metal encapsulation ( 1 ). 5. High-voltage system according to claim 1, characterized in that the barrier ( 7 ) is designed as an insulating screen ( 15 ). 6. High-voltage system according to claim 5, characterized in that the insulating screen ( 15 ) surrounds at least part of an insulator designed as a switching rod ( 12 ) in a funnel shape. 7. High-voltage system according to claim 6, characterized in that the insulating screen ( 15 ) is attached to an electrode ( 14 ) located at the potential of the current conductor ( 2 ) and with its outer surface the electrically conductive particles formed in a region of the high-voltage system designed as a switching point ( 4 ) from the shift rod ( 12 ). 8. High-voltage system according to one of claims 1 to 7, characterized in that the dielectric material of the barrier ( 7 ) is a foamed plastic. 9. High-voltage system according to claim 8, characterized in that the foamed plastic is a rigid foam based on polyurethane, cross-linked polyethylene, polyvinyl chloride, polystyrene, silicone and / or epoxy, and that SF ₆ , CO ₂ and / or freon is used as the propellant gas . 10. High-voltage system according to claim 9, characterized in that the diameter (D) of spherically foamed cells of the rigid foam satisfies the following inequality D <(U _min / E ₀ ) [(2ε _rM + 1) / 3ε _rM ], wherein
U _min = the minimum ignition voltage of the Paschen curve of the filling gas,
E₀ = the electrical background field strength at the location of the cells, and
ε _rM = the dielectric constant of the base plastic.