DE3216275A1 - Arrangement for the protection of gas-insulated, encapsulated switching installations - Google Patents

Abstract

In interrupter switching operations in gas-insulated encapsulated high-voltage switching installations (GIS) radio-frequency voltage travelling waves occur in parts (K) of the switching installation (GIS), as a result of arc ignition, which cause critical transient excess voltages. By fitting thin, poorly conductive coatings (B) having high magnetic permeability ( mu @) onto the surfaces (I, A) which guide the voltage travelling waves in the switching installation, it is possible significantly to reduce the amplitude of the transient excess voltages. <IMAGE>

Description

Arrangement for the protection of gas-insulated,

encapsulated switchgear The invention relates to an object according to the preamble of claim 1.

The article "Overvoltages in GIS caused by the operation of isolators" Proc. Symp. Surges in HV-Networks, Baden (1979), Book: Plenum, New York (1980), p, 115-128 describes the causes of the high-frequency voltage traveling waves that occur. Such switchgear assemblies usually have circuit breakers in addition to disconnectors. Disconnectors and circuit breakers are in series between two parts of an electrical system Power supply network, e.g. between a generator and a busbar or between a busbar and an overland line.

To separate such parts of the system, the usual procedure is always to go first the circuit breaker, then the disconnector open. The reverse is true for the connection of the two parts of the system, the isolator is closed first, then the circuit breaker. The circuit breaker is always open during the disconnection operations.

The isolator switching operations ignite during opening or If the isolator closes several times, a spark across the switching path of the isolator. The voltage across the switching path breaks in each case around the time it is being set up of the spark channel, which is only a few nsec. Because of the voltage breakdowns voltage wandering waves arise with a rise time that is also about the build-up time of the spark channel. The voltage traveling waves propagate from the divider in the often branched switchgear that is responsible for the voltage traveling waves has excellent transmission properties, since those enclosed by the encapsulation Head of the switchgear in cooperation with this very encapsulation practically no attenuation form coaxial lines.

In the following the propagation of the stress traveling waves is along the connecting cable between the disconnector and the circuit breaker, or coaxial cable for short called, considered more closely.

Upon reaching the open end of this coaxial line at the circuit breaker, the voltage traveling waves are reflected and run back to the isolator. is the switching path at the isolator is still bridged with the low-resistance arc, see above the voltage traveling waves can partially pass the isolator. The complementary one Part of the voltage traveling waves is due to the discontinuity between the wave resistance the coaxial line and the wave resistance of the system part beyond the isolator reflected. There are standing waves on the coaxial line with a Resonance frequency resulting from the phase velocity of the voltage traveling waves on the coaxial line divided by four times its length. The phase velocity gas-insulated coaxial lines is just below the speed of light. With a typical length of the coaxial line of 15 m, the result is a ty- pical resonance frequency of about 5 MHz.

The maximum amplitude of the voltage traveling waves results from the Ends of the coaxial line and can be twice as large as the amplitude of the Be operating voltage.

It is true that the amplitude of the voltage traveling waves fades through over time the incomplete reflection on the separator; nevertheless, they are burdened with the tension wandering waves connected overvoltages on the one hand the components of the switchgear and lead on the other hand, too high transient contact voltages on the outside of the enclosure. Interference can also occur in the vicinity of installed measurement or control lines and thereby to a lasting impairment of the operational management of the switchgear come.

To reduce the critical overvoltages, it has already been proposed (9th publication mentioned at the beginning, p. 129, 3rd paragraph from the bottom) the voltage traveling waves to attenuate by ohmic series resistors or surge arresters, for this one However, ohmic resistors suitable for the purpose are particularly suitable for installation in the coaxial line too large and also have the disadvantage that additional Switching means must be provided in order to avoid the operating current in the same way to dampen.

The use of surge arresters is very complex and different from an economic point of view.

The object of the invention is therefore in particular to find a new way to effective reduction of critical overvoltages in gas-insulated, encapsulated To show switchgear.

According to the invention, this object is achieved by the elements of the characterizing part of the main claim solved.

Expedient configurations of these features contain the dependent ones Claims.

The advantages and further features of the invention emerge from The exemplary embodiment explained below with reference to the drawings.

It shows: FIG. 1 a schematic diagram of a known, gas-insulated, encapsulated switchgear and FIG. 2 shows a section of the coaxial line of the switchgear according to Fig. 1 with the coverings according to the invention.

In both figures, the same parts are denoted by the same symbols.

Fig. 1 shows the gas-insulated encapsulated switchgear (GIS) with the Disconnector T and the circuit breaker S. The disconnector T and the circuit breaker S are connected to one another via the inner conductor I of the coaxial line K, while the outer conductor A of the coaxial line K through the metallic encapsulation the gas-insulated switchgear GIS, which also includes the disconnector T and the circuit breaker S includes. With G is the electrically insulating gas-filled space between the inner conductor I and the outer conductor A.

Fig. 2 shows a portion of the coaxial line K in enlarged Scale compared to FIG. 1 with the coverings B according to the invention, which in this example both on the outside of the inner conductor I and on the inside of the outer conductor A are applied. With d and D in Fig. 2 is the diameter of the inner conductor I and the outer conductor A and with s the thickness of the coverings B.

This thickness s of the coverings B is dimensioned in such a way that it together the gas-filled space G between the inner conductor I and the outer conductor A not affected.

The invention takes advantage of the fact that those with voltage traveling waves associated high-frequency currents in electrically conductive surfaces less deep penetrate as low-frequency, e.g. operating-frequency currents. For frequencies of 5 MHz and 50 Hz, the depths of penetration differ by a factor of about 300. The The surfaces relevant for wave propagation are in the case of the coaxial line K the outside of the inner conductor I and the inside of the outer conductor A. The Currents associated with wave propagation in the inner conductor I and in the outer conductor A therefore flow to a larger one with the high-frequency voltage traveling waves Part in that applied to the inner conductor I and the outer conductor A according to the invention Deposits B. The high-frequency currents are therefore advantageously selective dampened in the poorly electrically conductive coverings B.

The damping becomes particularly effective and selective if the thickness s of the coverings B in meters according to the relationship is dimensioned, where e is the relevant length of the switchgear for the formation of the standing waves in meters, d is the electrical conductivity in Siemens / meter and Pr is the relative magnetic permeability of the coverings and further the two last-mentioned quantities by the relationship are linked. The diameters d and D as well as the length should also be entered in meters. Since the length e of the switchgear which is relevant for the formation of the standing waves is the length of the coaxial line K between the isolator T and the circuit breaker S in this exemplary embodiment.

Because the amplitude of the high-frequency voltage waves at all Discontinuities of the wave resistance along the coaxial line K in particular So is particularly large at their ends, the pads B are preferably in the Surrounding these discontinuities applied. A complete assignment of the coaxial Line K with pads B may then be superfluous under certain circumstances.

Iron powder, for example, is a suitable material for coverings B. a grain size between 1/50 to 1/1000 mm in question, which in an electrical poorly conductive binder is embedded. Synthetic resin can be used as a binder which may be due to a small admixture of an electrical conductor, e.g. graphite, can be made weakly conductive.

On the other hand, the coverings can also consist of a weakly conductive one Ferrite.

With such materials, e.g. at 5 MHz, relative magnetic Achieve permeabilities of ur = 100.

From equation (2) then follows for the electrical conductivity a typical length e = 15 m, typical diameters d = 0.2 m and D = 0.6 m of the coaxial line K has a value of 6 = 50 S / m. This is calculated using the equation (1) a thickness s of the coverings B of 5 mm. The coverings B of this small thickness are s so easily to apply to the inner conductor I and the outer conductor A, without the insulating gas-filled gap G to impair.

With coverings B dimensioned in this way, the amplitude of the stress traveling waves at the open end of the coaxial line with the typical dimensions chosen, i.e. at the circuit breaker, where it reaches the highest value, at 5 MHz can be reduced by a factor of 5. At 35 MHz, a frequency as e.g. occurs in the steep front of the voltage traveling wave, the amplitude can even can be attenuated by a factor of 80.

L e r s e i t e

Claims (7)

Claims arrangement for the protection of gas-insulated, encapsulated Switchgear against high-frequency voltage traveling waves, characterized in that that at least some of the system elements (K) with a covering (B) for damping of the stress traveling waves is provided, which in comparison with the elements of the Switchgear (I, A) for the high-frequency voltage traveling waves a lower one Has electrical conductivity and a higher magnetic permeability. 2. Arrangement according to claim 1, characterized in that the environment of discontinuities (T, S) of the wave resistance in the switchgear with the covering (B) is provided. 3. Arrangement according to one of claims 1 or 2, characterized in that that the outside of at least part of the inner, enclosed by the encapsulation Head (I) and / or the inside of at least part of the outer, the encapsulation forming conductor (A) of the switchgear is provided with the covering (B). 4. Arrangement according to one of claims 1 to 3, characterized in that the thickness s of the covering (B) in meters according to the relationship is dimensioned, where e is the relevant length of the switchgear for the formation of standing waves in meters, d is the electrical conductivity in Siemens / meter and Yr is the relative magnetic permeability of the covering (B). 5. Arrangement according to one of claims 1 to 4, characterized in that the electrical conductivity d in Siemens / meter and the relative magnetic permeability of the covering (B) by the relationship are linked, where d is the outer diameter of the inner conductor enclosed by the encapsulation (I) in meters, D is the inner diameter of the outer conductor (A) forming the encapsulation in meters and e is the length in meters that is relevant for the formation of standing waves. 6. Device according to one of claims 1 to 5, characterized in that that the coverings (B) are made of iron powder with a grain size between 1/50 and 1/1000 mm, with the iron powder embedded in a weakly conductive binder is. 7. Device according to one of claims 1 to 5, characterized in that that the linings (B) are made of weakly conductive ferrite.