DE3541440A1 - Overvoltage protection cage for a housing lead-in of a high-voltage cable - Google Patents

Abstract

The invention relates to an overvoltage protection cage for a housing lead-in of a high-voltage cable, which cage is formed by a plurality of copper bars (61), which run perpendicularly with respect to the housing and are connected on the one hand to the housing, on the other hand to the dividing tube of the cable. It achieves the object of designing the protection cage in such a way that, on the one hand, direct-axis currents are suppressed and cathodic corrosion protection is possible and, on the other hand, the separating point between housing and dividing tube is protected and damage to electronic power line protection systems is avoided. The way in which the object is achieved is essentially that each copper bar (61) of the cage has a step-shaped interruption, and this is bridged by a plate-shaped metal-oxide varistor (63), the electrodes of which are given surface contact by metal plates (64). <IMAGE>

Description

The invention relates to an overvoltage protective cage Housing entry of a high-voltage cable of at least three copper bars are formed, which are essentially run perpendicular to the housing base plate and at its ends in elbows for connection to the housing or the distribution tube of the cable.

To suppress longitudinal sheath currents in pressure cable systems and secondly to give the operators the opportunity The cathode will protect the pressure pipes against corrosion Dividing head of a system is divided in isolation and is divided into each a pressure cable surrounding copper distribution pipe below the End closure base plate an insulating piece installed as a separation point. The isolated installation of a three-wire cable Pressure cable termination system is for example in DE-GM 68 10 534.

Since, especially in SF ₆ -insulated high-voltage switchgear, circuit breaker or isolator movements stimulate transient processes with steep wave fronts, which can result in considerable transient overvoltages across the isolating points, protective spark gaps are installed in parallel to the isolating pieces to avoid flashover hazards. In many pressure cable systems, conversion transformers 5 are mounted below the insulating pieces, which are connected to electronic network protection systems via auxiliary lines.

In some systems, the disconnection points are made up of four copper bars existing "baskets" have been bridged by the operator, to such faults in electronic network protection systems to avoid responding to the protective spark gaps to be led back. The operator thus takes longitudinal sheath currents and no active (cathodic) corrosion protection the pressure pipes in purchase.

Since gas pipelines are increasingly cathodic in the utilities are operated in a protected manner, and often in parallel to cathode cable systems Corrosion protection of the pressure pipes of the cables are introduced. Further details can be found in AfK Recommendation No. 8, March 1983 (Arbeitsgemeinschaft DVGW / VDE for corrosion issues recommendation "Cathodic Corrosion protection for steel pipes of high voltage cables ") specified. To do this, however, the galvanic connections between the cable dividing pipes and the earthed termination Base plates (the "baskets") are interrupted.

The invention is therefore based on the object instead of Protective device "spark gap" an alternative protective device to develop with which, on the one hand, longitudinal sheath currents largely suppressed and the cells for cathodic corrosion protection be kept functional, on the other hand the Separation points protected from flashovers and damage electronic Network protection systems can be avoided.

The solution to this problem is with a generic overvoltage Protection cage by the characterizing features of the claim 1 specified. It essentially consists in the fact that each copper bar of the basket has a step-like interruption that through a plate-shaped metal oxide varistor, whose electrodes are contacted by metal plates, is bridged.  The voltage-dependent resistors, especially metal oxide Varistors, provide spark gaps or valve arresters especially for continuous degradation transient Surges, with the response delay also compared Stress waves with steep wave fronts are avoided. In addition results in the surface contacting of the varistor electrodes compared to the usual wire or band-shaped contact less reflections and less travel time losses of the traveling waves and thus lower transient overvoltages.

Further designs of the surge protection cage according to the invention are specified in the subclaims, of which the claims 2 and 3 a varistor bridge with one of a sealant enclosed varistor, 4 a varistor bridge with an encapsulated varistor, and 5 the Concern copper bars of the basket.

The advantages achieved with the invention are in particular in that by the structurally simple installation of Varistors in the baskets it is possible, on the one hand, the pressure pipes to protect cathodically and on the other hand the separation points against flashovers to protect and damage electronic network protection systems to avoid. Due to the flat installation of the varistors enter the baskets at the beginning of a transient process noticeably lower peak values of the voltage at the separation points on, and in the further course of the transient process the Varistors for a much faster breakdown of the transients Surges.

Two embodiments of the invention are in the drawing are shown and are described in more detail below. Show it

Fig. 1 in longitudinal section the housing introduction of a high voltage cable, more precisely the point of separation of a Aufteilrohres of a pressure cable which is bridged by a surge protection cage with metal oxide varistors,

Fig. 2 in longitudinal section the Varistorbrücke in a basket with a rail enclosed by a sealing compound varistor,

Fig. 3 in an oblique view a plate-shaped metal oxide varistor and

Fig. 4 in longitudinal section the varistor bridge with an encapsulated varistor.

• Are labeled with 1 cable entry part of an SF ₆ -insulated switchgear
  2 end closure base plate (housing base plate)
  3 Isolating piece as a separation point between the distribution pipe and the system housing
  4 Copper splitting tube
  5 conversion transformers
  6 Surge protection cage
  61 copper bars of the basket
  62 angles at the rail ends
  63 metal oxide varistor (ZnO varistor)
  64 copper plates
  65 screw connections
  66 insulating pieces
  67 Sealing made of silicone compound
  7 metal oxide varistor in the housing
  71 sintered metal oxide plate
  72 electrodes of the varistor
  73 Housing cylinder wall made of porcelain or cast resin
  74 Housing end walls made of metal
  75 studs on one end wall.

Figs. 1 shows above the cable insertion portion 1 of an SF ₆ - insulated switchgear, the insulator of the cable termination is surrounded by the housing wall of the plant with distance. The cable end closure is fastened to the system housing via the end closure base plate 2 , which is grounded. The pressure cable surrounded by the distribution tube 4 made of copper is inserted from below through the cable end closure into the switchgear housing. For the galvanic separation of the distribution tube 4 from the base plate 2 , the insulating piece 3 is installed between the two. The conversion transformer 5 is mounted below the insulating piece, from which a line leads to an electronic network protection system.

The insulating piece 3 and the conversion transformer 5 are bridged by the overvoltage protection cage 6 , which is formed by four copper rails 61 which are at right angles to one another and run perpendicular to the end closure base plate 2 (and thus the housing base plate) and merge into elbows at their ends , which are connected on the one hand to the base plate 2 and on the other hand to the distribution tube 4 of the cable.

As shown in Fig. 2 and 4 show, each copper bar 61 has a step-shaped interruption which is preferably bridged by a plate-shaped voltage-dependent resistor 63, by a metal oxide varistor. Here, the two rail ends face each other by 1 to 3 times the length of the varistor, the varistor is arranged therebetween - with electrodes reinforced by the two metal plates 64 or 74 - and each rail end is connected to the plates by one or two screw connections 65 the varistor housing or the other rail end. Such varistors are used which, on the one hand, are so high-resistance at the distribution tube voltages of the quasi-stationary network operation that cathodic protection against corrosion is guaranteed, and on the other hand become sufficiently low-resistance in the case of transient overvoltages. In addition, they must have sufficient energy absorption capacity. Metal oxide (ZnO) varistors have the most advantageous properties. Fig. 3 shows a plate-shaped, rectangular metal oxide varistor 63, the plate 71 consists of sintered zinc oxide grains with admixtures of other metal oxides, and which is provided on both sides also with plate-shaped electrodes 72.

Fig. 2 shows a Varistorbrücke with a space enclosed by a sealant 67 varistor 63rd The two electrodes 72 of the metal oxide plate 71 of the varistor are contacted and reinforced by copper plates 64 , the narrow sides of the varistor are enclosed by the seal 67 made of silicone compound, and each rail end is screwed to the other rail end by two screw connections 65 . These are arranged next to two of the narrow sides of the varistor, insulated from the copper bars 61 by insulating pieces 66 . The copper plates 64 laterally protrude the varistor 63 by about 10% and they have bevelled edges between which the sealing compound 67 is introduced.

In contrast, Fig. 4 shows a Varistorbrücke with an encapsulated in a cylindrical housing varistor. 7 The two electrodes of the varistor are in surface contact with the two metal housing end walls 74 , the narrow sides of the varistor are surrounded by the housing cylinder wall 73 made of porcelain or cast resin, and each housing end wall 74 is on the opposite end of the copper bar 61 by means of of a stud 75 screwed.

Finally, a few comments on the surge protective cage 6 formed from the copper bars 61 :

When using the protective cage according to the invention, calculation and experiment have shown that the peak value of the voltage at the separation point 3 decreases with an increasing number of copper bars. This is due to the fact that the resulting wave impedance of the basket decreases. The basket is preferably formed from four copper bars with built-in varistors.

It has also emerged that baskets consist of 0.5 m long rails have smaller peak values of the voltage at the separation point, than 2 m long baskets, and that the smallest possible basket length is to be aimed for. A practically achievable and preferred value is 0.5 m.

And finally it turned out that the installation location of the varistors within the basket rails 61 has practically no meaning.

Claims (5)

1. Overvoltage protective cage for a housing entry of a high-voltage cable, which is formed by at least three copper bars ( 61 ) which run essentially perpendicular to the housing base plate and at their ends in angle pieces ( 62 ) for connection to the housing or the distribution pipe of the Pass over cable, characterized in that each copper bar ( 61 ) has a step-shaped interruption, which is bridged by a plate-shaped voltage-dependent resistor ( 63 ), preferably by a metal oxide varistor, whereby
the two rail ends face each other by 1 to 3 times the length of the varistor,
- The varistor with electrodes reinforced by metal plates ( 64, 74 ) is arranged in between, and
- Each rail end is screwed to the plates of the varistor housing or the other rail end with one or two screw connections ( 65 ). 2. Overvoltage protection cage according to claim 1, characterized in that with a varistor ( 63 ) enclosed by a sealing compound ( 67 )
- The two electrodes ( 72 ) of the metal oxide plate ( 71 ) of the varistor are contacted and reinforced flat by copper plates ( 64 ),
- The narrow sides of the varistor are enclosed by the seal ( 67 ) made of silicone compound, and
- Each rail end is screwed to the other rail end by two screw connections ( 65 ) which are arranged next to two of the narrow sides of the varistor, insulated from the copper rails ( 61 ) by insulating pieces ( 66 ). 3. Overvoltage protection cage according to claim 2, characterized in that the copper plates ( 64 ) laterally protrude the varistor ( 63 ) by about 10% and they have beveled edges between which the sealing compound ( 67 ) is introduced. 4. Overvoltage protection cage according to claim 1, characterized in that in a varistor encapsulated in a cylindrical housing ( 7 )
- The two electrodes of the varistor are in flat contact with the two metal housing end walls ( 74 ),
- The narrow sides of the varistor are surrounded by the housing cylinder wall ( 73 ) made of porcelain or cast resin, and
- Each housing end wall ( 74 ) is screwed onto the opposite end of the copper bar ( 61 ) by means of a stud bolt ( 75 ). 5. Overvoltage protective cage according to one of claims 1 to 4, characterized in that the protective cage ( 6 ) is formed by four copper bars ( 61 ) which are between 0.3 and 1.5 m, preferably 0.5 m, long .