DE2259058A1 - METAL ENCLOSED, COMPRESSED GAS INSULATED HIGH VOLTAGE SWITCHGEAR - Google Patents

Description

Metal-encapsulated, pressurized gas-insulated high-voltage system Off the "Siemens-Zeitschrift", issue 4, April 1966 is a metal-enclosed, pressurized gas-insulated High-voltage switchgear for 110 kV known for connection to three-pole Busbar systems is intended. In the known plant it was considered to be gaseous Isolation agent chosen sulfur hexafluoride, which is under a pressure of, for example 2 bar. The housing of the individual devices that form the metal encapsulation is earthed and are connected to one another via flanges.

In the known target position, as in a high-voltage switchgear According to DT-OS 1 665 661 three-pole busbars are provided to which the individual Devices are connected in a single-pole encapsulated design. Accordingly contains each system field three pole-specific encapsulation trains, which have a vöm insulating distance between the high-voltage parts and the Kietallkapselung and the Maintenance of the encapsulation necessary space to ate certain space requirements.

To reduce the footprint and reduce the cost of the Equipment, in particular to achieve the smallest possible dimensions of the devices and conductor housing while maintaining one for electrical insulation The invention consists of a necessary distance between the high-voltage parts a metal-enclosed, compressed gas-insulated high-voltage switchgear for three-phase current with system fields consisting of encapsulated devices for connection to at least a three-pole encapsulated busbar in that the devices of a field are three-pole encapsulated and in one to the busbar arranged in the vertical plane are the one of the three poles and its high voltage carrying parts of all devices contains, and that on both sides of this field plane the other two poles and their High-voltage parts of the devices are symmetrically separated from each other are.

The application of the invention results in a comparison with the known high-voltage switchgear, reduced space requirements and significant material savings in the encapsulation and advantageous possibilities for at least approximately complete RJerksn-ontage. Each field of the high-voltage switchgear according to the invention is determined by a central level running right to the busbar, which at the same time forms the middle plane of one of the three poles, which of the two other poles is not cut.

A particularly favorable spatial distribution and the lowest possible Dimensions of the encapsulation of the individual devices can be achieved if the three Poles and the high-voltage parts of all devices in one transverse to the field level running cut arranged on the corners of imaginary equilateral triangles are. These can be of different sizes for different devices, then are but similar triangles.

The parts carrying high voltage can preferably be post insulators be worn, which are designed with two arms and opposite each other in two places the encapsulation.

This puts the high voltage parts practically in the middle of the isolators held so that these only with the phase voltage, not with the chained voltage. In addition, only one creepage distance can be advantageous train against earth.

In a preferred embodiment, the field plane is vertical oriented.

In a preferred exemplary embodiment, the system is encapsulated according to the invention of substantially cylindrical housing parts, the longitudinal axes of which lie in the field level. This means that the central field level is also the middle level for everyone Housing parts.

The drawing shows an embodiment of a metal-encapsulated, Compressed gas insulated high-voltage switchgear for three-phase current according to the invention.

Figures 1 to 3 show a high-voltage switchgear in elevation, plan and side elevation according to the invention in a schematic ear position.

In Fig. 4 is a high-voltage switchgear according to the invention for Connection to a busbar shown schematically.

FIG. 5 shows a high-voltage switchgear for a triple busbar system.

In Fig. 6 is a coupling field of a high-voltage switchgear (busbar cross coupling) drawn schematically according to the invention for a double busbar system.

FIG. 7 shows a coupling field of a high-voltage switchgear for a triple busbar system.

In Fig. 1 is a metal-enclosed, compressed gas-insulated high voltage switchgear for three-phase current with a voltage of 110 kV, for example shown, the system field of which consists of encapsulated devices and for connection on two three-pole encapsulated busbars 1 and 2. The three-pole Encapsulated busbars 1 and 2 have a metal enclosure 3, which is at Brdpotential lies and the three ladder R, S, T are preferably more uniform Post insulators 4 holds. Tm interior 5 is filled with sulfur hexafluoride is under a pressure of, for example, 2 to 3 bar.

The isolators 4 are supported on two sides opposite the encapsulation 3 from. The collecting rails 1 and 2 have flange parts 6 with which they are with the Plant field are connected.

The flange parts 6 are joined by two three-pole, similar ones encapsulated disconnector 7 by a three-pole encapsulated coupling piece 8 are connected to each other. The coupling piece 8 contains 8a in its encapsulation a grounding switching device 9, the grounding switch pins 10 of which each have their own Have drive 10a. The grounding switch pins 10 and the drives 10a are in one common plane running transversely to the field plane is arranged radially symmetrically.

In the illustrated embodiment, the field level is identical to the plane of the drawing in FIG Coupling piece 8 is followed by a cylindrical coupling housing 11, the three Surrounds the current and / or voltage converter 12, which is assigned to the individual phases fl, S, T are. With the housing 11, a circuit breaker 13 is connected to the three switching points 14 of each phase in a common encapsulation. The drive for the switching points 14 is accommodated in a housing 15.

The housing of the circuit breaker 13 is essentially cylindrical and has a flange part 16 extending transversely to the cylinder axis, with the an isolating and earthing switching device 17 in a three-pole encapsulated design is.

As with the grounding switching device 9 is in the grounding switching device 17a shows a radially symmetrical arrangement of the earthing switch pins and the associated ones Drives provided.

The switching points of the disconnector have a common drive 18. The switching device 17 is connected to a cable outlet device 19, which like all other devices filled with SF6 is. The high tension leading Parts 20, 21 and 22 are guided to bushing bodies 23, which are attached to the end face Plate 24 of the Fabelabgangsgerätes 19 are supported.

In the embodiment of the invention shown in FIG are all devices of one field each in a perpendicular to the axis 25 of the busbar 1, 2 Arranged at field level. All high-voltage parts belonging to phase S. the disconnector 7, the coupling piece 8, the converter housing 11, the circuit breaker 13, the switching device 17 and the cable outlet device 19 are in the field level. On both sides of this field level are the other two phases R and T and theirs High-voltage parts of the devices are symmetrically separated from each other. As can be seen from FIG. 3, the poles and the high-voltage parts are in this case of the devices in a section running transversely to the field level on the corners of a imaginary equilateral triangle arranged.

The system field is supported by supports 26 on the circuit breaker 13 and converter housing 11.

In Figures 2 and 3, the same parts are given the same reference numerals Mistake. The encapsulation of the system consists of essentially cylindrical housing parts, whose longitudinal axes lie in the field plane. The housing of the devices can be on the flange side advantageously partitioned gas-tight with suitable insulating bodies known per se be, so that there are several sub-spaces of the gas insulation.

In Fig. 4 is an elevation of a metal-enclosed, pressurized gas-insulated High-voltage switchgear schematically drawn for connection to a three-pole Busbar 1 is intended. A disconnecting earth switch connects to the busbar 1 7 to the extension of its axis with a current and voltage converter device 11 is connected. With the Converter device 11 is the icistun switch 13 connected in a three-pole encapsulated execution, which in turn transversely to his In the longitudinal direction via an isolating and earthing switchgear 17 with an output device 19 is connected.

Figure 5 shows a slightly different embodiment of a metal-encapsulated, Compressed gas-insulated high-voltage switchgear, with a representation similar to that of In Fig. 1, the device arrangement is made in which the coupling piece 8 is connected to a further busbar 27 via an isolating switchgear 7. Otherwise, the same parts are provided with the same reference numerals.

Figure 6 shows a coupling field for a double busbar system, while FIG. 7 shows a coupling field for a triple busbar assembly (busbar cross-coupling).

All of the representations in FIGS. 4 to 7 have in common that the three-pole encapsulated system parts are arranged in a central plane through the Drawing plane are determined. Here, too, the same parts are given the same reference numerals Mistake.

A major advantage of the design of the system according to the invention results from the fact that by rotating the interconnected encapsulation housing of the circuit breaker 13 and the voltage converter 11 about a transverse to the housing longitudinal axis running axis another application of the field is given without that the spatial dimensions of the system are changed.

7 figures 4 claims

Claims (4)

Patent claims 1 lethally encapsulated, pressurized gas insulated hole voltage switchgear for three-phase current with system fields consisting of encapsulated devices for connection to at least one three-pole encapsulated busbar, characterized in that the devices (7, 8, 9, 11, 13, 17, 19) each of a field three-pole encapsulated and in a to the busbar (1, 2) perpendicular plane are arranged, which one of the three poles (R, S, T) and parts of all devices (7, 8, 9, 11, 13, 17, 19) and that on both sides of this field level the two other poles and parts of the devices (7, 8, 9, 11, 13, 17, 19) are arranged symmetrically separated from one another. 2. High-voltage switchgear according to claim 1p, characterized in that that the three poles (R, S, T) and the high-voltage parts of all devices (7, 8, 9, 11, 13, 17, 19) in a section on the corners running transversely to the field plane equilateral triangles are arranged. 3. High-voltage switchgear according to claim 1 or 2, characterized in that that the field plane is oriented vertically. 4. High-voltage switchgear according to claim 1, characterized in that that the encapsulation of the system consists of essentially cylindrical housing parts, whose longitudinal axes lie in the field plane. Blank page