DE3780921T2 - GAS-INSULATED MULTIPOLE ROTARY SWITCH. - Google Patents

Abstract

Switch comprising, for each pole, a blade-shaped double moving contact (24) cooperating under rotation with a plurality of stationary contacts (14 - 22) in order to occupy a first closing position in which the first and third stationary contacts (14, 18) are interconnected by the blade, a second opening position in which the blade engages with a fourth stationary contact (20), and a third position for earthing the exit cable (28) thanks to the interconnecting of the second and fifth stationary contacts (16, 22) by means of the blade. The second and third stationary contacts (16, 18) are permanently joined together by an electrical connection (32). The same is true for the fourth and fifth stationary contacts (20, 22), thanks to an earth connection. The moving contact (24) is associated with a metal shield (36) advantageously arranged as a guard ring in the second opening position. The presence of this shield ensures an isolating function making it possible to retain the isolation between the input and output terminals (26, 28). Application: electrical panel for a medium-voltage distribution station. <IMAGE>

Description

The invention relates to a gas-insulated multi-pole load-break rotary switch, in particular for a medium-voltage distribution system, in an insulating housing filled with a gas of high dielectric strength, each pole consisting of a movable double contact in the form of a contact blade with three positions, which is attached to an insulating switching shaft and which, when rotated, interacts with several fixed contacts offset at an angle in a plane along the inner wall of the insulating housing, resulting in a first switching position (ON) for establishing the electrical connection between an input terminal with a feed line connected to it and an output terminal with an outgoing line connected to it, a second switching position (OFF) for separating the two conductors and a third switching position (EARTH) for earthing one of the two conductors.

When using an insulating housing to house the SF6 rotary switch, the problem of safe isolation between the input and output terminals arises, given the risk of leakage current along the inner wall of the insulating housing. To prevent any bridging of the isolation gap, two precautions can be taken:

- the creepage distance between the terminals of the switch-disconnector can be increased,

- a mass ring can be integrated into the creepage distance.

Increasing the creepage distance requires correspondingly large dimensions of the cylindrical insulating housing, which is often not compatible with the compact design of the switchgear in which the switch is to be installed.

The integration of a mass ring into a rotary switch leads to layout problems due to the rotary movement of the moving contact. In the closed position, the presence of this protective ring is also superfluous.

EP-A-199.044 describes a rotary load-break switch with an insulating housing and three fixed contacts that interact with a movable double contact designed as a blade contact. In the off position, the movable contact is separated from the fixed contacts and insulated from earth. The isolating and protective ring functions are not guaranteed. A compression vane is attached to the switching shaft, which also carries the blade contact for each pole. The compression vane is made of insulating material.

FR-A-1.279.475 describes a medium-voltage switchgear cell with a three-phase open rotary switch disconnector that operates with rotating bushings. The moving contact is connected to earth in the intermediate off position, but the switch has neither a protective ring nor a compression piston.

CH-390.346 describes a high-voltage disconnector for an encapsulated switchgear. It contains a rotary contact with two switching positions, whereby the movable contact is connected to earth in the off position. The movable contact is connected to a metal disk, which does not, however, have the function of a piston. Earthing of the phase conductors of the switchgear assigned to the fixed contacts is not possible.

The invention is based on the object of producing a gas-insulated load-break rotary switch with small dimensions and high dielectric strength.

The load-break switch according to the invention is characterized in that

- the movable contact in the second switching position (OFF) interacts with a permanently earthed fixed contact, so that by maintaining the interruption of the connection between Input and output terminals ensure a separation function,

- a metallic shield for forming the movable rotating unit is firmly connected to the movable contact together with the switching shaft, said shield being designed as a protective ring in said second switching position (OFF),

- at least one fixed partition arranged between the insulating housing and the switching shaft interacts with the metallic shield, which serves as a rotary piston for gas compression in order to form at least one piston extinguishing chamber (46a, 46b, 48a, 48b) connected to corresponding systems for arc blowing.

All work on active parts on the output side of the switch-disconnector, such as testing the output conductor, can therefore be carried out safely, as the metallic shield is earthed in the second switch position (OFF).

In addition to its function as a protective ring, the metallic shield serves as a rotary piston for compressing the gas in the piston extinguishing chamber of the housing. The blowing device works together with this extinguishing chamber to extinguish the arc that occurs between the contacts when the contact blade is moved from the first switching position (ON) to the second switching position (OFF). Further advantages will become apparent from the following description of an embodiment of the invention, which is shown in the accompanying drawings as follows:

Fig. 1 shows a perspective view of the schematic structure of a rotary load-break switch according to the invention;

Figs. 2 to 4 show cross-sectional views of the switch according to Fig. 1 in the on, off and earthing positions;

Fig. 5 shows a section along the line V-V of Fig. 1;

Fig. 6 and 7 correspond to the view of Fig. 5 for two design variants.

The drawings show a rotary load-break switch 10 for a three-phase medium-voltage distribution system with gas insulation in a cylindrical housing 12 which is filled with a gas of high dielectric strength, in particular sulphur hexafluoride.

The housing 12 is made of insulating material and is fitted along its inner wall with five fixed contacts 14 to 22, which are attached to radially arranged bushings. The fixed contacts are arranged in the middle transverse plane of the housing 12 at a certain angular offset and interact with a movable double rotary contact 24 designed as a contact blade with

three switching positions. The first fixed contact 14 is connected to the outside with a feed line 26, while the diametrically opposite third fixed contact 18 is connected to an outgoing line 28. The fourth and fifth fixed contacts 20 and 22 are connected to one another via an earthing line 30. The second fixed contact 16, diametrically opposite the fifth fixed contact 22, is arranged between the first and third fixed contacts 14 and 18 and is connected to the outgoing line 28 via a line 32.

A switching shaft 34 made of insulating material for carrying the moving contact 24 is arranged longitudinally inside the cylindrical housing 12. The contact blade of the moving double contact 24 is connected to a radial metallic shield 36 which is aligned at right angles to the switching shaft 34 arranged longitudinally and to the central transverse plane of the load-break switch 10. The metallic shield is laterally connected to two ring electrodes 38, 40 which enclose the ends of the insulating material switching shaft 34.

The blade of the movable contact 24 has two contact tongues 24a, 24b arranged in parallel at a fixed axial distance 1 (see Fig. 5). The two contact tongues 24a, 24b are subject to mutual elastic stress and the distance 1 allows the elastic insertion of the two diametrically opposed interruption zones of the contact blade when interacting with the corresponding fixed contacts 14 to 22 during the rotation of the switching shaft 34 between the three switching positions.

The dimensions of the metallic shield 36 can be smaller in the radial direction than those of the contact blade, so that a radial clearance (see Fig. 3) is created between the inner wall of the housing 12 and the outer edge of the shield 36. The width of this clearance is generally less than 5 mm.

The housing 12 also has two fixed partitions 42, 44 which, together with the rotating unit, form a mechanism for compressing the insulating gas contained in the two piston extinguishing chambers (46a, 46b, 48a, 48b) arranged inside the housing 12. The compression mechanism acts with a (not shown) blowing device to extinguish the arc that occurs between the contacts when the contact blade moves from one switching position to the other.

Fig. 2 to 4 show the functionality of the load-disconnecting rotary switch 10 with the different switching positions:

- In the first switch position (ON) (Fig. 2), the movable blade contact 24 short-circuits the first and third fixed contacts 14, 18 to connect the feed line 26 to the outgoing line 28. The fixed contacts 14, 18 represent the input and output terminals of the load-break switch, respectively.

The rotation of the switching shaft 34 along the circular arc (arrow f, Fig. 3) causes the switch to open by releasing the contact blade from the fixed contacts 14, 18 at a corresponding angle. The opening stroke of the movable contact 24 is approximately 60 degrees and after it has passed through, a contact zone of the contact blade is on the fourth fixed contact 20, which is connected to earth. In this second switching position (OFF), the movable unit forms an integrated protective ring consisting of the metallic shield 36, the movable contact 24 and the two electrodes 38, 40. The introduction of the metallic shield into the creepage distance between the input and output terminals of the load-break switch 10 prevents any bridging of the isolation distance between these terminals by a dangerous leakage current along the inner wall of the housing 12 and the switching shaft 34.

If the outgoing conductor 28 is designed as a cable, it is checked in the off position (Fig. 3) by introducing a test current into one of the fixed contacts 16 or 18 or into a special terminal of the outgoing conductor 28. In this way, the cable can be tested completely safely, since both the metal shield 36 and the contact blade are earthed.

The transition from the off position (Fig. 3) to the earthed position (Fig. 4) is achieved by further rotation of the switching shaft 34 in the direction of arrow f. The contact blade is then on the second and fifth fixed contact 16, 22, and the outgoing conductor 28 is earthed.

From the third switching position (EARTH), the switch-disconnector 10 is switched on again by turning the movable contact unit in the opposite direction of the arrow via the second switching position (OFF) back to the first switching position (ON).

In addition to its function as a protective ring in the off position, the metallic shield 36 serves as a rotary piston for compressing the insulating gas in the arcing chambers 46a, 46b, 48a, 48b. The compression effect occurs in both directions of rotation of the movable contact 24 and is advantageously used to blow off the arc that occurs during the off phase of the switch 10 when the switch moves from the first switching position (Fig. 2) to the second switching position (Fig. 3).

It should be noted that the rotary switch disconnector 10 performs an isolating function, since the earthed metallic shield 36 ensures that a safe isolating distance is maintained between the input and output terminals. The protective ring function is eliminated in the first switch position (ON) (Fig. 2) of the switch disconnector 10, since the shield 36 is not connected to earth.

In the embodiment shown in Fig. 6, the insulating housing 12 of the load-break rotary switch 10 has two projections 50, 52 provided with insulating ends, whereby the dimensions of the metallic shield can be reduced in the longitudinal direction.

Fig. 7 shows a design without any metallic shielding 36 with correspondingly large projections 50, 52, wherein the axial distance between the projections is reduced to such an extent that only the movable contact 24 with two parallel contact tongues can be guided between them.

According to a further design variant (not shown), the rotary piston for compressing the gas and the metallic shield 36 are designed as separate parts.

The invention has been described for a housing 12 with a single switch pole, but it can of course be applied to a three-phase load-break rotary switch in which the poles are arranged along the longitudinal axis of the switching shaft 34. The poles can be installed in a common insulating housing or in individual housings arranged in series.

According to a further embodiment, the housing 12 of each pole of the load-break rotary switch 10 is made of metal, with the fixed contacts being mounted on insulating bushings.

Fig. 8 shows an application of the invention in a three-phase medium-voltage distribution system with a circuit breaker 60, whose first terminal is connected to the busbars 62 via a first rotary switch 10 according to the invention and whose second terminal is connected to the outgoing circuit 64 via a second rotary switch 10 according to the invention.

Fig. 9 shows a further application of the invention in a switchgear for coupling two busbar feeds 62, 66 of a three-phase network RST by means of a circuit breaker 60.

The first busbar feed 62 is connected to the circuit breaker via a load-breaking rotary switch 10 and the second busbar feed 66 is connected to the circuit breaker via another load-breaking rotary switch with three switching positions. The two load-breaking switches 10 correspond in their structure to the description in Fig. 1 to 4.

Fig. 10 shows the top view of a circuit arrangement according to Fig. 8 and 9 with the one above the other and in the vertical parallel to the The rotary switch disconnectors 10 for the three phases are arranged on the axis of the poles of the circuit breakers 60. The column arrangement of the six switch disconnector poles in a shaft alignment simplifies the mechanical drive of the switchgear cell.

The invention can also be applied to a load-break switch with an eccentrically arranged contact blade.

According to a further embodiment, the arc that occurs during the switch-off phase of the rotary load-break switch can be extinguished using a permanent magnet that is suitably arranged inside the housing 12. The effect of the magnetic field on the arc causes it to rotate and be extinguished quickly.

Claims (3)

1. Gas-insulated multi-pole load-break rotary switch (10), in particular for a medium-voltage distribution system, in an insulating housing (12) filled with gas of high dielectric strength, per pole consisting of a movable double contact (24) in the form of a contact blade with three positions, fastened to an insulating switching shaft (34), which interacts with several fixed contacts 14 to 22 angularly offset in a plane along the inner wall of the insulating housing (12), whereby a first switching position (ON) for establishing the electrical connection between an input terminal with a feed line (26) connected to it and an output terminal with an outgoing line (28) connected to it, a second switching position (OFF) for separating the two conductors (26, 28) and a third switching position (EARTH) for earthing one of the two conductors (28) are obtained, thereby characterized by: - the movable contact (24) in the second switching position (OFF) interacts with a permanently earthed fixed contact (20) so that a disconnection function is ensured by maintaining the interruption of the connection between the input and output terminals, - a metallic shield (36) for forming the movable rotating unit with the switching shaft (34) is firmly connected to the movable contact (24), said shield being designed as a protective ring in said second switching position (OFF), - at least one fixed partition wall (42, 44) arranged between the insulating housing (12) and the insulating switching shaft (34) interacts with the metallic shield (36) and thus serves as a rotary piston for gas compression in order to drive at least one piston connected to corresponding systems for arc blowing Extinguishing chamber (46a, 46b, 48a, 48b). 2. Multi-pole load-break rotary switch according to claim 1, characterized in that the input terminal of the multi-pole load-break rotary switch (10) is formed by a first fixed contact (14) which leads out through the housing and is located exactly opposite a third fixed contact (18) connected to the output terminal, that a second fixed contact (16) arranged between the first and third fixed contacts (14, 18) is located exactly opposite a fifth grounded fixed contact (22), and that a fourth fixed contact (20), which interacts with the rotary blade in the second switching position (OFF), is arranged between the third and fifth fixed contacts (18, 22). 3. Multipole load-break rotary switch according to claim 1 or 2, characterized in that the metallic shield (36) has a flat radial surface which is arranged on both sides of the contact blade, perpendicular to the insulating material switching shaft (34) and in the central transverse plane of the pole of the multipole load-break rotary switch (10), and that the insulating material switching shaft (34) is enclosed at its ends by two ring electrodes (38, 40) fastened to the metallic shield (36).