FR2685562A1 - Through-lead for a high-voltage screened station equipped with a remote control device with a trap circuit - Google Patents

Abstract

In order to reduce the bulk of the line outlet of a station equipped with a remote control device, the coupling capacitor (22) of the trap circuit is incorporated into the casing (58, 32) of the screened station (16) which is insulated with SF6, and is connected to the high-voltage overhead line (20) by means of a first auxiliary conductor (64) arranged coaxially in a through-lead (34) with a main outlet conductor (50) from the station.

Description

CROSSING FOR A HIGH-VOLTAGE SHIELDED STATION WITH A
REMOTE CONTROL DEVICE WITH PLUG CIRCUIT.

The invention relates to a high-voltage shielded substation having a sealed envelope filled with insulating gas with high dielectric strength, in particular 1 sulfur thexafluoride SF6, the outlet of the substation being connected by a main crossing to an overhead distribution line at high voltage, and a remote control device associated with a plug circuit with inductance coil and coupling capacitor, intended to send a high frequency remote control signal on the line, the coil being located outside the envelope with isolation in the air.

The state of the art is shown in FIG. 1. The inductance coil 10 of the plug circuit 12 is electrically connected to a line disconnector 14 or circuit breaker at the
exit from a shielded station 16 with a sealed envelope 18, filled with insulating gas, in particular sulfur hexafluoride. The other end of the coil 10 is connected to the high voltage line 20, and has a coupling capacitor 22. At the other end of the capacitor 22 is connected a teletransmission circuit 30, intended to send a telecommunication signal at high frequency on line 20 of the high-voltage network. The remote transmission device 30 contains means of communication using capacitive coupling of the network lines as a transmission medium for the exchange of information and orders with the aim of improving the network operation and monitoring. The operation of the remote transmission circuit 30 does not disturb the distribution of electrical energy at 50 Hz on the line 20 supplied by the shielded station 16. The impedance of the coil 10 of the plug circuit 12 prevents any propagation of the high-frequency remote control signal to the armored substation 16.

The arrangement in the air of the coupling capacitor 22 poses an insulation problem, given the external connection between the high voltage of the line 20, and the point 28 of connection with the remote transmission device 30 connected to ground. the dielectric strength in the air therefore requires significant isolation of the coupling capacitor, which increases the size of the line output of the shielded station 16. Such a device is comatose, and on the other hand requires regular maintenance, especially in areas with high pollution.

The object of the invention is to reduce the size of the line output of a high-voltage shielded substation equipped with a telecommunications device.

The shielded station according to the invention is characterized in that the coupling capacitor is arranged in a sealed casing in communication with the gas SF6 of the envelope, and that the electrical connection of the capacitor with the line is effected by means of a first auxiliary conductor arranged coaxially inside the gaseous medium of the main crossing with a main conductor leaving the station.

The gaseous isolation of the coupling capacitor by incorporation in the station's SF6, and the coaxial connection of the station's main and auxiliary conductors and the capacitor with the line make it possible to reduce the size of the station's output.

The main conductor is separated from the first auxiliary conductor inside the main crossing by isolation means.

The isolation means comprises a first auxiliary bushing fixed on the external face of a conductive flange serving as a connection interface between the main conductor and a conductor for connection with the first terminal of the coil.

The coil is in the air being fixed above the head of the main crossing, and has a first terminal in electrical connection with the main conductor, and a second terminal at the potential of the line.

Other advantages and characteristics will emerge more clearly from the description which follows of an embodiment of the invention given by way of nonlimiting example, and represented in the appended drawings, in which:
FIG. 1 represents the electrical circuit of a shielded post with a telecommunication device according to the prior art described above.

Figure 2 is a schematic view of an outlet crossing of a shielded post according to the invention.

Figures 3 to 5 are partial views on enlarged scales of different parts A, B, C of Figure 1, showing the connection of the plug circuit.

In FIGS. 2 to 5, a shielded station 1 6 with a sealed envelope 32 filled with insulating gas, in particular sulfur hexafluoride
SF6, is connected to the overhead line 20 by a main crossing 34 comprising an insulator 36, the base 38 of which is sealingly fixed to a first flange 39 of a section 40 connecting the station 16. The coil 10 of the circuit inductance plug is mounted on a flush 41 at the level of the head of the insulator 36 opposite the base 38, and is electrically connected to two connection terminals 42, 44.

The first terminal 42 is connected by a connecting conductor 46 to an annular flange 48 of conductive material, sealingly mounted on the insulator 36 opposite the section 40. A main conductor 50 passes axially through the insulator 36 while being connected to the flange 48. The output conductor 52 of the shielded station 16 is electrically connected to the main conductor 50 by a coupler 54 arranged inside the connection section 40, and carried by an insulator 56 support of frustoconical shape.

The second terminal 44 of the coil 10 is connected directly to the high voltage line 20. It is noted that the distribution of electrical energy between the shielded station 16 and the line 20 takes place through the output conductor 52, the coupler 54, the main conductor 50, the flange 48, the connection conductor 46, the first terminal 42, the inductance coil 10, and the second terminal 44.

The coupling capacitor 22 is housed in a sealed casing 58 fixed to a second flange 60 of the connection section 40.

 The envelope 32 of the shielded station 1 6 is secured to a third flange 62 of the section 40, so as to allow the filling of the internal compartments of the bushing 34, of the section 40 and of the casing 58 with the same insulating gas SF6. This arrangement amounts to incorporating the capacitor 22 in the shielded station 16, while the coil 10 is in the air. The support insulator 56 is arranged in a gas-gas medium.

The main conductor 50 of the crossing 34 is formed by a tubular bar whose internal diameter allows the passage of a first auxiliary conductor 64 coaxial for the electrical connection of the capacitor 22 to a socket 66 located at the potential of the second terminal 44 of the inductance coil 10.

The auxiliary conductor 64 is thus connected by one of its ends to the input of the coil (terminal 44) and by the other end to the high voltage part of the coupling capacitor 22.

The auxiliary conductor 64 is isolated from the main conductor 50 as follows:
At the level of the head of the bushing 34, the first auxiliary conductor 64 is carried by a first auxiliary bushing 68 fixed on the external upper face of the flange 48. The interior of the first auxiliary bushing 68 communicates with the internal compartment of 1 ' insulator 36, and is filled with SF6 gas.

The exterior of the first auxiliary bushing 68 is in the air, and is surrounded by the frame 41 of the coil 10.

In the middle part of the bushing 34, a sleeve 70 of insulating material is interposed in the annular separation space formed between the two coaxial conductors 50,64.

At the support insulator 56 of the coupler 54, an insulating shim 72 serves as an isolation means between the two conductors 50, 64. The first auxiliary conductor 64 is electrically connected to the capacitor 22 by a connection pad 74.

The other terminal of the capacitor 22 is connected to the point 28 of connection with the remote transmission circuit 30 by means of a second auxiliary conductor 76, which is arranged inside the casing 58 filled with SF6 gas, and carried by a second auxiliary crossing 78.

The head of the main insulator 36 is surrounded coaxially by a ring 80 for distributing the electric field.

The presence of the two auxiliary bushings 68, 78 allows the connection in the air, on the one hand of the first auxiliary conductor 64 of the capacitor 22 to the input terminal 44 of the coil 10, and on the other hand of the second auxiliary conductor 76 with the remote transmission device 30. The coaxial arrangement of the two conductors 50, 64 inside the main bushing 34 filled with SF6 gas, and the incorporation of the coupling capacitor 22 in the shielded station minimizes the space requirement from line output 20.

Claims (8)

1. Shielded high-voltage substation having a sealed envelope (32) filled with insulating gas with high dielectric strength, in particular sulfur hexafluoride SF6, the outlet of the substation being connected by a main crossing (34) to a line (20 ) aerial high-voltage distribution, and a remote control device associated with a plug circuit (12) with inductor coil (10) and coupling capacitor (22), intended to send a high-frequency remote control signal on the line (20), the coil (10) being located outside the envelope (32) with air isolation, characterized in that the coupling capacitor (22) is arranged in a sealed casing (58) in communication with the gas SF6 of the envelope (32), and that the electrical connection of the capacitor (22) with the line (20) is effected by means of a first auxiliary conductor (64) arranged coaxially inside gaseous medium from the main crossing (34) with a c main output converter (50) of the substation (16). 2. Armored substation according to claim 1, characterized in that the first auxiliary conductor (64) is separated from the main conductor (50) by isolation means (68,70,72).  3. Armored post according to claim 1 or 2, characterized in that the coil (10) is fixed by a frame (41) above the head of the main bushing (34), comprising a first terminal (42) in electrical connection with the main conductor (50), and a second terminal (44) connected to the line (20), and that the first auxiliary conductor (64) is connected to an outlet (66) located at the potential of the second terminal (44).  4. Armored substation according to claim 3, characterized in that the isolation means comprises a first auxiliary bushing (68) fixed on the external face of a flange (48) conductor serving as a connection interface between the main conductor ( 50) and a connecting conductor (46) with the first terminal (42) of the coil (10). 5. Armored station according to claim 2,3 or 4, characterized in that the isolation means comprises a socket (70) and / or wedge (76) arranged in the annular space between the two conductors (50,64) coaxials of the main crossing (34).  6, shielded station according to one of claims 1 to 5, characterized in that the other terminal of the coupling capacitor (22) is connected to a point (28) of connection with the remote control device via a second auxiliary conductor (76) passing through the casing (58) by means of a second auxiliary bushing (78). 7. Armored substation according to one of claims 1 to 6, characterized in that an intermediate section (40) comprises a first flange (39) for fixing the insulator (36) of the main crossing (34), a second flange (60) for connecting the housing (58) for housing the capacitor (22), and a third flange (62) secured to the casing (32) of the shielded station (16), and that a coupler (54) is arranged inside the section (40) by being connected respectively to an output conductor (52) of the station, and to a connection pad (74) of the capacitor (22). 8. Shielded station according to one of claims 1 to 7, characterized in that the first auxiliary conductor (64) extends inside the main conductor (50) in the form of a tubular bar.