EP0591039A1 - H.T. self-blast circuit breaker having an arc chamber with reduced gas compression - Google Patents

Abstract

A self-blast circuit breaker comprising a movable assembly including an arc chamber in two parts consisting of a blast chamber (17) and of a compression chamber (18). The two chambers are separated from one another by a crown (9). The compression chamber (18) is closed by a semi-movable piston (11). The circuit breaker is characterised by a means for immobilising the piston during a first part of the movement of the movable contact assembly between a closing position and an opening position and by a means for axially displacing the piston with the movable contact assembly during a second part of this displacement. This makes it possible to reduce the quantity of energy necessary for displacing the movable contact assembly during the opening operation. <IMAGE>

Description

The invention relates to a high-voltage circuit breaker of the self-blowing type having a cut-off chamber with reduced gas compression.

Document EP-0475270 discloses a high-voltage circuit breaker of the self-blowing type, comprising an insulating envelope surrounding an expansion chamber filled with a dielectric gas under pressure, two arcing contacts cooperating with each other, one at least forming part of a movable contact assembly secured to an operating member and adapted to be moved axially in the envelope between a closed position and an open position, the movable contact assembly being constituted by two coaxial tubes to delimit, on either side of a ring connecting the tubes, a constant volume blowing chamber closed by a blowing nozzle and a compression chamber communicating with the blowing chamber and closed by a semi-piston mobile.

During an opening operation, the gas in the compression chamber is compressed because the distance between the piston and the ring separating the compression chamber from the blowing chamber decreases. In this known circuit breaker, the dielectric gas is compressed during the entire movement of the movable contact assembly between the closed position and the open position. Moving the movable contact assembly requires a certain amount of energy. The amount of energy required is greater the greater the gas in the compression chamber is compressed during the entire stroke of the movable contact assembly.

The object of the invention is to reduce the energy consumption of the circuit breaker during an opening operation.

To this end, the invention relates to a high voltage circuit breaker of the self-blowing type, comprising a insulating envelope surrounding an expansion chamber filled with a dielectric gas under pressure, two arcing contacts cooperating with each other, at least one forming part of a movable contact assembly secured to an operating member and suitable for be moved axially in the envelope between a closed position and an open position, the movable contact assembly consisting of a first tube and a second tube coaxial with the first tube to delimit, on either side of a first ring connecting the first and second tubes, a constant volume blowing chamber closed by a blowing nozzle and a compression chamber communicating with the blowing chamber and closed by a piston, characterized by means for immobilizing the piston during a first part of the movement of the movable contact assembly between the closed position and the open position and a means for axially moving the piston with the assembly of c ontact mobile during a second part of this same movement of the mobile contact assembly.

In the case of low currents to be cut, the extinction of the arc occurring between the arcing contacts during an opening operation is effected by means of compression of the gas in the compression chamber. However, the extinction of the arc obtained by a flow of gas coming from the compression chamber takes place before the movement of the movable contact assembly has ended. Therefore, it is not necessary to compress the gas in the compression chamber during the entire movement of the movable contact assembly. From the moment the piston moves with the movable contact assembly, the amount of energy required to operate the movable contact assembly is very reduced because there is no more gas compression .

According to another characteristic of the invention, the means for axially displacing the piston consists of a drive member integral with the contact assembly mobile which drives a stop integral with the piston during the second part of the movement of the mobile contact assembly, this stop being disposed on the path of the drive member.

The piston is connected to a third tube provided with at least one lumen in which slides a finger integral with the first tube and which extends radially with respect to the latter in the direction of the second tube.

The means for immobilizing the piston consists of a spring arranged between the drive member and the piston and by a fixed retaining member cooperating with the piston. This spring also makes it possible to compensate for the effects of gas overpressure in the compression chamber in the event of a break in high currents.

An exemplary embodiment of the invention is described below in detail with reference to the figures.

FIGS. 1A, 1B, 1C are views in longitudinal section of a circuit breaker having a breaking chamber with limited compression, respectively in the closed position, in the end of compression position and in the open position.

FIGS. 2A, 2B and 2C illustrate the application of the invention to a circuit breaker of the end contact type, and partially represent, in longitudinal section, a circuit breaker with end contacts respectively in the closed position, in the end position of compression and in the open position.

In what follows, a breaking chamber will be described, it being understood that a high voltage circuit breaker, may comprise, for each phase, several breaking chambers of the type which will be described. In FIGS. 1A to 1C, the same references designate identical elements.

In the figures, the reference 1 designates an insulating envelope, preferably of porcelain, delimiting an expansion chamber 2 filled with a gas with good properties dielectric, for example sulfur hexafluoride under a pressure of a few bars.

The circuit breaker includes a fixed assembly and a movable contact assembly.

The fixed assembly comprises an arcing contact 3, consisting of a metal tube, the end 3A of which is made of a material resistant to the effects of the arcing, for example an alloy based on tungsten. The fixed assembly also includes a fixed permanent contact 4 consisting of fingers protected by a corona hood 5. The arcing contact and the fixed permanent contact are electrically connected to a first socket, not shown.

The movable contact assembly comprises an operating part 6 passing through the chamber 2 in a sealed manner and connected to a mechanism not shown. To the part 6 is connected a metallic assembly comprising two coaxial tubes 7 and 8, the tube 8 having a diameter larger than the tube 7. The two tubes 7, 8 are connected together by a metal ring 9. These tubes and this crown are preferably made in one piece from machining.

The tube 7 constitutes the movable arcing contact. Its end 7A is made of a material resistant to the effects of the arc and cooperates with the contact 3-3A. The tube 8 has one end 8A, of reduced diameter and carrying a blowing nozzle 10 made of insulating material. The tubular portion 8A constitutes the permanent movable contact of the circuit breaker and cooperates, when the circuit breaker is in the engaged position (closed position) with the fingers 4 as shown in FIG. 1A.

The end 8A of the tube 8, the blowing nozzle 10, the tube 7 and the crown 9 define a blowing chamber 17. The crown 9, the tubes 7 and 8 and a piston 11 define a compression chamber 18 separated from the blowing chamber through the crown 9. The piston slides axially between the tubes 7 and 8 in a sealed manner. The piston 11 is connected to a tube 12 coaxial with the tubes 7 and 8. The free end of the tube 12 is connected to a ring 12A forming a collar. The crown 12A cooperates with a crown 14A connected to a fixed tube 14 coaxial with the tube 12, the crown 14A forming an end of travel stop for the tube 12 during a closing operation. The tube 14 is electrically connected to a second outlet not shown. The tube 14 also supports a permanent contact formed by fingers 16 in electrical contact with the tube 8. It should be understood that the crown 11, the tube 12 and the crown 12A form a single piece coming from machining.

One or more fingers 7B integral with the tube 7 and extending radially with respect to the latter in the direction of the tube 8 engage by their free end in one or more openings 13 arranged in the tube 12. It will be understood that the fingers 7B and the tube 7 form a single piece.

One or more springs 15 are arranged between the finger (s) 7B and the piston 11.

The piston 11 is equipped with a unidirectional valve 11A allowing gas circulation from the interrupting chamber 2 to the compression chamber. Likewise, the crown 9 is equipped with a unidirectional valve 9A allowing gas circulation from the compression chamber 18 to the blowing chamber 17.

The circuit breaker works as follows.

To switch on the circuit breaker, the operating tube 6 is actuated to move the movable contact assembly to the left as indicated by the arrow f in FIG. 1A. During this closing maneuver, the spring 15 is compressed because the distance between the finger 7B and the piston 11 decreases. Indeed, the finger 7B moves to the left while the piston is held stationary because the crown 12A is retained by the crown 14A. Furthermore, the compression chamber 18 is filled with gas coming from the cutting chamber 2 because the distance from the ring 9 of the piston 11 causes the valve 11A to open. Likewise, the blowing chamber 17 is filled with gas from the compression chamber 18 due to the opening of the unidirectional valve 9A. In the engaged position, the current flows through the fingers 4, the tube 8A, 8, the fingers 16, the tube 14.

To cut off a current, the operating tube 6 is actuated to move the movable contact assembly to the right as indicated by the arrow o in FIGS. 1B and 1C. Permanent contacts 4 and 8A separate. Current is switched on the arcing contacts 3-3A and 7A and an arcing occurs between the arcing contacts when they separate. The electric arc heats the gas in the region of the arc which causes an increase in the pressure in the blowing chamber. The arc current follows a frequency system with a sinusoidal curve and when the current value approaches zero crossing, the overpressure in the chamber 17 is evacuated through the channel delimited by the tube 7A and the nozzle 10 and causes the blowing the arc. When the displacement of the movable contact assembly has been sufficient for the arcing contact 3A to release the outlet of the nozzle 10 where the pressure is lower than the pressure of the blowing chamber, the gas under pressure in the blowing chamber blowing passes through the outlet of the nozzle to evacuate into the cutting chamber 2. The electric arc is cooled by the circulation of gas and cut off at the zero crossing of the current.

During the opening operation, the gas in the compression chamber is compressed because the distance between the crown 9 and the piston 11 decreases. Indeed during a first part of the movement of the movable contact assembly, the finger 7B moves freely in the lumen 13 of the tube 12 between a left end of the lumen and a right end of the lumen while the crown 12A of the tube 12 is held in abutment against the crown 14A due to the action of the spring 15 on the piston 11. This causes a rise in pressure in the compression chamber. When finger 7B comes into abutment against the right end of the light after having traversed a distance Dx, it drives the tube 12 and therefore the piston 11 until the end of the movement of the movable contact assembly. During this second part of the movement of the movable contact assembly, the compression of the gas in the compression chamber 18 is interrupted and the energy required to actuate the operating tube is reduced.

Before the movement of the movable contact assembly has ended, the pressure in the blowing chamber decreases as described above, and the unidirectional valve 9A opens. This leads to a decrease in the pressure in the compression chamber which causes gas to flow from the compression chamber to the blowing chamber and then to the region of the arc. The high density cold gas from the compression chamber then replaces the low density hot gas in the arc region which causes a considerable reduction in the temperature in the blowing chamber and therefore better operation of the circuit breaker.

When it comes to cutting small currents, the increase in pressure in the blowing chamber caused by the arc is insufficient to effectively cut the arc. In such a case, the arc is extinguished using the compression chamber in which the gas pressure increases during the opening operation. The pressure in the compression chamber thus becomes greater than in the blowing chamber which causes the opening of the valve 9A and a circulation of gas from the compression chamber to the expansion chamber. This gas circulation is sufficient to cut the arc at the zero crossing of the current. The opening operation continues to move the arcing contacts away while the compression volume in the compression chamber remains constant because the piston 11 is driven with the movable contact assembly. The consumption circuit breaker energy for this part of the movement of the movable contact assembly is reduced.

FIGS. 2A to 2C illustrate the application of the invention to a medium or high voltage circuit breaker of the type with end contacts.

The movable assembly comprises a metal cylinder 21 electrically connected to a socket not shown by contact fingers 22: the cylinder 21 is mechanically connected by its bottom 21A to an operating rod 23; the cylinder 21 delimits with an annular transverse partition 24 and an insulating nozzle 25, an expansion volume V1. The partition 24 is provided with at least one unidirectional valve 26.

Inside the cylinder 21 is placed an annular piston 27 fixed to the end of a tube 28 serving as movable contact; the end 28A of the cylinder 28 is made of an alloy resistant to the effects of the electric arc and cooperates with a fixed tube 30 constituting the fixed contact of the circuit breaker. The end 30A of the tube 30 is made of an alloy resistant to the effects of the arc.

The cylinder 21, the partition 26, the piston 27 and the tube 28 delimit a compression volume V2.

When the circuit breaker is in the closed position, the contact pressure between the tubes 28 and 30 is provided by a spring 31 resting on the bottom 21A and on the piston 27.

Contact fingers 32 fixed to the partition 24 ensure the passage of permanent current when the circuit breaker is in the closed position.

A sliding contact 33 allows the current to flow from the tube 28 to the partition 26.

It will be noted that the piston 27 is provided with a unidirectional valve 35 and that the bottom 21A is pierced with holes 36.

• en position fermée (Fig. 2A), le courant traverse le tube 30, les doigts 32, la cloison 26, le cylindre 21 et les doigts 22.
• à l'ouverture du disjoncteur, l'ensemble mobile est déplacé vers la droite de la figure. Le volume de compression diminue; les doigts 32 quittent le tube 30 mais le contact reste assuré par les contacts en bout 28A et 30A. Le piston 27 reste donc immobile. (Fig. 2B)
• à la séparation des contacts 28A et 30A, le piston est entraîné avec le reste de l'ensemble mobile.

The circuit breaker works as follows:

• in the closed position (Fig. 2A), the current flows through the tube 30, the fingers 32, the partition 26, the cylinder 21 and the fingers 22.
• when the circuit breaker opens, the mobile assembly is moved to the right in the figure. The compression volume decreases; the fingers 32 leave the tube 30 but the contact remains ensured by the end contacts 28A and 30A. The piston 27 therefore remains stationary. (Fig. 2B)
• when the contacts 28A and 30A separate, the piston is driven with the rest of the movable assembly.

Claims (5)

1 / High voltage circuit breaker of the self-blowing type, comprising an insulating jacket (1) surrounding an expansion chamber (2) filled with a dielectric gas under pressure, two arcing contacts (3A-7A) cooperating between them, at least one being part of a movable contact assembly secured to an operating member (6) and adapted to be moved axially in the envelope between a closed position and an open position, the movable contact assembly consisting of a first tube (7) and a second tube (8) coaxial with the first tube to delimit, on either side of a first ring (9) connecting the first and the second tubes, a constant volume blowing chamber (17) closed by a blowing nozzle (10) and a compression chamber (18) communicating with the blowing chamber and closed by a semi-mobile piston (11), characterized by means for immobilizing the piston during a first part of the displacement of the con assembly movable contact between the closed position and the open position and by means for axially displacing the piston with the movable contact assembly during a second part of this same displacement of the movable contact assembly. 2 / circuit breaker according to claim 1, wherein the means for axially moving the piston (11) is constituted by a drive member (7B) integral with the movable contact assembly which drives a stop integral with the piston during the second part displacement of the movable contact assembly, this stop being disposed on the path of the drive member. 3 / circuit breaker according to claim 2, wherein the piston is connected to a third tube (12) provided with at least one lumen (13) in which slides a finger (7B) integral with the first tube (7) and which s extends radially with respect to the latter towards the second tube (8). 4 / circuit breaker according to claim 2, wherein the means for immobilizing the piston (11) consists of a spring (15) disposed between the drive member and the piston and by a fixed retaining member (14A) cooperating with the piston. 5 / Self-blowing circuit breaker with end contacts, comprising a movable assembly and a fixed assembly, the movable assembly comprising a metal cylinder (21) provided with a bottom (21A), a transverse partition 24 and a blowing nozzle (25), the fixed assembly comprising a tube 30 constituting a fixed contact, characterized in that the movable assembly further comprises a piston (27) placed between said bottom (21A) and said partition (26) and fixed to a tube (28) constituting a movable contact and cooperating with said fixed contact (30), said contacts (28, 30) constituting end contacts, said piston being pushed by a spring (31) resting on said bottom (21A), the piston remaining stationary during an operation of opening the circuit breaker until the separation of the end contacts.

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