WO2015007635A1

WO2015007635A1 - Optimized piston-effect blast circuit breaker

Info

Publication number: WO2015007635A1
Application number: PCT/EP2014/064900
Authority: WO
Inventors: Christophe Creusot; Philippe ROBIN-JOUAN
Original assignee: Alstom Technology Ltd
Priority date: 2013-07-15
Filing date: 2014-07-11
Publication date: 2015-01-22
Also published as: EP3022758A1; FR3008541B1; FR3008541A1

Abstract

Circuit breaker (1) insulated by a dielectric fluid which comprises a first pair of contacts (10, 20), which can move in translation with respect to one another, an arc extinction chamber (30), a compression chamber (40) suitable for propelling a part of the dielectric fluid by piston effect into the extinction chamber (30). The circuit breaker (1) is adapted so that the dielectric fluid propelled by the compression chamber (40) is introduced into the extinction chamber (30) through an end of the first contact (10). According to one possibility of the invention, the extinction chamber is surrounded by a fixed thermal chamber perforated with orifices and thus ensuring blasting as close as possible to the arc contacts.

Description

OPTIMIZED PISTON BLOWING CIRCUIT BREAKER

DESCRIPTION

TECHNICAL AREA

The invention relates to the field of self - blowing high - voltage circuit breakers.

For many years, circuit breakers have been actively researched in order to reduce their size while offering a good dielectric strength when opening and seeking to minimize the energy of maneuvering.

A solution used to reconcile these characteristics, yet antagonistic, is to equip the high-voltage circuit breakers piston blow system to promote the blowing of an electric arc formed between the two arcing circuit breaker contacts when it opens.

Thus, the invention relates more particularly to a high-voltage circuit breaker, the piston blow molding is optimized. STATE OF THE PRIOR ART

In order to promote the extinction of an electric arc formed between the two arcing contacts of the circuit breaker, it is known to equip the high-voltage circuit breakers with at least one compression chamber in order to promote the blowing of the bow.

The insulation of such a circuit breaker is generally provided by a fluid having good dielectric strength characteristics. This circuit breaker in the closed position ensures the passage of the current and interrupts the current in the open position. This same type of circuit breaker comprises in a usual configuration:

a first pair of contacts, said arcing contacts, movable in translation relative to each other, the arcing contacts being remotely in the open position and in contact in the closed position,

an arc extinction chamber in which an electric arc is formed between the arcing contacts during their separation when the circuit breaker moves from the closed position to the open position,

a compression chamber adapted to propel a portion of the dielectric fluid by piston effect in the quenching chamber during the separation of the arcing contacts so as to promote the blowing of the electric arc by said fluid flow.

The compression chamber is generally arranged at the rear of one of the arc contacts with a wall of the compression chamber which is integral in displacement with a first contact and which acts as a piston, the rest of the chamber of compression. compression being secured in displacement with the second arcing contact. The compression chamber is in communication with the extinguishing chamber by at least one channel supplying the flow of fluid propelled by piston effect in the chamber on the periphery of the movable contact.

Thus, with such a circuit breaker the translation displacement of the first arc contact by relative to the second when the circuit breaker passes from the closed position to the open position causes the displacement of the movable wall and therefore a compression of the fluid present in the compression chamber. This compression makes it possible to propel the fluid present in the compression chamber through the channel in the quenching chamber.

This supply of dielectric fluid during the opening of the circuit breaker arcing contacts promotes blowing of the electric arc formed during the separation of the arcing contacts. It may be noted that for this type of circuit breaker there are self-blowing circuit breakers (better known by their English name of "puffer-type circuit breaker") and self-expansion circuit breakers (better known by their English name of "self blast"). circuit breaker ").

Nevertheless, regardless of whether they are of the self-blowing type or of the self-expanding type, such circuit breakers have a compression ratio which is not optimized because, for self-blowing circuit breakers with a dead volume of compression chamber, and for self-expanding circuit breakers, the presence of an expansion chamber between the extinguishing chamber and the compression chamber.

Thus if the supply of dielectric fluid by piston effect promotes the rapid extinction of the arc during the separation of the arcing contacts, it may not be sufficient to extinguish the arc this particular due to a rate of unoptimized compression. This is particularly the case when the circuit breaker conducts a high amperage current or when the circuit breaker is particularly compact with a distance between the arcing contacts in the open position of the relatively low circuit breaker. STATEMENT OF THE INVENTION

The invention aims to remedy this drawback.

Thus, the invention more specifically aims to provide a circuit breaker for promoting an arc blow between the two arcing contacts for larger operating currents than those of a circuit breaker of the prior art having the same compactness.

The invention also aims to provide a circuit breaker for promoting an arc blowing between the two piston-shaped arc contacts that can have an optimized compression ratio compared to a circuit breaker of the prior art implementing a piston effect.

For this purpose, the invention relates to a circuit breaker isolated by a dielectric fluid and having a closed position in which the circuit breaker conducts the current and an open position in which the circuit breaker cuts the current, the circuit breaker comprising:

a first pair of movable contacts in translation relative to each other, having a first and a second contact, said arcing contacts, the arcing contacts being remotely in the open position and in contact in the position closed an arc extinction chamber in which an electric arc is formed between the arcing contacts during their separation when the circuit breaker moves from the closed position to the open position,

a compression chamber adapted to propel a portion of the dielectric fluid by piston effect in the quenching chamber during the separation of the arcing contacts so as to promote the blowing of the arc by said fluid flow,

the circuit breaker being adapted so that the dielectric fluid propelled by the compression chamber is introduced into the quenching chamber through the end of the first contact.

Above and in the rest of the description, the term "extinguishing chamber" means the volume of the circuit breaker located between the first and second contacts and in which the electric arc is formed when the circuit breaker opens.

Such adaptation of the circuit breaker by propulsion of the flow of dielectric fluid at the end of the first contact which is housed in the quenching chamber improves the blowing power of the fluid on the arc formed between the two contacts. 'bow.

In addition, the communication between the compression chamber and the extinguishing chamber is made by one of the arcing contacts, generally of reduced volume vis-à-vis the compression chamber, without the need of a important dead volume. The compression ratio can therefore be optimized vis-à-vis a circuit breaker comprising an expansion chamber or a self-blowing circuit breaker having a large dead volume.

Thus, a circuit breaker allowing an arc break for higher operating currents than a circuit breaker of the prior art of the same compactness, that is to say, having the same distance between the arc contacts in open position.

It can further be provided a thermal chamber containing dielectric fluid, said thermal chamber being configured so that the formation of the arc between the two arcing contacts during their separation causes an expansion of the fluid contained in the thermal chamber and a influx of this fluid into the extinguishing chamber so as to promote the extinction of the arc, said chamber having at least two outlet orifices each arranged to direct the expanded fluid towards an end of a contact corresponding arc.

Such a thermal chamber, with two outlet ports each arranged to direct the expanded fluid towards an end of a respective arc contact, and which is housed in the quenching chamber, allows a dielectric fluid supply to level of the end of each of the arc contacts which is housed in the extinguishing chamber and therefore at both ends of the arc. This produces a blowing of the arc at its two ends, which allows it to be particularly effective. With such a configuration, the piston effect is useful for the elimination of arcs of low intensity, the self-blowing effect is exploited for the elimination of arcs of high intensity. Indeed, with the self-blowing phenomenon, a fraction of the arc energy is used to put a reserve of pressurized gas and blow it at the time of zero crossing of the current.

In addition, with such a circuit breaker; since the thermal chamber is not in the path of the gas flow coming from the compression chamber, the compression ratio is also improved with respect to a circuit breaker of the prior art.

The first arcing contact may be a tulip type contact having a plurality of flexible strips joined to delimit a receiving cavity of the second contact, the dielectric fluid flow propelled by the compression chamber being introduced by said cavity. Home.

A guide piece for the flow of fluid may be provided inside the cavity for receiving the contact in order to channel the fluid towards the end without the fluid escaping radially through the contact slots present between the lamellae. flexible.

Such a first contact is particularly suitable for providing a dielectric fluid passage in the direction of the extinguishing chamber at its end, the latter being provided with a receiving cavity opening into the extinguishing chamber at the end. level of said end.

The first arc contact may comprise at least one channel in communication with the chamber of compression putting in communication the reception cavity and the compression chamber.

Such a channel in communication with the compression chamber makes it possible to conduct the fluid at the level of the reception cavity without disturbing the rest of the circuit breaker.

The first contact may further comprise a system for evacuating the influx of the expanded fluid into the extinguishing chamber adapted to evacuate said influx into another part of the circuit breaker, said evacuation system being adapted to be neutralized during the propulsion by piston effect of most of the dielectric fluid in the compression chamber.

Such a system for evacuating the influx of fluid allows an evacuation of the influx of dielectric fluid into the quenching chamber without this evacuation system disturbing the propulsion of dielectric fluid in the quench chamber by piston effect . This results in a blowing of the arc which is optimized for both that provided by piston effect than for that provided by the expansion of the fluid present in the thermal chamber.

It will be understood above and in the remainder of this document that most of the dielectric fluid in the compression chamber is propelled by piston action when the volume of the compression chamber has a volume which is divided by three by relative to the volume of the compression chamber in the closed position of the circuit breaker. The evacuation system may comprise at least one opening formed in the first contact, said opening being arranged on the first contact to be placed in communication with another part of the circuit breaker when the circuit breaker passes from the closed position to the open position after that a major part of the dielectric fluid in the compression chamber has been piston-propelled into the quench chamber.

The exhaust system may further include an obstruction member adapted to obstruct the opening provided on the first contact during a portion of the displacement of the first contact during which the major portion of the dielectric fluid propelled by the compression chamber is introduced into the first contact. the extinction chamber.

The arrangement of the opening arranged in the first contact can be adapted so that during the displacement of the first contact during the passage of the circuit breaker from the open position to the closed position, the opening comes into communication with another part of the circuit breaker only from the moment a major part has been propelled by piston effect in the extinguishing chamber

Such evacuation systems are particularly adapted to evacuate a portion of the influx of expanded fluid from the thermal chamber into the quenching chamber without significant disturbance of the propulsion of the fluid by piston effect from the compression chamber. The channel communicating the receiving cavity and the compression chamber may have a non-return valve adapted to prevent any evacuation of the influx of fluid in the compression chamber.

Such a valve makes it possible to prevent any penetration into the fluid compression chamber resulting from the influx of fluid from the thermal chamber. Such penetration could cause thrust on a wall of the compression chamber against relative movement between the first and second arcing contacts.

The second contact may be a fixed contact with respect to an outer envelope of the circuit breaker, the first contact being movable in translation relative to this same envelope, the circuit breaker further comprising a blowing nozzle adapted to promote the blowing of the arc. forming between the arcing contacts during the passage of the circuit breaker from the closed position to the open position, the blowing nozzle being secured to the second arcing contact.

Such a configuration reduces the mass to be displaced during the passage of the circuit breaker from the closed position to the open position and therefore reduces the energy required to move the circuit breaker between these two positions.

The first contact may comprise a hollow contact body on which the flexible lamellae are arranged and in which the communication channel extends longitudinally in the body. BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be better understood on reading the description of exemplary embodiments, given purely by way of indication and in no way limiting, with reference to the appended drawings in which:

FIG. 1 illustrates a sectional view of a circuit breaker according to the invention in the closed position, FIG. 2 illustrates a sectional view of the circuit breaker illustrated in FIG. 1 in the open position,

FIG. 3 is a close-up view of FIG.

Identical, similar or equivalent parts of the different figures bear the same numerical references so as to facilitate the passage from one figure to another.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

FIG. 1 illustrates a self-bleeding high-voltage circuit breaker 1 comprising a compression chamber 40 according to the invention. Such a circuit breaker 1 is a circuit breaker isolated by a dielectric fluid such as a sulfur hexafluoride gas SF ₆ and is of the self-blowing type. The circuit breaker 1 extends along a longitudinal axis.

The circuit breaker 1 has a closed position in which the circuit breaker 1 conducts the current and an open position in which the circuit breaker 1 cuts the current.

The circuit breaker 1 comprises: a first pair of contacts 10, 20 movable in translation relative to each other, having a first and a second contact 10, 20, said arcing contacts, the arcing contacts being in contact in the closed position as shown in FIG. 1, and remotely in the open position, as illustrated in FIG.

an extinction chamber 30 of the arc, particularly illustrated in FIG. 2, in which an electric arc is formed between the arcing contacts 10, 20 during their separation during the passage of the circuit breaker from the closed position to the position opened,

a compression chamber 40 adapted to propel a portion of the dielectric fluid by piston effect in the extinction chamber 30 during the separation of the arcing contacts 10, 20 so as to promote the blowing of the arc by said fluid flow , the compression chamber comprising a movable wall 41 adapted to modify the volume of the compression chamber 40 by its displacement,

a blow nozzle 50 in which is arranged a heat chamber 55 configured so that the formation of the arc between the two arc contacts during their separation causes an expansion of the fluid contained in the heat chamber 55 and an influx of this fluid in the extinction chamber 30 so as to promote the extinction of the arc.

In this document, the terms arc contacts

10, 20 and first and second contacts 10, 20 are used alternately and represent the same two elements of the circuit breaker.

Similarly, the terms main contacts 60, 70 and third and fourth contacts 60, 70 are used alternately and represent the same two elements of the circuit breaker.

The circuit breaker 1 further comprises a third and a fourth contact 60, 70 movable in translation relative to each other and which are said to be main. The third and fourth contacts 60, 70 are electrically connected respectively to the first and second contacts 10, 20. The main contacts 60, 70 are, when the circuit breaker 1 is in the closed position in contact with each other and are when the circuit-breaker is in the open position, at a distance from each other.

The first contact 10 comprises a first part 11 in the general shape of a tulip and a second part 15 which extends the first part in the direction opposite to the second contact and which has the general shape of a hollow cylinder whose base which is connected to the first part is open.

The first part 11 comprises a plurality of elastic strips 12 distributed radially around the longitudinal axis of the circuit breaker 1 so as to define a receiving cavity for the second contact 20 which is open towards the same second contact 20. The lamellae elastic members 12 join at their base, which is opposed to the second contact 20 to form a ring surrounding the second portion 15 of the first contact 10 at the the end connected to the first portion 11 of the first contact 10. The receiving cavity 13 delimited by the first portion 10 is in fluid communication with the interior of the second portion 15 of the first contact 10.

According to a possibility of the invention not illustrated, it can be provided inside the reception cavity 13 in a guide piece of the fluid flow in order to channel the fluid towards the end of the first contact 10 without the fluid does not escape radially through the slits present between the elastic lamellae 12.

The second part 15 comprises a hollow part which delimits a longitudinal duct s 'opening for one of its ends in the receiving cavity 13 of the first part and having, for the other of its ends, a lateral opening s' opening, when the circuit breaker 1 is in the open position, on another part 80 of circuit breaker 1.

The hollow part is divided into two portions, a first portion 16, in contact with the first portion 11 of an outer diameter substantially identical to that of the first portion of the first contact and a second portion 17 housed in the other portion 80 of the circuit breaker 1 having an outside diameter greater than that of the first portion. Thus, the hollow part comprises at the intersection between the first and the second portion 16, 17 a shoulder.

The first portion 16 has a relatively thick side wall vis-à-vis that of the second portion. The side wall of the first portion defines a portion of the duct extending for said portion over the entire length of the first portion. The side wall has a length portion of channels 45 placing the receiving cavity 13 of the first portion 11 of the first contact 10 into communication with the compression chamber 40. The channels 45 are formed in the wall of the first portion 16 and extend along the entire length of the first portion 16. The channels 45 also include a portion of length which extends in the second portion 17 of the second portion 15 of the first contact 10 towards the compression chamber 40.

The second portion 17 has a cylindrical shape, a first base, which is opposite the second contact 20, in fluid communication with the first portion 16 so as to form the conduit and a second base, opposite to the first, is closed. The second portion 17 has openings 18 provided on its longitudinal wall near its second base. The openings 18 are adapted to allow a communication of the conduit with another part 80 of the circuit breaker 1.

Each channel 45 has an inlet which communicates with the compression chamber at the level of the movable wall 41 and an outlet which opens into the receiving cavity 13 at the end of the second portion 15 of the first contact 10. A flap check 46 is installed at the channel outputs 45 in the docking cavity 13. the check valve ^¬ back 46 is adapted to prohibit the introduction into the channels 45 of dielectric fluid coming from the reception cavity 13.

The second portion 15 of the first contact 10 is integral with the movable portion 61 of the third contact 60. A movable portion 61 of the third contact

60 is fixed on the second portion 15 of the first contact 10 bears on its shoulder.

The moving part 61 of the third contact 60 has a general shape of revolution around the longitudinal axis of the circuit breaker 1. The moving part

61 of the third contact 60 has an L-shaped section with the longest branch along the longitudinal axis and the shortest branch extending substantially in a plane orthogonal to the longitudinal axis towards the same axis. The branch of the shortest L of the movable portion 61 of the third contact 60 forms the movable wall 41 of the compression chamber 40.

The third contact 60 also comprises a fixed part 62 comprising a cover 62a, a contact body 64 and a plurality of flexible tongues 63. The cover 62a and the tongues 63 are adapted to accommodate the movable portion 61 of the third contact 60 with the tabs flexible 63 which are supported on the movable portion 61 of the third contact 60 irrespective of the position of the circuit breaker 1. Such an adaptation is obtained by a shape of revolution of the cover 62a, which has a generally hollow cylindrical shape whose base which is opposite the second contact 20 is open to allow a translation in the cover 62a of the movable portion 61 of the third contact 60, and the base which is opposed to the second contact 20 is closed by the contact body 64. The flexible tongues 63 of the third contact 60 are arranged inside the cover 62a extending along the inner wall of the latter in support of the movable part 61 of the third contact 60.

In this way, the movable portion 61 of the third contact 60 can move when the circuit breaker 1 goes from the closed position to the open position without loss of electrical contact between the movable portion 61 and the fixed portion 62 of the third contact 60. The hood 62a comprises at its end which is opposite the second contact 20 a seal 62b arranged to allow movement of the movable portion 61 of the third contact 60 while ensuring the seal between the cover 62a and the movable part 61 third contact 60.

The contact body 64 comprises a valve 47 adapted to allow the entry of fluid into the compression chamber 40 from the other part 80 of the circuit breaker 1 during the movement of the circuit breaker from the open position to the closed position. Such a valve 47 allows the filling of the compression chamber 40 during the closing of the circuit breaker thus ensuring the supply of fluid into the extinguishing chamber 30 by piston effect when opening the circuit breaker 1.

The cover 62a delimits, with the movable portion 61 and the contact body 64, the compression chamber 40, the movable portion of the third contact 60 comprising the movable wall 41 of the compression chamber 40. When moving the first contact 10 relative to the second contact and the rest of the circuit breaker, which occurs during the passage of the circuit breaker in the open position, the movable wall 41 moves causing a reduction in the volume of the compression chamber 40. Such a reduction in volume increases the pressure in the compression chamber 40 and causes an expulsion of a portion of the fluid in the compression chamber 40 toward the extinguishing chamber 30. This influx of fluid into the chamber extinguishing 30 promotes the extinction of an arc formed in the latter during the separation of the arcing contacts 10, 20

The contact body 64, also called the contact gate, of the third contact 60 has a general shape of revolution around the longitudinal axis of the circuit breaker 1 with a first cylindrical outer casing 64a whose base facing the second contact 20 has a suitable passage for the passage of the second portion 15 of the first contact 10 and a second cylindrical inner envelope 64b which extends the passage for the first contact in the direction opposite to the second contact 20. The inner envelope 64b has an inside diameter slightly greater than the outside diameter of the second portion 17 of the hollow piece so as to allow sliding of the latter in the inner casing 64b. The adjustment of the inner diameter of the inner casing 64b ensures a closure of the opening 18 of the second portion 17 of the second portion 15 over a portion of the displacement of the first contact 10 during the passage of the circuit breaker 1 from the closed position to the open position.

The length of the inner casing 64b is smaller than that of the second portion 17 of the second portion 15 to enable the conduit to be placed in communication with the other part 80 of the circuit breaker 1 delimited by the outer casing 64b of the contact body. 64. The length of the inner casing 64b is adapted so that during the passage of the circuit breaker 1 from the closed position to the open position, the conduit is placed in communication with the other part of the circuit breaker 1 after a major part of the dielectric fluid in the compression chamber 40 has been propelled by piston effect in the extinguishing chamber 30.

The first contact 10, when the circuit breaker 1 is in the closed position, is partially housed, with the second contact 20, in the extinction chamber 30.

The extinguishing chamber 30 is delimited by the blast nozzle 50. The extinguishing chamber 30 has a generally cylindrical shape with an inside diameter slightly greater than the outside diameter of the first part of the first contact 1. The extinguishing chamber 30 is in communication with the thermal chamber 55 by means of a plurality of outlet orifices 56. The orifices are divided into four groups 56a, b, c, d of twelve orifices whose orifices of a given group are substantially distributed radially. around the extinction chamber 50 so to provide an influx of isotropic fluid in a plane substantially perpendicular to the axis.

If in this embodiment each of the groups comprises twelve orifices, it is also conceivable, without departing from the scope of the invention, for one or more of the groups of orifices to comprise more than twelve or less than twelve. orifices. Thus a circuit breaker of the invention may comprise, for example, for each group, only 3 orifices distributed or not radially around the extinguishing chamber.

The two groups of external openings 56a are arranged to direct the expanded fluid towards the ends each towards one end of a corresponding arc contact 10, 20. With such an arrangement of the two groups of orifices external 56a, d, the orifices of these two groups are arranged for, during the passage of the circuit breaker in the open position, directing a fluid escaping from the thermal chamber 55 towards an end of a corresponding arc contact 10, 20.

The thermal chamber 55 is arranged in the blast nozzle 50 and surrounds the extinction chamber 30. The thermal chamber 55 is thus close to an arc forming in the extinguishing chamber 30 during the separation of the first and the second chamber. second contact 10, 20. Such proximity to the arc formed during the separation of the first and the second contact 10, 20 allows a transfer in the thermal chamber 55 of a portion of the heat that is related to the formation of this arc and thus causes an expansion of the dielectric fluid in the thermal chamber 55.

The second contact 20 is mounted integral with the blast nozzle 50 with the end of the second contact 20, which end is opposite the first contact 10 which is housed in the extinguishing chamber 30. The second contact 20 has an oblong shape extending from a support member 25 towards the first contact 10.

The second contact 20 is in electrical contact with the fourth contact 70 from the support member 25. The fourth contact 70 comprises a cover 71 and a plurality of flexible lamellae 72 both substantially cylindrical. The flexible strips 72 of the fourth contact 70 are adapted to accommodate the movable portion 62a of the third contact 60 and be in contact therewith.

Such a circuit breaker 1, during the transition from its closed position to its open position, has the following kinematics:

the first contact 10 and the third contact 60 are moved in translation relative to, respectively, the second contact 20 and the fourth contact 40, during this displacement the first and second contacts 10, 20 separate generating an electric arc,

at the same time, the movable wall 41 of the compression chamber 40 is moved with the first contact 10, causing a piston effect thrust of the fluid in the channels 45 towards the extinguishing chamber 30 by passing through the first contact 10, such a supply of dielectric fluid in the extinguishing chamber 30 being favorable to the blowing of the electric arc,

when a major part of the dielectric fluid in the compression chamber 40 has been piston-propelled into the quench chamber 30, the heating of the fluid in the heat chamber 55 causes an expansion of the fluid and an influx of the fluid. same fluid in the extinguishing chamber 30 thus promoting the blowing of the electric arc,

concomitantly the first contact 10 reaches a position in which the inner casing 64b no longer closes the openings of the second part 15 of the first contact 10 thus putting the conduit in communication with the other part 80 of the circuit breaker 1, so the influx fluid in the extinguishing chamber 30 can be evacuated in the other part 80 of the circuit breaker.

With such kinematics, an electric arc formed during the opening of the circuit breaker is subjected in turn to a flow of fluid originating from the compression chamber 40 and to an influx of expanded fluid from the thermal chamber 55, thus ensuring a good blowing of the arc regardless of the compactness of the circuit breaker 1.

Claims

A circuit breaker (1) isolated by a dielectric fluid and having a closed position in which the circuit breaker (1) conducts the current and an open position in which the circuit breaker (1) cuts the current, the circuit breaker (1) comprising:

a first pair of mutually translatable contacts (10, 20) having a first and a second contact (10, 20), said arcing contacts, the arcing contacts (10, 20); 20) being remotely in the open position and in contact in the closed position,

an arc extinction chamber (30) in which an electric arc is formed between the arcing contacts (10, 20) during their separation when the circuit breaker (1) moves from the closed position to the open position,

a compression chamber (40) adapted to propel a portion of the dielectric fluid by piston effect in the extinguishing chamber (30) during the separation of the arcing contacts so as to promote the blowing of the arc by said flux of fluid,

the circuit breaker (1) being characterized in that it is adapted so that the dielectric fluid propelled by the compression chamber (40) is introduced into the quenching chamber (30) through one end of the first contact (10). ).

2. Circuit breaker (10) according to claim 1, wherein there is further provided a thermal chamber (55) containing dielectric fluid, said thermal chamber (55) being configured so that the formation of the arc between the two contacts arc (10, 20) during their separation causes an expansion of the fluid contained in the thermal chamber (55) and an influx of this fluid into the extinguishing chamber so as to promote the extinction of the arc, said chamber thermal circuit (55) having at least two outlet ports (56a, b, c, d) each arranged to direct the expanded fluid towards an end of a corresponding arc contact (10, 20).

3. Circuit breaker (1) according to claim 1 or 2, wherein the first contact (10) is a tulip type contact having a plurality of flexible strips (12) joined to define a receiving cavity (13) of the second contact (20), the flow of dielectric fluid propelled by the compression chamber (40) being introduced by said receiving cavity (13).

4. Circuit breaker (1) according to claim 3, wherein the first contact (10) comprises at least one channel (45) in communication with the compression chamber (40) communicating the receiving cavity (13) and the compression chamber (40).

Circuit breaker (1) according to claim 2 or claim 3 or 4 in combination with claim 2, wherein the first contact (10) further comprises a system for evacuating the influx of the expanded fluid into the extinguishing chamber adapted to evacuate said influx to another part (80) of the circuit breaker (1), said evacuation system being adapted to be neutralized during the piston effect of most of the dielectric fluid in the compression chamber (40).

6. Circuit breaker (1) according to the preceding claim, wherein the evacuation system comprises at least one opening (18) formed in the first contact (10), said opening (18) being arranged on the first contact (10) for communicating with another part of the circuit breaker (1) when the circuit breaker (1) moves from the closed position to the open position after a major portion of the dielectric fluid in the compression chamber (40) has been propelled by piston action in the extinguishing chamber (30).

The circuit breaker (1) according to claim 4 or claim 5 or 6 in combination with claim 4, wherein the channel (45) communicating the receiving cavity (13) and the compression chamber (40) has a non-return valve (46) adapted to prevent any evacuation of the influx of fluid into the compression chamber (40).

8. Circuit breaker (1) according to any one of the preceding claims, wherein the second contact (20) is a fixed contact with respect to a outer envelope of the circuit breaker (1), the first contact (10) being movable in translation relative to this same envelope, the circuit breaker (1) further comprising a blowing nozzle (50) adapted to promote the blowing of the arc is forming between the arcing contacts (10, 20) during the passage of the circuit breaker (1) from the closed position to the open position, the blowing nozzle (50) being integral with the second contact (20).

The circuit breaker (1) according to claim 4 or any one of claims 5 to 8 in combination with claim 4, wherein the first contact (10) comprises a hollow contact body (64) on which the lamellae are arranged flexible (62a) and wherein the communication channel (45) extends longitudinally in the body.