EP3991191B1 - Electric circuit breaker - Google Patents

Description

The present invention relates to an electrical circuit breaker.

In the field of electrical protection, electrical circuit breakers make it possible to interrupt an electrical current, for example to disconnect an electrical load from an electrical circuit in response to a cut-off order.

In certain applications, in particular those relating to photovoltaic panels or electric vehicles powered by batteries, it is sometimes necessary to interrupt an electric current with a very short response time (eg in less than 10ms).

Ideally, such a circuit breaker should have a wide operating range, i.e. it should be able to interrupt low-intensity electrical currents (e.g. less than 100 A under 1000 V DC) , or even to open a circuit in the absence of current, as well as to interrupt high intensity electrical currents (e.g. up to 30 kA), whether in electrical circuits of very low inductance ( eg 3 µH or less) or in high inductance electrical circuits (eg 100 µH or more).

It is known from FR-3064107-A1 to use a single-use circuit breaker formed by the association of a pyrotechnic switch with an external fuse, in which the pyrotechnic switch is triggered to physically cut an electrical conductor connecting input and output terminals of the cutter -circuit and in which the electrodes of the external fuse are automatically connected to the severed conductor as soon as the switch has been triggered. This connection diverts the current to the fuse and the latter will then melt to interrupt the current.

Such a circuit breaker however has the drawback of having an operating range that is too small, since it is not possible to optimize the fuse both for interrupting low-intensity currents and high-intensity currents.

In practice, with low intensity currents (e.g. intensity less than 10 times the fuse rating), the fuse takes longer to melt completely, in particular because the fuse pre-arcing time depends on the intensity of the fuse. current to be interrupted.

Thus, if the fuse is sized for high intensity currents, it will take longer to melt completely when it is crossed by low intensity currents. During this time, the current will continue to flow at inside the pyrotechnic switch and the electrical load will continue to be supplied, despite the cut-off order.

If no current flows through the circuit breaker when it trips, the fuse will remain intact. A current much lower than the caliber of the fuse can therefore continue to circulate in the circuit breaker without a time limit. This is undesirable, because the function required of the circuit breaker is to open the electrical circuit in all cases, independently of the value of the current flowing through it at the instant of tripping.

If, on the other hand, the fuse is sized for low-intensity currents, there is a risk that the fuse will melt too quickly when high-intensity currents pass through it, which will not allow the gases present in the switch to cool. and to de-ionize, which can lead to the re-establishment of an electric arc between the severed portions of the conductor in the pyrotechnic switch. The current can then no longer be interrupted, which can damage the electrical load and/or the circuit breaker itself, to the point of leading to the destruction of the circuit breaker

There is therefore a need for an electric circuit breaker capable of interrupting an electric current with a very short response time and with a wide operating range, from a current of zero intensity to a current of very high intensity.

• un conducteur électrique comprenant un premier terminal et un deuxième terminal ;
• un interrupteur configuré pour séparer le premier terminal du deuxième terminal lorsqu'il est déclenché en réponse à un ordre de coupure du courant ;
• une chambre d'extinction d'arc délimitée par un corps du coupe-circuit, la chambre d'extinction d'arc étant configurée pour recevoir, après déclenchement de l'interrupteur pyrotechnique, une portion du conducteur électrique étant séparée au moins du premier terminal ou du deuxième terminal ;
• un fusible configuré pour être connecté électriquement entre les premier et deuxième terminaux après le déclenchement de l'interrupteur ;

le coupe-circuit comporte un dispositif de connexion comprenant une barrière configurée pour être rompue postérieurement au déclenchement de l'interrupteur uniquement lorsqu'au moins l'une ou l'autre de la température, ou de la pression à l'intérieur de la chambre d'extinction d'arc, ou de l'intensité d'un arc électrique présent dans la chambre d'extinction d'arc dépasse un seuil prédéfini, le dispositif de connexion étant configuré pour connecter une électrode du fusible à un des terminaux du conducteur électrique seulement une fois que la barrière est rompue.To this end, according to one aspect of the invention, an electrical circuit breaker comprises:

• an electrical conductor including a first terminal and a second terminal;
• a switch configured to separate the first terminal from the second terminal when triggered in response to a power cut command;
• an arc extinguishing chamber delimited by a body of the circuit breaker, the arc extinguishing chamber being configured to receive, after triggering of the pyrotechnic switch, a portion of the electrical conductor being separated at least from the first terminal or the second terminal;
• a fuse configured to be electrically connected between the first and second terminals after the switch has been tripped;

the circuit breaker comprises a connection device comprising a barrier configured to be broken after the tripping of the switch only when at least one or the other of the temperature, or of the pressure inside the chamber arc extinction, or the intensity of an electric arc present in the arc extinguishing chamber exceeds a predefined threshold, the connection device being configured to connect an electrode of the fuse to one of the terminals of the electrical conductor only once the barrier is broken.

The association between the fuse and the device makes it possible to obtain a rapid response and a wide operating range.

The barrier makes it possible to introduce a threshold from which the current is diverted towards the fuse. The threshold required to break the barrier and thus connect the fuse depends indirectly on the intensity of the electric current to be interrupted and can be controlled by choosing certain characteristics of the barrier during the manufacture of the circuit breaker.

Thus, the threshold from which the fuse is connected after the tripping of the switch adapts automatically according to the conditions which prevail inside the arc extinguishing chamber. Thanks to this adaptation, for currents of intensity lower than the defined threshold, the switch opens the circuit without intervention of the fuse; for currents of intensity greater than the defined threshold, the fuse is connected in parallel with the switch. The time then necessary for the melting of the fuse (pre-arcing time) allows the cooling and the deionization of the gases present in the interrupting chamber of the switch. When the fuse has melted, an electric arc appears and grows within it, which makes it possible to interrupt the flow of current. Thanks to this adaptation, the same fuse can be used both to interrupt high and low intensity currents

• Au moins une électrode du fusible s'étend à l'intérieur de la chambre d'extinction d'arc, la barrière étant une barrière électriquement isolante qui sépare ladite au moins une électrode du reste de la chambre d'extinction d'arc.
• La barrière isolante comporte une paroi qui délimite un volume autour de ladite au moins une électrode du fusible dans la chambre d'extinction d'arc.
• La paroi est électriquement isolante.
• La paroi est configurée pour fondre lorsque la température dans la chambre d'extinction d'arc dépasse un seuil prédéfini.
• La paroi comporte une zone prédécoupée configurée pour se détacher et former une ouverture dans la paroi lorsque la pression dans la chambre d'extinction d'arc dépasse un seuil prédéfini.
• La barrière isolante comporte un revêtement électriquement isolant déposé sur ladite au moins une électrode du fusible dans la chambre d'extinction d'arc, ce revêtement étant configuré pour fondre lorsque la température dans la chambre d'extinction d'arc dépasse un seuil prédéfini.
• La paroi ou le revêtement est recouvert d'au moins une couche extérieure électriquement conductrice.
• La paroi est en métal.
• La paroi est configurée pour se déformer lorsque la pression dans la chambre d'extinction d'arc dépasse un seuil prédéfini, jusqu'à venir en contact contre l'extrémité libre de ladite au moins une électrode.
• L'extrémité libre de ladite au moins une électrode est configurée pour perforer la paroi lorsque la paroi se déforme et entre en contact avec ladite extrémité libre.
• La paroi comporte une zone prédécoupée configurée pour se détacher et former une ouverture dans la paroi lorsque la pression dans la chambre d'extinction d'arc dépasse un seuil prédéfini.
• Le coupe-circuit comporte un circuit de commande, un capteur pour mesurer une condition à l'intérieur de la chambre d'extinction d'arc et un actionneur auxiliaire configuré pour rompre la barrière isolante et dans lequel le circuit de commande est configuré pour déclencher l'actionneur auxiliaire lorsqu'une grandeur physique mesurée par le capteur dépasse une valeur seuil.
• Le coupe-circuit comporte un fusible additionnel configuré pour être connecté électriquement entre les premier et deuxième terminaux après le déclenchement de l'interrupteur, au moins une électrode du fusible additionnel s'étendant à l'intérieur de la chambre d'extinction d'arc, le coupe-circuit comportant en outre une barrière additionnelle électriquement isolante qui sépare ladite électrode du fusible additionnel du reste de la chambre d'extinction d'arc, ladite barrière étant configurée pour être rompue postérieurement au déclenchement de l'interrupteur uniquement lorsqu'au moins l'une ou l'autre de la température, ou de la pression à l'intérieur de la chambre d'extinction d'arc, ou de l'intensité d'un arc électrique présent dans la chambre d'extinction d'arc dépasse un seuil prédéfini, ce seuil étant différent du seuil de déclenchement associé à la barrière isolante de l'autre fusible.
• Le coupe-circuit comporte un conducteur électrique additionnel raccordé à un des terminaux du conducteur électrique, le conducteur électrique additionnel

According to advantageous but not mandatory aspects, such an electrical circuit breaker may incorporate one or more of the following characteristics, taken separately or in any technically permissible combination:

• At least one electrode of the fuse extends inside the arc extinguishing chamber, the barrier being an electrically insulating barrier which separates said at least one electrode from the rest of the arc extinguishing chamber.
• The insulating barrier comprises a wall which delimits a volume around said at least one electrode of the fuse in the arc extinguishing chamber.
• The wall is electrically insulating.
• The wall is configured to melt when the temperature in the arc quenching chamber exceeds a predefined threshold.
• The wall has a pre-cut area configured to detach and form an opening in the wall when the pressure in the arc extinguishing chamber exceeds a predefined threshold.
• The insulating barrier comprises an electrically insulating coating deposited on said at least one electrode of the fuse in the arc extinguishing chamber, this coating being configured to melt when the temperature in the arc extinguishing chamber exceeds a predefined threshold.
• The wall or coating is covered with at least one electrically conductive outer layer.
• The wall is metal.
• The wall is configured to deform when the pressure in the arc extinguishing chamber exceeds a predefined threshold, until it comes into contact against the free end of said at least one electrode.
• The free end of said at least one electrode is configured to perforate the wall when the wall deforms and comes into contact with said free end.
• The wall has a pre-cut area configured to detach and form an opening in the wall when the pressure in the arc extinguishing chamber exceeds a predefined threshold.
• The circuit breaker includes a control circuit, a sensor for sensing a condition within the arc extinguishing chamber, and an auxiliary actuator configured to break the insulating barrier and wherein the control circuit is configured to trip the auxiliary actuator when a physical quantity measured by the sensor exceeds a threshold value.
• The circuit breaker includes an additional fuse configured to be electrically connected between the first and second terminals after the switch has been tripped, at least one electrode of the additional fuse extending inside the arc extinguishing chamber , the circuit breaker further comprising an additional electrically insulating barrier which separates said electrode of the additional fuse from the rest of the arc extinguishing chamber, said barrier being configured to be broken after tripping of the switch only when at minus either the temperature, or the pressure inside the arc quenching chamber, or the intensity of an electric arc present in the arc quenching chamber exceeds a predefined threshold, this threshold being different from the tripping threshold associated with the insulating barrier of the other fuse.
• The circuit breaker comprises an additional electrical conductor connected to one of the terminals of the electrical conductor, the additional electrical conductor

• Le dispositif de connexion comporte une pièce mobile électriquement conductrice déplaçable entre une position de repos et une position excitée dans laquelle elle raccorde électriquement ladite électrode du fusible avec ledit terminal, la pièce mobile étant montée coulissante dans un logement du coupe-circuit, la barrière étant disposée de manière à séparer la chambre d'extinction d'arc du logement et étant configurée pour rompre lorsque le seuil prédéfini est dépassé.
• L'interrupteur est un interrupteur pyrotechnique.

being isolated from the arc extinguishing chamber and comprising a free end which opens inside the volume delimited by the wall.

• The connection device comprises a movable electrically conductive part movable between a rest position and an energized position in which it electrically connects said electrode of the fuse with said terminal, the movable part being slidably mounted in a housing of the circuit breaker, the barrier being arranged to separate the arc quenching chamber from the housing and being configured to break when the predefined threshold is exceeded.
• The switch is a pyrotechnic switch.

• [Fig 1] la figure 1 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un premier mode de réalisation de l'invention, illustré dans un premier état ;
• [Fig 2] la figure 2 est une représentation schématique du coupe-circuit électrique de la figure 1, illustré dans un deuxième état ;
• [Fig 3] la figure 3 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un deuxième mode de réalisation de l'invention ;
• [Fig 4] la figure 4 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un troisième mode de réalisation de l'invention ;
• [Fig 5] la figure 5 est une représentation schématique, selon une vue en coupe, du coupe-circuit de la figure 4 illustré dans un deuxième état ;
• [Fig 6] la figure 6 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un quatrième mode de réalisation de l'invention ;
• [Fig 7] la figure 7 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un cinquième mode de réalisation de l'invention ;
• [Fig 8] la figure 8 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un sixième mode de réalisation de l'invention ;
• [Fig 9] la figure 9 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un septième mode de réalisation de l'invention ;
• [Fig 10] la figure 10 est une représentation schématique, selon une vue en coupe, d'un coupe-circuit électrique selon un huitième mode de réalisation de l'invention ;
• [Fig 11] la figure 11 est une représentation schématique, selon une vue en coupe, du coupe-circuit électrique de la figure 6 selon un autre mode de réalisation ;
• [Fig 12] la figure 12 est une représentation schématique de deux coupe-circuits électriques connectés en série.

The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of an embodiment of an electrical circuit breaker given solely by way of example and made with reference to the accompanying drawings, in which:

• [ Fig 1 ] there figure 1 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a first embodiment of the invention, illustrated in a first state;
• [ Fig 2 ] there figure 2 is a schematic representation of the electrical circuit breaker of the figure 1 , illustrated in a second state;
• [ Fig.3 ] there picture 3 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a second embodiment of the invention;
• [ Fig 4 ] there figure 4 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a third embodiment of the invention;
• [ Fig.5 ] there figure 5 is a schematic representation, according to a sectional view, of the circuit breaker of the figure 4 illustrated in second state;
• [ Fig 6 ] there figure 6 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a fourth embodiment of the invention;
• [ Fig 7 ] there figure 7 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a fifth embodiment of the invention;
• [ Fig.8 ] there figure 8 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a sixth embodiment of the invention;
• [ Fig.9 ] there figure 9 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to a seventh embodiment of the invention;
• [ Fig. 10 ] there figure 10 is a schematic representation, according to a sectional view, of an electrical circuit breaker according to an eighth embodiment of the invention;
• [ Fig.11 ] there figure 11 is a schematic representation, according to a sectional view, of the electrical circuit breaker of the figure 6 according to another embodiment;
• [ Fig. 12 ] there figure 12 is a schematic representation of two electrical circuit breakers connected in series.

THE figure 1 And 2 represent an electrical circuit breaker 2.

The circuit breaker 2 is suitable for use in an electrical system to protect an electrical load connected to an electrical power source.

For example, the circuit breaker 2 is more particularly configured to disconnect an electrical load in response to a control command, for example when an electrical fault is detected in the electrical system.

According to examples given without limitation, the circuit breaker 2 can be used to protect an electrochemical storage battery or a photovoltaic panel.

For example, the control command can be provided automatically by a trigger, or by an electronic control system, or manually by an operator.

The circuit breaker 2 comprises an electrical conductor 10 comprising a first terminal 12 and a second terminal 14, which respectively form input and output terminals of the circuit breaker 2. For example, the conductor 10 is a bar or a tab made of metallic material, such as copper.

The circuit breaker 2 is switchable from a first state, also called “closed state” or “armed state”, to a second state, also called “open state” or tripped state”.

In the closed state, the circuit breaker 2 allows the flow of an electric current through the electrical conductor 10. For example, the first terminal 12 and the second terminal 14 are electrically connected by a main part 16 of the conductor 10.

In the open state, the electrical conductor 10 is severed to separate the first terminal 12 from the second terminal 14 and thus interrupt the electrical current.

The circuit breaker 2 also includes a switch 20.

According to preferred embodiments, described and illustrated in the following by way of example, the switch 20 is a pyrotechnic switch including a pyrotechnic actuator 22 and a cut-off member 24, housed in a first part of a casing of the circuit breaker 2.

Switching device 24 is configured to separate first terminal 12 from second terminal 14 in response to activation of actuator 22.

The member 24 comprises for example a cutting element, such as a blade or a guillotine or a punch, configured to cut the conductor 10, or a mobile body configured to push a pre-cut or weakened portion of the conductor 10.

The cut-off member 24 is movable by translation between a retracted position and an extended position. In the figures, the cut-off member 24 is only visible in its deployed position.

The actuator 22 comprises a pyrotechnic charge which can be triggered by applying a control signal and whose operation propels the cut-off member 24 towards its deployed position to cut the conductor 10.

A seal 26 or other sealing means may be carried by the cut-off member 24 to hermetically close the first casing part.

In alternative embodiments, the switch 20 may be an electromechanical electrical switching device, comprising for example moving parts such as separable electrical contacts operable by means of an actuating mechanism. These moving parts then replace switchgear 24 and portion 16 of electrical conductor 10.

Everything that is described below with reference to the pyrotechnic switch 20 is applicable, mutatis mutandis, to such alternative embodiments.

The circuit breaker 2 also comprises an arc extinguishing chamber 32 partly delimited by a second part 30 of the casing of the circuit breaker 2.

The chamber 32 is associated with the electrical conductor 10 and participates in the interruption of the electrical current between the first terminal 12 and the second terminal 14 when the circuit breaker 2 is switched from the closed state to the open state.

In the open state, the main portion 16 is separated from at least the first terminal 12 or the second terminal 14 and is located at least partly inside the chamber 32. For example, as in the example of the figure 1 , part 16 is detached from terminal 14 but remains attached to terminal 12. Alternatively, part 16 could be completely separated from both terminals 12 and 14.

According to construction examples, illustrated on the figure 1 And 2 , the first and second housing parts are joined and aligned in a first direction, for example a vertical direction, and the conductor 10 extends in a second direction perpendicular to the first direction, for example in a horizontal direction. Other configurations can however be used as a variant.

For example, the casing is made of an electrically insulating material, such as a polymer.

In practice, when the conductor 10 is severed while an electric current is flowing therein, an electric arc (denoted A) forms in the chamber 32 between the two severed ends of the conductor 10, for example between the free end of the main part 16 and the cut end of conductor 10 which remains connected to terminal 14.

As long as the electric arc A remains present, the electric current continues to flow between the terminals 12 and 14. It is therefore understood that the electric arc A must be extinguished for the electric current to be effectively interrupted by the circuit breaker 2.

The circuit breaker 2 further comprises a fuse 40 arranged to be electrically connected in series between the first terminal 12 and the second terminal 14 after the tripping of the switch, as explained in more detail below. In the closed state, fuse 40 remains disconnected from terminal 12. In the example shown, the other end of fuse 40 remains permanently connected to terminal 14.

The fuse 40 comprises at least one electrode 42 extending inside the internal volume defined by the housing part 30 delimiting the extinguishing chamber 32.

A second electrode 44 of fuse 40 is connected to one of terminals 12 or 14 of the conductor.

The free end of electrode 42 protruding into chamber 32 here bears the reference "46". The free end 46 corresponds to the portion of the electrode 42 which is inside the chamber 32.

The connection of the fuse 40 to the other terminal of the conductor 10 can therefore only be made through the intermediary of the extinguishing chamber 32, either by bringing the electrode 42 into direct contact with said terminal, or by intermediary of an electric arc A' between said terminal 12 and electrode 42.

In general, the term "fuse" here denotes any component, such as a dipole, capable of dissipating energy to interrupt an electric current crossing. According to one example, the fuse 40 may include at least one fuse blade arranged in a fuse body.

The circuit breaker 2 further comprises a connection device comprising an electrically insulating barrier which separates said at least one electrode 42 from the rest of the arc extinguishing chamber 32.

According to embodiments such as that illustrated on the insert (a) of the figure 1 , the electrically insulating barrier comprises a wall 50 which delimits a closed volume 52 within the extinguishing chamber 32. The volume 52 is filled with an electrically insulating medium, such as air or vacuum. The barrier can however be made differently.

Advantageously, the barrier is configured to be broken after the triggering of the switch 22 only when at least one or the other of the temperature or the pressure inside the extinguishing chamber of arc 32, or the intensity of an electric arc present in the arc extinguishing chamber 32, exceeds a predefined threshold.

In other words, as long as the barrier has not been broken, it prevents fuse 40 from being connected to terminal 10 even when switch 22 has been tripped and circuit breaker 2 is no longer in the closed state. Electric arc A can therefore be maintained between terminals 12 and 14. The current to be interrupted does not flow through fuse 40.

The electrode 42 cannot be connected to the conductor 10 (in this case, to the terminal 12 in the example of the picture 2 ) only once the barrier is broken, in particular under the direct or indirect effect of the electric arc A, for example due to heating and/or erosion and/or an increase in pressure ionized gases generated by the electric arc A.

Preferably, as illustrated in the figure 2 , once the barrier has been broken, the electric arc A disappears and the connection is then made via a second electric arc A' established between the electrode 42 and the end 16 of the terminal 12.

In other words, the connector device is configured to connect electrode 42 to terminal 12 only after the barrier is broken.

This connection device, implemented by the insulating barrier in the illustrated embodiments, makes it possible to introduce a delay (a delay) between the instant when the actuation device is triggered and the instant when the current to be interrupted is diverted to fuse 40. The value of this delay can be at least partially controlled by choosing barrier construction parameters. In the remainder of this description, this delay may be referred to as a “threshold”.

The threshold required to break the barrier and thus connect the fuse 40 depends indirectly on the intensity of the electric current to be interrupted and can be controlled by choosing certain characteristics of the barrier, such as the melting or sublimation temperature of the material used to form the wall 50 and/or the mechanical strength of the wall 50 and/or the dimensional characteristics of the wall 50 and/or of the volume 52.

This makes it possible to guarantee that the barrier will be broken when the physical conditions in the chamber 32 (conditions characterized by at least one of the following physical quantities: the temperature in the chamber 32, the pressure in the chamber 32, the intensity of the electric arc A) will have reached a predefined threshold.

Thus, the threshold from which the fuse is connected after the pyrotechnic device has been triggered automatically adapts according to the conditions prevailing inside the arc extinguishing chamber. Thanks to this adaptation, the same fuse can be used both to interrupt currents of high intensity and low intensity.

For example, if the intensity of the current to be interrupted is zero or low, the threshold from which the fuse is connected is not reached. The switch works alone, the fuse is never connected to terminal 12. This makes it possible to obtain a fast electrical current interruption time.

For example, if the intensity of the current to be interrupted is high, then the threshold from which the fuse is connected is exceeded. The fuse is then dimensioned to have a sufficiently long pre-arcing time, in order to allow the gases of the chamber 32 to cool and to de-ionize.

As will be explained through the examples below, the wall 50 can be a fusible wall which is destroyed by melting or by sublimation above a predefined temperature, or a wall which deforms or breaks above a preset pressure.

According to embodiments, the wall 50 is made of an electrically insulating material. The wall 50 therefore electrically isolates the electrode 42 (for example, at least the portion of the electrode 42 which is inside the chamber 32) from the rest of the chamber 32. The insulating properties of the barrier are therefore due to the insulating properties of the barrier 50, although the volume 52 of air or vacuum can also participate in this insulation. The volume 52 can however be omitted when the wall 50 is sufficiently insulating.

In other embodiments, the electrical insulation properties of the barrier come from the electrically insulating properties of the volume 52 of air or vacuum, the wall 50 then serving only to contain this volume 52 and to keep it separate. from the rest of the extinguishing chamber 32 until the wall 50 is broken.

In such a case, the wall 50 can be made of an electrically conductive material, for example metal, the volume 52 being sized to by itself electrically insulate the electrode 42 from the rest of the chamber 32 and from the wall 50. in contact with the electrode 42 is ensured not by breaking the wall 50, but by deforming the wall 50 until it comes into direct contact with the end 46 of the electrode 42 so as to be electrically in contact with the latter. An electrical connection between the fuse 40 and the conductor 10 can then be established by the electric arc A' which is established between the wall 50 and the terminal 16.

According to examples, the fusible wall 50 is made of polymer, for example polyamide or polypropylene or polyimide, or elastomer, or polyester, or silicone, these materials possibly including a mineral filler such as glass fibers or graphene.

According to examples given by way of illustration, the polymide wall may have a thickness of less than 300 μm, or even less than 100 μm, or even less than 50 μm. The polypropylene wall may have a thickness of less than 450 μm, or even less than 300 μm, or even less than 100 μm.

In the example illustrated in the insert (a) of the figure 1 , the wall 50 is added inside the chamber 32.

However, as a variant, the wall 50 can be formed in one piece with the walls of the second housing part 30, as illustrated on the insert (b) of the figure 1 , the precise shape of the wall 50 illustrated in this figure not necessarily being limiting. This simplifies the manufacturing process, since the wall 50 can be manufactured at the same time as the rest of the casing 30, for example by molding. For example, an added bottom wall 53 can be used to close the rear of the housing 52.

According to embodiments given by way of example, the walls of the second casing part 30 can comprise a housing which opens into the chamber 32 and in which the end 46 of the electrode 42 is arranged. The wall 50 is arranged in the opening of the housing so as to close this housing.

The dimensions of the wall 50, and in particular its thickness, depend on the material chosen and on the threshold value retained for the temperature or for the pressure.

According to a non-limiting example given by way of example, the wall 50 has a thickness of less than 0.5 mm or 0.1 mm. The volume 52 here has a cylindrical shape with a diameter equal to 3mm and a height equal to 2mm.

For example, volume 52 is less than or equal to 50 mm ³ .

As a variant, the wall 50 can be replaced by a separation element not necessarily having the shape of a plate, such as a separation membrane, or one or more seals.

According to other embodiments of the invention which are not illustrated in the figures, the wall 50, when it is formed from an electrically insulating material, can be covered with an electrically conductive coating on its external face, c that is to say its face directly exposed towards the chamber 32. This conductive coating makes it possible to attract the electric arc A as close as possible to the wall 50, which makes it possible to accelerate the rate of degradation of the wall 50.

There picture 3 shows a circuit breaker 302 according to another embodiment of the invention.

The circuit breaker 302 is similar to the circuit breaker 2 except that it further comprises a control circuit 310 and a second actuator 312, arranged to break the insulating barrier in response to a control signal emitted by the control circuit 310 .

In the illustrated embodiment, the actuator 312 is a pyrotechnic actuator, similar to the actuator 22. Alternatively, the actuator 312 can be an electromagnetic actuator or a piezoelectric actuator or use any other suitable motorization means to break the barrier 50.

The control circuit 310 comprises an electronic processing unit 314 (for example a processor, such as a microcontroller) and a sensor 316 for measuring at least one physical quantity relating to a condition inside the chamber 32.

Circuit 310 is configured to trigger second pyrotechnic actuator 312 so as to break said barrier when said measured condition exceeds a predefined threshold. For example, the condition is a temperature in chamber 32, or a pressure in chamber 32, or the intensity of the current flowing in conductor 10.

In the example illustrated, the sensor 316 is configured to measure the current flowing in the conductor 10 when the electric arc A is established between the terminals 12 and 14. When the measured current exceeds the predefined threshold value, the second actuator 312 is triggered.

According to one example, the second actuator 312 is arranged outside the chamber 32 by being placed facing the wall 50 through an opening 318 formed in the housing part 30. During the ignition of the consecutive pyrotechnic charge on activation of the actuator 32, the pressure wave created by the operation of the pyrotechnic charge is at least partly channeled through the passage 318 and reaches the wall 50, causing it to rupture and opening an electrical conduction path between electrode 42 and conductor 10.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 302.

THE figure 4 And 5 represent a circuit breaker 402 according to another embodiment of the invention. The circuit breaker 402 is illustrated in its closed state on the figure 4 and in its open state on the figure 5 .

The circuit breaker 402 is functionally similar to the circuit breaker 2 but differs from the latter in certain construction details and in particular in the way of constructing the insulating barrier of the connection device.

The elements of the circuit breaker 402 which are similar to those of the circuit breaker 2 or which play a role similar to the latter carry the same numerical reference as the latter, increased by the quantity “400”. For example, fuse 440 is similar to fuse 40. The description given above of these elements with reference to embodiments of circuit breaker 2 can be transposed to circuit breaker 402.

In the circuit breaker 402, the conductor 410 is in the form of a blade or a tongue comprising terminals 412 and 414 connected together by the central part 416, the latter possibly being pre-cut or weakened with respect to the terminals 412 and 414.

The circuit breaker 402 has a body (a casing) having a cylinder shape with an axis Z402. The first part 420 of the casing comprises walls which delimit a central housing 426 centered on the axis Z402 and in which are arranged the pyrotechnic charge 422 of the pyrotechnic switch and a mobile body 424 able to move by translation in the housing 426 along the Z426 axis.

The arc extinguishing chamber 432 is delimited by the walls of the second part 430 of the casing and extends in the extension of the central housing 426.

For example, the housing 426, the chamber 432 and the movable body 424 have a cylindrical shape.

As long as the circuit breaker 402 is in the closed state, the central portion 416 of the conductor 410 extends across the housing 426, perpendicular to the direction Z402.

The fuse 440 comprises a first electrode 442 and a second electrode 444, which are partly inserted into the walls of the second housing part 430 and which open into the extinguishing chamber 432 via ends 446 and 448, respectively. For example, the ends 446 and 448 are placed face to face.

The insulating barrier includes an O-ring 450 placed in the chamber 432 facing the ends 446 and 448 of the electrodes of the fuse 440.

For example, the seal 450 is arranged coaxially with the axis Z402 while being pressed against the walls of the chamber 432. The seal 450 has a central opening configured to let the mobile body 424 pass when it is in its deployed position after triggering. pyrotechnic charge 422.

For example, the seal 450 is made of elastomeric material, for example polypropylene, or PTFE, or silicone, or any other suitable material.

Advantageously, a second O-ring 452 is placed in chamber 432, above seal 450, coaxially with direction Z402. The second seal 452 prevents an electric arc from coming out of the chamber 432 when the current is cut off.

Advantageously, a third O-ring 454 is arranged in chamber 432, below seal 450, coaxially with direction Z402. The third seal 454 makes it possible to prevent an electric arc from being able to pass through the main part 16 when the current is cut off (the latter having been pushed towards the bottom of the chamber 432 by the mobile body 424 after triggering of the load 422).

Preferably, seals 452 and 454 have a higher strength than seal 450, because the latter is configured to fail when conditions in the chamber require it, while seals 452 and 454 must maintain the sealing of the chamber. extinction during the operation of the circuit breaker.

For example, seals 452 and 454 are made of elastomeric material, for example PTFE or silicone, preferably silicone filled with a mineral material, such as mica.

Advantageously, at least one vertical seal 456 in the form of a strip connects the seals 450, 452 and 454 by extending along the walls of the chamber 432, for example by extending parallel to the direction Z402. Although only such a vertical seam 456 is visible on the figure 4 , in practice several such seals can be arranged in the chamber 432.

For example, the vertical seal 456 is made of elastomeric material, for example PTFE or silicone, for example silicone charged with a mineral material, such as mica, preferably in the same material as the seals 452 and 454.

There figure 6 shows a circuit breaker 502 according to another embodiment of the invention.

The circuit breaker 502 is similar to the circuit breaker 2 but differs from the latter in that the insulating barrier comprises a metal capsule 550 mounted in a sealed manner around the end 46 of the electrode 42 and which defines a volume 552 comparable to volume 52, as illustrated by the insert (a) of the figure 6 .

As long as the metal capsule 550 is intact, the electrode 42 is isolated from the rest of the chamber 32 by the air or by the vacuum contained in the volume 552.

When the pressure in the chamber 32 exceeds the predefined pressure threshold, the capsule 550 undergoes a deformation which forces it to come into direct contact with the electrode 42, preferably with the free end 46 of the electrode 42, at the level of a deformation zone 554, as illustrated schematically by the insert (b) of the figure 6 . In doing so, the electrode 42 is in electrical contact with the capsule 550, even if the latter is not broken and an electrical contact can be established by an electric arc between the electrode 42 and the conductor 10.

According to another variant, the end 46 of the electrode 42 has a point shape and is configured to perforate the capsule 550 when the latter deforms and comes into contact with the end 46. This perforation forms an orifice in the capsule 550, through which the interior of volume 552 is placed in communication with the rest of chamber 32. The insulating barrier is thus broken and electrical contact can be established by an electric arc between electrode 42 and conductor 10.

This variant can advantageously be implemented in the case of a capsule or a wall which is not necessarily metallic or electrically conductive, for example in the case of a membrane or an insulating barrier made of plastic.

According to another variant, the capsule 550 is configured to be ruptured when the pressure in the chamber 32 exceeds the predefined pressure threshold. For example, a pre-cut is formed beforehand on one face of the capsule 550. In the event of overpressure, the pre-cut zone detaches totally or partially from the rest of the capsule, thus forming an orifice in the capsule 550, through which the inside of the volume 552 is placed in communication with the rest of chamber 32. The insulating barrier is thus broken and electrical contact can be established by an electric arc between electrode 42 and conductor 10.

This variant can advantageously be implemented in the case of a capsule or a wall which is not necessarily metallic or electrically conductive, for example in the case of a membrane or an insulating barrier made of plastic.

According to alternative embodiments not illustrated, the capsule 550 can be replaced by one or more metal walls.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 502.

It should be noted that, in this example, the wall 30 of the arc extinguishing chamber 32 comprises a reinforcement zone 560 which protrudes inside the chamber 32 to guide the electric arc A towards a particular location. of room 32.

This reinforcement zone 560 is not essential and can be omitted as a variant. In alternative embodiments, one or more reinforcement areas 560 could be used in the circuit breakers according to the other embodiments described herein.

There figure 7 shows an electrical circuit breaker 602 according to another embodiment of the invention.

The circuit breaker 602 is similar to the circuit breaker 2 but differs from the latter in that the insulating barrier comprises an electrically insulating coating 650 deposited on the end 46 of the electrode 42 and, preferably, on the entire part of the electrode 42 which extends into the chamber 32. The coating 650 isolates the electrode 42 from the rest of the chamber 32 and prevents the establishment of an electrical contact, even by means of an electric arc, between electrode 42 and conductor 10. Coating 650 is configured to melt when the temperature in chamber 32 exceeds a preset temperature. By melting or sublimating, the coating exposes electrode 42 and allows electrical contact to be established with conductor 10.

According to examples, the coating 650 is made of polymer, for example polyamide or polypropylene or polyimide. Alternatively, coating 650 is enamel. For example, the electrode 42 is formed by connecting to the fuse 40 a portion of enameled wire.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 602.

There figure 8 shows an electrical circuit breaker 702 according to another embodiment of the invention.

The circuit breaker 702 is similar to the circuit breaker 2 but differs from the latter in that it comprises two fuses 710, 720 in place of the fuse 40. For example, the first fuse 710 comprises a first electrode 712 which leads inside the chamber 32 and a second electrode 714 connected to the conductor 10, for example here connected to the terminal 14. Similarly, the second fuse 720 comprises a first electrode 722 which opens inside the chamber 32 and a second electrode 724 connected to conductor 10, for example here connected to terminal 14 via a common electrode with electrode 714.

The two fuses 710 and 720 have different ratings.

For example, fuse 710 has a current rating of 50 A and fuse 720 has a current rating of 150 A.

A first insulating barrier is associated with the electrode 412 of the first fuse 410 and a second insulating barrier is associated with the electrode 422 of the second fuse 420. The first and second insulating barriers are as previously described. For example, the first barrier comprises a wall 730 and a volume 732 similar to the capsule 550 and to the volume 552. Similarly, the second barrier comprises a wall 740 and a volume 742 similar to the capsule 550 and to the volume 552.

Although illustrated here in the form of capsules similar to capsule 550, the walls 730 and 740 can be made differently. For example, these may be walls similar to wall 50.

Advantageously, the first and second barriers are configured to break under different conditions, in particular so as not to break at the same time. For example, the first barrier is configured to break before the second barrier when an electric arc A is present after the conductor 10 has been cut and the temperature and/or the pressure and/or the intensity of the arc is increasing. .

Preferably, the barrier associated with the fuse 410 or 420 having the lower current rating of the two fuses is configured to break before the barrier associated with the other fuse 410 or 420.

The embodiment of the figure 7 can be generalized to other embodiments in which more than two fuses 410, 420 are used.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 702.

There figure 9 shows an electrical circuit breaker 802 according to another embodiment of the invention.

The circuit breaker 802 is similar to the circuit breaker 2 but differs from the latter in that it comprises an additional electrical conductor 860 connected to one of the terminals of the conductor 10 (here to terminal 12), the additional electrical conductor 860 being isolated from the arc extinguishing chamber and comprising a free end 862 which opens inside the volume 52 delimited by the wall 50.

For example, the additional electrical conductor 860 is formed outside the body 30 or in a wall of the body 30 (for example by overmoulding).

In exemplary embodiments, additional electrical conductor 860 is tungsten.

Advantageously, the insulation distance between the end 862 of the additional electrical conductor 860 and the end 46 of the electrode 42 is chosen to allow electrical insulation in the air for an electrical voltage greater than or equal to at least 1 .5 times the electrical voltage of the generator used in the electrical circuit with which the circuit breaker 802 is associated.

Thanks to the insulation distance, no electric arc can be established between the ends 46 and 862 as long as the barrier 50 has not been broken.

After the switch 22, 24 has been triggered, once the barrier has been broken under the effect of the electric arc A, the volume 52 is placed in communication with the ionized atmosphere of the arc extinguishing chamber. The electric arc can then be established between ends 46 and 862, effectively connecting fuse 40 to terminal 12.

The use of the additional electrical conductor 860 makes it possible to connect the fuse 40 with better reliability, since the distance between the ends 46 and 862 can be easily defined during the manufacture of the circuit breaker 802, whereas it is not always possible to predict with precision what will be the distance between the part 16 and the electrode 46 following the separation of the conductor 10.

Alternatively, the wall 50 may include an electrically conductive layer on its outer face, that is to say its face exposed on the side of the chamber 32. This makes it easier to attract the electric arc close to the wall. 50 and facilitate rupture by fusion.

According to another optional variant, which can be combined with the previous variant, the wall 50 may include an electrically conductive layer on its inner face, that is to say on its face which is inside the volume 52. This electrically conductive layer is then capable of providing electrical contact between the 2 electrodes 46 and 862 after the barrier has been broken.

This makes it possible to obtain a threshold depending on both the temperature and the pressure, the "strongest" of these magnitudes then triggering the breaking of the barrier to cause the connection of the fuse 40.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 802.

There figure 10 shows an electrical circuit breaker 902 according to another embodiment of the invention.

The circuit breaker 902 is generally similar to the circuit breaker 2 but differs from the latter in that the connection device does not include a barrier as previously defined separating the end 46 from the rest of the extinguishing chamber. bow.

Instead, the connection device comprises a housing 910 formed in a wall of the body 30 and in which are arranged a barrier 912 and an electrically conductive moving part 914, for example made of metal, slidably mounted in the housing 910.

For example, the housing 910 is a channel, preferably cylindrical in shape, which opens outside the body 30.

The end of electrode 44 of fuse 40 opens into housing 910 via its free end 916. An additional electrode is connected to terminal 14 and opens into housing 910 via its free end 918. For example, ends 916 and 918 are arranged facing each other.

The ends 916 and 918 are separated at a distance from each other, for example with an isolation distance as defined previously.

The moving part 914 is movable between a rest position, in which it remains at a distance from the ends 916 and 918, and an energized position in which it electrically connects said electrode of fuse 40 with said terminal 14, coming into direct contact with the ends 916 and 918.

On the figure 10 , the movable part 914 is illustrated in its rest position. The position occupied by the moving part 914 in the energized position is represented by the dotted outline 914'.

The barrier 912 is arranged to separate the arc extinguishing chamber 32 from the housing 910, for example by closing an entrance to the housing 910.

Barrier 912 is configured to break when the predefined threshold in quench chamber 32 is exceeded.

Thus, the barrier 912 can advantageously be a wall similar to the wall 50 or to the capsule 550.

Preferably, barrier 912 is configured to break when the pressure within arc quenching chamber 32 exceeds the predefined threshold.

Once the barrier has been broken, the moving part 914 is moved from its initial rest position to the energized position 914' under the effect of the pressure increase in the housing 910 caused by the fluidic communication with the chamber 32. In other words, part 914 acts like a piston. This displacement is illustrated by the arrow F1 on the figure 10 .

For example, part 914 has a complementary shape to the shape of housing section 910.

Preferably, the part 914 is mounted in the housing 910 with zero or negative play in order to be able to remain held in the rest position as long as the barrier 912 has not been broken and it has not been moved by the increase in pressure. This limits the risk of the part 914 accidentally moving towards the energized position, for example when the circuit breaker 902 is subjected to a shock or to strong acceleration.

As a variant, for the same purpose, part 914 could be mechanically connected with barrier 912, for example by overmoulding.

Advantageously, the housing 910 includes retaining means 920, such as one or more stops, which limit the movement of the moving part 914 to prevent it from going further than the energized position 914'. Thus, the part 914 remains held in the excited position 914'.

In alternate embodiments, although not drawn on the figure 10 , the circuit breaker 902 could include an additional connection device as defined in the embodiments of the figures 1 to 9 , associated with end 46 of electrode 42.

According to variants, the end 46 and the electrode 42 can be omitted and replaced by an electrode 922 which directly connects the end of the fuse 40 to the terminal 12, without necessarily passing through the arc extinguishing chamber.

Apart from these differences, the description of circuit breaker 2 is applicable to circuit breaker 902.

In the embodiments described above, once the insulating barrier has been broken, contact between electrode 42 and conductor 10 is achieved by means of an electric arc A′. However, according to embodiments not shown, this connection is made directly by bringing the electrode into direct contact with the conductor 10.

For example, the electrode 42 is placed in the chamber 32 in such a way that the severed part 16 comes into contact against the wall 50 (or the capsule 550) after the conductor 10 has been cut. When the barrier is broken (for example by destruction of the wall 50 or the capsule 550), the severed part 16 is in direct contact with the electrode 42.

In the embodiments above, only the electrode 42 of the fuse emerges in the chamber 32. However, according to variants not illustrated, the other electrode 44 of the fuse could also emerge in the chamber 32. In this case, two Separate electric arcs are required to electrically connect fuse 40 to the two terminals 12 and 14 of conductor 10.

In the embodiments described above, the switching devices are described by way of example as being associated with the electrode 42 or with the electrode 44 (and, respectively, with the terminal 12 or with the terminal 14), but it is understood that as a variant, these cut-off devices can be used on the other electrode 44 or 42 of the fuse (and therefore on the other terminal 14 or 12), or even on the two electrodes 42 and 44 at the same time.

Other embodiments are possible. The additional variants described below can be combined with the embodiments previously described according to any technically permissible combination.

According to a variant of the embodiment of the circuit breaker 802 illustrated in figure 9 , the free end 862 of the additional conductor 860 can emerge inside the extinguishing chamber 32, while being outside the volume 52 delimited by the wall 50, the electrode 46 remaining isolated from the rest of the membrane arcing chamber 50

This arrangement makes it possible to place the free end 862 freely in the extinguishing chamber 32, and thus to adapt to the geometry of this chamber of extinction. Even if the free end 862 is then no longer isolated from the terminal 14, the electric arc will anyway pass through the electrode 46 once the wall 50 has been broken.

The free end 862 thus being able to be placed freely, it is possible to place it at a short distance from the electrode 46, for example at less than 500 μm, in order to reduce the length of the electric arc, and therefore to reduce the energy that this electric arc dissipates inside the chamber 52 as well as inside the extinguishing chamber 32.

According to a variant, in particular applicable to the embodiments of the figure 6 And 8 , the metal capsule 550 can be deformable in a bistable manner, that is to say reversibly deformable between a first state in which the capsule is not in contact with the electrode 46, and a second state in which the Electrode 46 is in direct contact with metal capsule 550 to establish electrical conductivity.

The bistable character of the deformation of the metal capsule can be obtained thanks to a specific conformation of the upper wall of the capsule, for example thanks to a curved shape, or a dome shape.

In the example illustrated, in the first state, the domed shape is away from the electrode 46. In the second state, the domed shape is inverted and comes into contact with the electrode 46. This promotes contact with the electrode 46 and ensures a good threshold effect.

According to a particular implementation of this variant, an example of which is illustrated by the figure 11 , the circuit breaker 502 comprises an additional conductor similar to the additional conductor 860, and which connects the terminal 12 to the metal capsule, which here bears the reference 1050. This provides the same advantages as those described with reference to the additional conductor 860.

According to another variant, the free end of the additional conductor can emerge inside the volume 1052 delimited by the capsule 1050.

According to yet another variant, the additional conductor can be connected to the metal capsule even when the capsule is not deformable in a bistable manner, like the capsule 550 previously described.

According to a variant of the embodiment of the circuit breaker 902 illustrated in figure 10 , the moving part 914 is coupled to a return member, such as a coil spring or a preloaded spring, configured to push the moving part back to its energized position.

As long as the barrier 912 is not broken, the moving part 914 remains in position in the rest position. When the barrier 912 is broken, the movable part is moved towards the excited position in particular under the action of the return member.

This prevents the movable part 914 from not completely establishing electrical contact with the ends 916 and 918 in the event that the barrier has been broken but the conditions in the extinguishing chamber are not sufficient to completely move the barrier. moving part 914.

In general, the circuit breakers according to one or more of the embodiments described above can be connected together, for example in series or in parallel, by means of their respective terminals 12, 14, to form a device circuit breaker with increased performance.

According to optional embodiments, as illustrated in the figure 12 , when two circuit breakers 1100 and 1102 are connected together, the fuse 40 of one of the circuit breakers can be omitted and replaced by an electrical conductor 1110 connecting their respective electrodes 42.

The embodiments and the variants envisaged above can be combined together to give rise to new embodiments.

Claims (17)

1. An electric circuit breaker, including:

   - an electrical conductor (10) comprising a first terminal (12) and a second terminal (14);

   - a switch (22, 24) configured to separate the first terminal from the second terminal when it is tripped in response to a current cutoff order;

   - an arc extinguishing chamber (32) delimited by a body of the circuit breaker, the arc extinction chamber being configured to receive, after the switch is tripped, a portion (16) of the electrical conductor separated at least from the first terminal or the second terminal;

   - a fuse (40) configured to be electrically connected between the first and second terminals after the switch is tripped;

   the circuit breaker being characterized in that it includes a connection device comprising a gate (50, 52, 912) configured to be broken after the switch is tripped only when at least one of the temperature, or the pressure inside the arc extinguishing chamber (32), or the intensity of an electrical arc present in the arc extinguishing chamber (32) passes a predefined threshold, the connection device being configured to connect an electrode (42, 916) of the fuse (40) to one of the terminals (12, 918) of the electrical conductor (10) only once the gate (50, 52, 912) is broken.
2. The circuit breaker according to claim 1, wherein at least one electrode (42) of the fuse (40) extends inside the arc extinguishing chamber (32), the gate being an electrically insulating gate (50, 52) that separates said at least one electrode (42) from the rest of the arc extinguishing chamber (32).
3. The circuit breaker according to claim 2, wherein the insulating gate includes a wall (50) that delimits a volume (52) around said at least one electrode (42) of the fuse (40) in the arc extinguishing chamber (32).
4. The circuit breaker according to claim 3, wherein the wall (50) is electrically insulating.
5. The circuit breaker according to claim 3 or claim 4, wherein the wall (50) is configured to melt when the temperature in the arc extinguishing chamber (32) passes a predefined threshold.
6. The circuit breaker according to claim 3 or claim 4, wherein the wall (50) includes a precut area configured to detach and to form an opening in the wall (50) when the pressure in the arc extinguishing chamber (32) passes a predefined threshold.
7. The circuit breaker according to claim 2, wherein the insulating gate includes an electrically insulating coating (650) deposited on said at least one electrode (42) of the fuse (40) in the arc extinguishing chamber (32), this coating being configured to melt when the temperature in the arc extinguishing chamber (32) passes a predefined threshold.
8. The circuit breaker according to any one of claims 3 to 6 or according to claim 7, wherein the wall (50) or the coating (650) is covered with at least one electrically conductive outer layer.
9. The circuit breaker according to claim 3, wherein the wall (50) is made from metal.
10. The circuit breaker according to claim 3 or claim 9, wherein the wall (550) is configured to deform when the pressure in the arc extinguishing chamber (32) passes a predefined threshold, until it comes into contact against the free end (46) of said at least one electrode (42).
11. The circuit breaker according to claim 10, wherein the free end (46) of said at least one electrode (42) is configured to perforate the wall (550) when the wall (550) deforms and comes into contact with said free end (46).
12. The circuit breaker according to claim 3 or claim 9, wherein the wall (50) includes a precut area configured to detach and to form an opening in the wall (50) when the pressure in the arc extinguishing chamber (32) passes a predefined threshold.
13. The circuit breaker according to claim 2, wherein the circuit breaker (302) includes a control circuit (310), a sensor (316) for measuring a condition inside the arc extinguishing chamber (32) and an auxiliary actuator (312) configured to break the insulating gate and in which the control circuit (310) is configured to trip the auxiliary actuator (312) when a physical property measured by the sensor (316) passes a threshold value.
14. The circuit breaker according to any one of the preceding claims, wherein the circuit breaker (702) includes an additional fuse (720) configured to be electrically connected between the first and second terminals after the switch is tripped, at least one electrode (722) of the additional fuse extending inside the arc extinguishing chamber (32), the circuit breaker further including an electrically insulating additional gate (740, 742) that separates said electrode (722) of the additional fuse from the rest of the arc extinguishing chamber (32), said gate being configured to be broken after the switch is tripped only when at least one of the temperature, or the pressure inside the arc extinguishing chamber (32), or the intensity of an electrical arc present in the arc extinguishing chamber (32) passes a predefined threshold, this threshold being different from the tripping threshold associated with the insulating gate of the other fuse (710).
15. The circuit breaker according to any one of claims 3, 4, 5, 6, 8, 9, 10, 11, 12 or according to claim 14 combined with any one of claims 3, 4, 5, 6, 8, 9, 10, 11, 12, wherein the circuit breaker (802) includes an additional electrical conductor (860) connected to one of the terminals (12) of the electrical conductor, the additional electrical conductor (860) being insulated from the arc extinguishing chamber and including a free end (862) that opens to the inside of the volume (52) delimited by the wall (50).
16. The circuit breaker (902) according to claim 1, wherein the connection device includes an electrically conductive movable part (914) that is movable between an idle position and an excited position in which it electrically connects said electrode (916) of the fuse (40) with said terminal (14), the movable part being mounted sliding in a housing (910) of the circuit breaker (902), the gate being arranged so as to separate the arc extinguishing chamber from the housing (910) and being configured to break when the predefined threshold is passed.
17. The circuit breaker according to any one of the preceding claims, wherein the switch (22, 24) is a pyrotechnic switch.

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