EP1115131A1 - Circuit breaker pole with wide arc extinguishing chamber - Google Patents

Abstract

The circuit breaker has fixed and moving contacts together with extinction chamber The 3-phase circuit-breaker layout conforms to established pattern, with 3 single-pole units side-by-side, each with its own fixed contacts, the corresponding moving contacts being ganged on a transverse rotatable bar, ensuring all poles open and close together. When closed, the main current-carrying moving contacts bear, under spring pressure, on bars, part of the fixed contact system (28), that run across the front of an insulating plate (90) forming the floor of the arc extinction chamber (24). A fixed arcing contact (30), centred on the bars and associated with a similar moving contact, is connected to a fan-shaped arcing plate (34) fixed to this floor. This plate's rear edge, deep in the chamber, has a rim of gas-emitting material (92) and lies below a parallel array of flat metal separators (78), regularly spaced, parallel to the chamber floor. Plate front edges are alternately notched (82) to one side and the other of the plate centers. As the circuit breaker's main contacts open, the current transfers to the fixed arcing contact (30) and its moving counterpart, which open slightly later, striking an arc that extends from the fan-shaped plate (34,84 up over the separators, regaining the moving arcing contact via a projecting arcing plate (98) on the chamber top. Arc gases escape (74) via the chamber back-plate (72).

Description

The invention relates to a breaking chamber of a high-voltage low-voltage circuit breaker intensity. For such circuit breakers, there is a particular difficulty when seeks to cut a current under a relatively high voltage, of the order of 600 Volts effective in single-phase, or 1000 Volts effective three-phase, with a fairly low intensity, of the order of 5 to 10 times the rated current of the circuit breaker.

Document EP 0 306 382 describes a multi-pole circuit breaker with molded insulating housing meeting this requirement, containing a control mechanism coupled to a switching bar, so as to ensure the opening and closing of the assembly of the circuit breaker poles. Each pole has a fixed contact member, a movable contact and an arc extinguishing chamber. The fixed contact member includes a fixed conductive range of current supply bearing on the bottom of the housing, main fixed contacts and a fixed arcing contact. The mobile contact member comprises a fixed conductive current supply range also bearing on the bottom of the housing, and a contact system having a plurality of identical main contacts, divided into two series of the same number on either side of a movable arcing contact extending longitudinally along the center line of the pole, the length of the arcing contact movable being greater than the length of the movable main contacts. Bedroom arc extinguishing is arranged above the first range and includes a stack of separators constituted by metal sheets for deionizing the arc, each sheet having a V-shaped notch. A pair of lower and upper arc horns frames the stacking of sheets in the extinguishing chamber. The lower bow horn is secured to the upper face of the first track with the interposition of an insulating screen, by means of three screws which ensure the passage of current between the bow horn and the beach. The three screws are arranged at the vertices of an isosceles triangle, one of the screws being arranged along the center line of the pole near an edge of the insulating shield and a wall of the cut-off gases to the outside and the other two being near the main stationary contacts. The width of the lower bow horn decreases in the direction of the migration of the arc towards the central screw, and the two other screws are on both sides of the fixed arcing contact, and in the vicinity of the corresponding fixed main contacts. When the contacts open, the arc arises in the contact separation zone arc located along the center line of the pole and then develops in the central area from the room. The arc migrates towards the central screw which stabilizes the root of the arc. In end of opening stroke, the distance between the arcing contacts becomes greater than the distance between the main contacts, resulting in a reclassification of the arc at the contacts main on one side of the room. The arc then develops on a second different path, along one side of the chamber, gradually refocusing, and by encountering along its path cold surfaces where absorption occurs efficient of the energy favorable to the extinction of the arc.

In such a device, a large part of the chamber is used for extinguishing the arc. However, we note that one of the sides of the room remains largely untapped, since after the arching of the arc, it only develops on one of the sides of the bedroom. The depth of the chamber, i.e. its longitudinal dimension between the inlet of the chamber and the exhaust gas wall, must therefore be sufficient to provide the volume of energy exchange necessary to extinguish the arc. Now it turns out desirable for a given performance circuit breaker to decrease the depth of the room, while keeping its width, which is a dimension imposed in the practical by installation standards for installers.

Furthermore, document FR 2 604 026 describes a circuit breaker, the lower arc horn of which widens from its front part close to the contacts to its rear part close to the bottom of the extinguishing chamber. The enlarged posterior part constitutes a collecting part whose surface is smaller than the section of an arc root for an arc which would be formed with a constant electric current density corresponding to the breaking current nominal. The objective here is to bring the arc to the collecting part and to stabilize it there. The arc stabilized then develops mainly in the middle part of the chamber. A such a configuration is only effective if the longitudinal dimension of the chamber, i.e. its depth between the fixed contact zone and the rear wall of the chamber serving gas extraction is important. The width of the room can be reduced because it is not used to extinguish the arc.

The invention therefore aims to improve the performance of a low multipole circuit breaker high rating voltage, including a circuit breaker to be adapted to cut nominal current greater than 1000 amperes effective, at a high voltage, of the order of 600 Volts in effective value per phase. It aims in particular to reduce the volume of the room necessary to guarantee the breaking of a current under high voltage, by reducing its depth for a given width. More specifically, it aims to make full use of the chamber volume when the chamber is wide and shallow and / or tall scaled down.

• un organe de contact fixe en matériau conducteur, comportant une zone de contact,
• un organe de contact mobile comportant un ou plusieurs doigts de contact en matériau conducteur, l'organe de contact mobile étant apte à être accouplé audit mécanisme, et à passer d'une position fermée dans laquelle le ou les doigts de contact sont en contact avec la zone de contact de l'organe de contact fixe, à une position ouverte où les deux organes de contact sont séparés,
• une chambre d'extinction d'arc, comportant:
  • deux flasques latéraux parallèles en matériau isolant, situés à égale distance d'un plan géométrique longitudinal médian de la chambre, le plan médian longitudinal délimitant ainsi deux demi-espaces géométriques latéraux contenant chacun l'un des flasques latéraux,
  • une paroi postérieure comportant un ou plusieurs orifices d'échappement de gaz,
  • des séparateurs constitués par des plaques métalliques s'étendant d'un des flasques latéraux à l'autre, sensiblement perpendiculairement au plan médian longitudinal,
  • une ouverture antérieure située à proximité de la zone de contact de l'organe de contact fixe et faisant face à la paroi postérieure,
  • une corne d'arc inférieure en matériau conducteur, reliée électriquement à l'organe de contact fixe, comportant:
    • une partie postérieure située à proximité de la paroi postérieure et pourvu d'un rebord,
    • une partie intermédiaire reliant la zone de contact et la partie postérieure,
  • un fond en matériau isolant,
  • une corne d'arc supérieure en matériau conducteur, les séparateurs étant situés entre la corne d'arc inférieure et la corne d'arc supérieure,

caractérisé en ce que:

• la partie postérieure a une largeur, mesurée parallèlement à un axe perpendiculaire au plan longitudinal médian, plus importante que la largeur de la partie intermédiaire mesurée parallèlement au même axe,
• dans chacun des demi-espaces latéraux, la partie postérieure de la corne d'arc possède au moins un point situé par rapport au flasque latéral situé dans le demi-espace considéré, à une distance qui est inférieure au quart de la distance entre les deux flasques latéraux,
• la distance entre la partie postérieure et chacun des flasques latéraux est inférieure à la moitié de la distance entre chacun des flasques latéraux et le plan médian,
• le fond est muni d'un pourtour en matériau gazogène s'interposant entre le rebord de la partie postérieure et les flasques latéraux.

According to the invention, this objective is achieved thanks to a pole for an electric circuit breaker comprising a housing and a control mechanism capable of passing from a closed position to an open position, said pole comprising:

• a fixed contact member made of conductive material, comprising a contact zone,
• a movable contact member comprising one or more contact fingers of conductive material, the movable contact member being able to be coupled to said mechanism, and to pass from a closed position in which the contact finger or fingers are in contact with the contact area of the fixed contact member, in an open position where the two contact members are separated,
• an arc extinguishing chamber, comprising:
  • two parallel lateral flanges of insulating material, located at equal distance from a median longitudinal geometric plane of the chamber, the longitudinal median plane thus delimiting two lateral geometric half-spaces each containing one of the lateral flanges,
  • a rear wall comprising one or more gas exhaust orifices,
  • separators constituted by metal plates extending from one of the lateral flanges to the other, substantially perpendicular to the longitudinal median plane,
  • an anterior opening situated near the contact zone of the fixed contact member and facing the rear wall,
  • a lower arc horn of conductive material, electrically connected to the fixed contact member, comprising:
    • a rear part located near the rear wall and provided with a rim,
    • an intermediate part connecting the contact zone and the posterior part,
  • an insulating material base,
  • an upper bow horn made of conductive material, the separators being located between the lower bow horn and the upper bow horn,

characterized in that:

• the posterior part has a width, measured parallel to an axis perpendicular to the median longitudinal plane, greater than the width of the intermediate part measured parallel to the same axis,
• in each of the lateral half-spaces, the posterior part of the bow horn has at least one point situated with respect to the lateral flange situated in the half-space considered, at a distance which is less than a quarter of the distance between the two side flanges,
• the distance between the posterior part and each of the lateral flanges is less than half the distance between each of the lateral flanges and the median plane,
• the bottom is provided with a perimeter in gasogenic material interposed between the rim of the rear part and the side flanges.

With a device of this type, after a cut-off test of a lower current, it is observed at 10 times the nominal current under an AC voltage exceeding 600 Volts in value effective single-phase, that the lower bow horn is stressed to the same degree on the two most lateral parts of the posterior end zone. This makes it possible to affirm, although the theoretical explanations are still unclear, that both parties side of the chamber contributed in very close proportions to the absorption of the energy released by the arc, therefore with the extinction of this one. In fact, it is difficult to say whether the traces observed are due to the existence of two arcs developing simultaneously in the room or if they are due to a rapid lateral oscillation of the arc of a side to side of the posterior end region of the bow horn. Still, this layout allows full use of the available width of the room, and therefore obtain high voltage arc break, above 600 volts effective for phase considered, with a shallow chamber.

The invention finds a particularly effective application in terms of reduction of volume if in each part of the chamber delimited by the longitudinal median plane, said point is also located in relation to the rear wall at a distance which is less than a quarter of the distance between each of the side flanges. We are thus assured that the arc will fully use the volume of material made up of the separators.

The invention preferably applies to a relatively wide pole, in in particular a pole whose distance between the contact zone of the fixed contact member and the bottom wall of the chamber is less than the distance between the side flanges of the bedroom. It also applies to a pole whose arc horn is less than a length, measured in the longitudinal median plane, which is less than the largest width of the posterior part of the bow horn, measured along an axis perpendicular to the plane longitudinal median.

Preferably, the metal plates of the separators have an anterior edge provided an asymmetrical notch directed towards one or the other of the lateral flanges.

Preferably, the periphery protrudes towards the inside of the chamber relative to the posterior part of the bow horn or flush with the posterior part of the bow horn. The projecting circumference allows a significant degassing, which contributes strongly creating the desired effect of developing two parallel arcs or an arc oscillating laterally in the two lateral parts of the chamber.

• chaque demi-espace latéral comporte une partie des séparateurs, cette partie des séparateurs ayant un barycentre géométrique,
• dans chaque demi-espace latéral, la distance entre la première zone d'extrémité et le flasque latéral contenu dans le demi-espace est plus faible que la distance entre le barycentre situé dans le même demi-espace et ledit flasque latéral.

According to one embodiment, it is considered that:

• each lateral half-space comprises a part of the separators, this part of the separators having a geometric barycenter,
• in each lateral half-space, the distance between the first end zone and the lateral flange contained in the half-space is less than the distance between the barycenter located in the same half-space and said lateral flange.

• la figure 1 représente une vue d'un pôle d'un appareillage selon un premier mode de réalisation de l'invention, en coupe suivant un plan longitudinal médian d'une chambre de coupure de ce pôle;
• la figure 2 représente en perspective éclatée d'une partie du pôle de la figure 1, montrant notamment la chambre de coupure ;
• la figure 3 représente une vue du dessus du pôle de la figure 1;
• la figure 4 représente une vue d'un pôle d'un appareillage selon un deuxième mode de réalisation de l'invention, en coupe suivant un plan longitudinal médian d'une chambre de coupure de ce pôle;
• la figure 5 représente en perspective éclatée d'une partie du pôle de la figure 4, montrant notamment la chambre de coupure ;
• la figure 6 représente une vue du dessus du pôle de la figure 4.

Other advantages and characteristics of the invention will emerge from the description which follows of various embodiments of the invention, given by way of nonlimiting examples and represented in the appended drawings in which:

• FIG. 1 represents a view of a pole of an apparatus according to a first embodiment of the invention, in section along a median longitudinal plane of a breaking chamber of this pole;
• Figure 2 shows an exploded perspective view of part of the pole of Figure 1, showing in particular the breaking chamber;
• Figure 3 shows a top view of the pole of Figure 1;
• FIG. 4 represents a view of a pole of an apparatus according to a second embodiment of the invention, in section along a median longitudinal plane of a breaking chamber of this pole;
• Figure 5 shows an exploded perspective view of part of the pole of Figure 4, showing in particular the breaking chamber;
• FIG. 6 represents a top view of the pole of FIG. 4.

With reference to FIGS. 1 to 3, a low-voltage multi-pole power circuit breaker 10 comprises a molded insulating housing 12 containing a type 14 control mechanism known, provided with a transverse switching bar 16 common to all of the poles, swiveling in bearings formed in the housing 12. Each pole has a fixed contact member 20, a movable contact member 22 and an extinguishing chamber arc 24 located near the fixed contact member 20.

The fixed contact member 20 includes a current supply range 26 mounted in the bottom of the housing 12, partially under the arc extinguishing chamber 24. The body of fixed contact 20 further comprises two main contact strips 28 (FIG. 2) fixed directly to the current supply range 26 and a median arcing contact 30. The arcing contact 30 is fixed to the current supply range 26 in an intermediate zone between the bars 28 and the chamber 24. The arcing contact 30 extends towards the inside of the chamber 24 by a conductive lower arc horn 34 described in detail below. The current supply range 26, the bars 28, the arcing contact 30 and the arcing horn 34 are made of various conductive metallic materials, and have the same potential. The arcing contact 30 and the bars 28 together constitute a contact area 36 intended for ensuring electrical contact with the movable contact member 22.

The movable contact member 22 comprises a fixed conductive supply path current 40, a support cage 42 pivotally mounted about an axis 44 fixed relative to the housing 12 and a plurality of main contact fingers 46 (Figure 3) placed on the side and on the other side of a middle arc contact finger 48. The contact fingers 46, 48 pivot around a common geometric axis 50, fixed relative to the cage 42, and are recalled to the fixed contact member by contact pressure springs 52. A connecting rod coupling 54 is used for coupling between the cage 42 of the movable contact member 22 and a crank 56 of the switching bar 16 of the mechanism 14. Each finger main 46 includes a contact pad 58, intended to ensure contact with the corresponding contact strip 28 of the fixed contact member 20 when the appliance is in the closed position shown in Figure 1, and a lug 60 protruding beyond from the contact pad to the extinguishing chamber 24. The arcing contact finger meanwhile has a movable arcing contact 62 des intended to ensure contact with the fixed arcing contact 30 of the fixed contact member 20 when the device is in the position closed shown in Figure 1, and a lug 64 protruding beyond the pellet of contact towards the extinguishing chamber 24 with a shape identical to that of the pins 60. The contact fingers 46, 48 are electrically connected to the current supply range 40 through braids 49.

The extinguishing chamber 24 comprises two lateral flanges 68 of insulating material, which are parallel to the section plane of Figure 1 and located equidistant from both sides of it, so that the cutting plane constitutes a longitudinal geometric plane median 70 of room 24 and the pole. A rear wall 72 of gas exhaust is arranged at the rear of the chamber, perpendicular to the lateral flanges 68. This wall 72 has one or more orifices 74 for exhausting the breaking gases. A front opening 76 is arranged near the contact zone 36, opposite the rear wall 72. Separators 78 constituted by flat metal plates extend perpendicular to the median longitudinal plane 70 of the anterior opening 76 at the rear wall 72. The dividers 78 are arranged at a distance from each other so as to leave the possibility of gas circulation between the front opening 76 and the rear wall 72. They are supported laterally by the lateral flanges 68. Each plate 78 has an anterior stop 80 for capturing the electric arc, which has approximately a concave U-shaped curved shape in the plane of the plate or in V with a narrower and asymmetrical notch 82. The separators 78 are stacked so that the notches 82 are alternately on a lateral side and the other from room 24.

The lower bow horn 34, intended to receive the root of the bow when the bow extends from the fixed arcing contact 30 towards the interior of the chamber 24, has a part rear 84 located inside the chamber, and an intermediate portion 85 connecting the part posterior to the fixed arcing contact 30. The width of the posterior part 84, that is to say its largest dimension measured along an axis perpendicular to the plane longitudinal median 70 of the chamber, is important while the intermediate part 85 constitutes a narrower section. The rear part 84 has two lateral surfaces constituting reception areas 86 for the root of an electric arc developing in room 24.

The distance between reception area 86 and the side flange located in the same half-space delimited by the longitudinal median plane 70 is less than half the distance between the flange 68 and the median plane 70, and therefore less than a quarter of the width of the chamber measured between the flanges 68. The reception areas 86 are also relatively close to the rear wall 72 of the chamber. In other words, the horn lower arc 34 has in its rear part 84 and on each lateral side of the chamber at least one point located, relative to the lateral flange located on the same side of the chamber, at a distance less than a quarter of the width of chamber 24 and located, by relative to the posterior wall 72, at a distance less than a third or a quarter of the width of the chamber 24.

The lower bow horn 34 is fixed on a bottom constituted by a plate of material insulator 90, in this case polyamide 6-6 loaded with 30% glass fiber. The part of the plate 90 not covered by the bow horn extends to the flanges 68 and the wall posterior 72. It has a periphery 92 forming a protruding shoulder in the chamber and flush with the periphery of the rear part 84 of the bow horn. Alternatively, the periphery 92 can project towards the inside of the chamber until a height greater than that of the posterior part of the bow horn. Around 92 has a rounded shape of C which matches the shape of the rim of the rear part 84, and in particular reception areas 86, so as to constitute a separation between the posterior part 84 and the posterior wall 72 of the chamber on the one hand, and between the part posterior 84 and the lateral flanges 68 on the other hand. The posterior part 84 of the horn arcing is electrically connected to the field 26 only through the arcing contact 30, and the plate 90 constitutes a continuous solid insulator between the rear part 84 and the pad 26.

An upper bow horn 96, intended to receive the head of the bow at the end of opening of the movable contact member 22, is constituted by a metal plate perpendicular to the median longitudinal plane 70, supported by the lateral flanges. The upper bow horn 96 is substantially parallel to the separators 78 in its rear part and comprises in its front part a flap 98 which at least partially encloses the separators 78 located in the upper part of the room.

The operation of the device according to the first embodiment is as follows:

In the closed position, the switching bar 16 locked by the mechanism 14, and maintains the cage 42 in the position illustrated in FIG. 1. The springs 52 provide a contact pressure between the pads 58 of the main contact fingers 46 and the contact strips 28, as well as between contact 62 of arcing contact finger 48 and the fixed arcing contact 30.

On detection of a low fault current, an electronic trip device acts on the mechanism 14 which causes the opening. The rotation of the switching shaft 16 makes pivot the cage 42 around its axis of rotation 44. The main contact fingers 46 pivot very slightly around the axis of rotation 50, counterclockwise of a watch in FIG. 1, under the effect of the contact pressure springs 52, while remaining in contact with the bars 28. Then they meet a stop of the cage 42, and are driven in solidarity with the cage 42 rotating clockwise around the axis of rotation 44, so that they separate from the bars 28. In principle, the movement of the arcing contact finger 48 is similar, but offset in time, because the spatial offset between the bars 28 and the fixed arcing contact 30. Thus, when the separation of the main contact fingers 46, the arcing contact finger 48 is still in contact with the fixed arcing contact 30. All of the current flowing between the pads 26, 40 then passes through the arcing contacts 30, 62. In a second phase, the contact finger arc 48 in turn encounters a stop of the cage 42 which drives it solidly with the cage 42 in the latter's rotational movement around the axis of rotation 44 of the cage, clockwise, so that separation occurs from the arcing contact finger 48 and the fixed arcing contact 30. An arc arises between the arcing contacts 30. Due to the loop of current formed in range 26 and plate 32, the root of the arc migrates rapidly towards the bottom of the chamber 24, while the head of the arc remains on the lug 64 of the finger contact 48. When the mechanism reaches the open position, the contact fingers 46, 48 are located near flap 98 of the upper bow horn. The bowhead switches then on the upper arc horn 96, and a secondary arc is formed in series with the first, between the flap 98 and the lug 64 of the arc contact finger 48. The arc, penetrating in chamber 24, divides more or less in contact with the separators 78 in an arc elementary, each elementary arc constituting an electrical connection in series between two separators 78 adjacent to or between each arc horn 34, 96 and the separator 78 making it face.

Arriving at the rear of chamber 24, the arc root tends to move to one or other of the lateral reception areas 86 of the bow horn lower. When it is established on one of the lateral reception areas 86, the root of the arc causes the rim of the periphery 92 to be ablated in gas-generating material with a significant emission of gas, especially hydrogen. This nearby gas emission bow root causes constriction of the bow root and prevents the latter to stabilize definitively on the lateral reception area 86 in question.

The next phase of development and extinction of the arc is not perfectly known, the fact that the means of observation are limited and that the theory does not allow a full explanation of the results observed. We observe indeed after extinction of the arc that the two lateral reception areas 86 of the posterior part 84 of the bow horn bear similar traces, with wear significantly greater than the wear of other parts of the bow horn 34. This confirms that the two reception areas side were exposed in a privileged way to an electric arc, in proportions very close to each other. Two hypotheses can be put forward: according to a first hypothesis, the root of the arc located on one of the reception areas 86 would be expelled from emits gas around 92, and migrate laterally to the other area reception 86 where the same phenomenon would occur again, so that we would witness a oscillating movement of the root of the arc between the two lateral reception areas 86. According to another hypothesis, the gaseous emission would cause necking of the root of the arc, such that a re-plating would take place at the other reception area 86, the two arches remaining simultaneously in the room. The presence of two arches simultaneous in parallel in a room being generally a very transient phenomenon unstable which is resolved by the extinction of one of the two arcs, it is suggested that in this case, an exceptional phase oscillation of densities would be established of current of the two arcs, notably under the effect of the emission of gas in the vicinity of each arc which would tend to constrain the arc of greater current density.

In fact, in the absence of visualization tests with an ultra-fast camera, we are not it is not possible to determine exactly which of the two hypotheses is correct. The decisive fact is that we obtain thanks to the combination of the two reception areas side 86 and a gas-generating periphery 92, use of the entire chamber and a balanced energy distribution between the two lateral reception areas 86.

It should be noted that this phenomenon is only significant for breaking the currents low intensity under high voltage. When cutting the intensity currents high under low tension, the arc invades the entire chamber in a conventional manner.

Referring to Figures 4 to 6 is presented a circuit breaker pole according to a second embodiment of the invention. To facilitate the description, the signs of reference used in the description of the first embodiment for the parts similar.

The circuit breaker 10 is contained in a box 12 and includes, as before, a mechanism 14 including a transverse switching bar 16 constituted by a shaft pivoting common to all the poles of the circuit breaker. Each pole has an organ fixed contact 20, a movable contact member 22 and an arc extinguishing chamber 24.

This circuit breaker differs essentially from the previous one by the absence of arcing contacts. The fixed current supply range 26 comprises a single contact strip 36a which cooperates with contact fingers 46a all similar to the movable contact member 40. The end of the contact fingers 46a lying near the axis of rotation 50 comprises a cam 47 cooperating with an elastic energy accumulator 52a taking support on the support cage 42, so as to form a bistable mechanism 53 able to recall the fingers 46a either towards the fixed range 26, or opposite the latter. The operation of the bistable device 53 is described in detail in the patent application French with the registration number FR 9905276. The contact fingers 46a are electrically connected to the current supply range 40 by means of a braid.

A lower arc horn 34 constituted by a conductive metal plate is fixed by a part before the area 26 of the fixed contact member 20. The front part 34a of the lower arc horn located near the contact strip 36a comprises a contact area with the current supply range 26 and is fixed thereto. The part front also has a transverse rim 34b projecting slightly above from the surface of the contact strip 36, in the direction of the contact fingers 46a. The lower bow horn 34 also has a rear portion 84 extending to the interior of the chamber, the width of which is the largest dimension measured along an axis perpendicular to the median longitudinal plane of the chamber, is important. The front part 34a and the rear part 84 are connected by an intermediate part 85 of width less than that of the posterior part. As in the first mode of embodiment, the rear part 84 constitutes two lateral reception areas 86 for a bow.

The bottom of the chamber is constituted by a plate 90 of insulating material. The plaque has an imprint corresponding to the shape of the lower bow horn and in which houses the bow horn 34. The part of the plate not covered by the horn arc constitutes a circumference 92 protruding from the bottom of the imprint, which is flush with the level of the upper edge of the rear part 84 of the bow horn 34. This periphery is interposed on the one hand between the edge of the bow horn and the posterior wall of the chamber, and on the other hand between the edge of the bow horn 34 and the lateral flanges of the bedroom. The entire plate, and in particular the periphery 92, is made up of a gasifier material, in this case polyamide 6-6 loaded with 30% glass fiber.

The operation of the device according to the second embodiment of the invention is the following:

Contact separation can take place either due to electromagnetic repulsion fingers 46a which pivot relative to the cage 42 clockwise beyond the neutral position of the bistable mechanism 53, until finding an end position for race, either following an opening order which causes the mechanism 14 to open, the pivoting of its switching rod 16 and, via the connecting rod coupling 54, the pivoting of the cage 42 around its axis 44 clockwise in Figure 1, which drives the fingers 46a.

The contact fingers 46a separate simultaneously, creating an arc between one fingers 46a and contact strip 36a. By the electrodynamic loop effect of current in the fixed contact member 20, the root of the arc immediately migrates to the rim 34b of the anterior part of the lower bow horn then inwards of the chamber 24. Passing through the narrower intermediate part of the bow horn, the root refocuses with respect to the median plane 70.

The rest of the cut is similar to that of the first embodiment.

Each of the embodiments therefore makes it possible to observe after breaking a current of high tension and moderate intensity, the existence of two traces of arc roots at the level lateral reception areas of the posterior part of the lower bow horn, attesting to the presence of an arc in each lateral part of the chamber. Given the lack of theoretical basis to explain the reproducible result obtained, the characterization of the shape of the posterior part of the lower arch horn cannot be that empirical.

To more precisely locate the relative position of the posterior part of the bow horn lower and separators, the two halves should be considered separately side of the room each located in one of the two half-spaces delimited by the longitudinal median plane. It is then possible to define for each part of the separator being in the half-space considered, a center of gravity. Each of the gravity considered is closer to the lateral flange located in the considered half-plane than from the longitudinal median plane, due to the notch formed by the U-shaped edge of the separators. By connecting together the centers of gravity obtained in half of room, we get a broken line whose points are closer to the flange lateral corresponding only from the median longitudinal plane. By determining the center of gravity previous centers of gravity, in other words the barycentres of the points constituting the centers of gravity each weighted by the corresponding mass of the separator, we also obtains a barycenter or global center of gravity of the material subset consisting of the part of separators contained in the half-space considered, closer from the lateral flange than from the median longitudinal plane.

To fully exploit half of the room, we empirically try to ensure that the root of the arc can stabilize near the previously defined broken line. Indeed, if the arc meets each separator near its center of gravity, it causes relatively uniform heating of the separator, therefore absorption significant thermal.

The posterior part of the bow horn therefore includes an area for receiving the arc root formed by a bulge located approximately in the extension of the previously defined imaginary broken line. This can be achieved by ensuring that a straight line drawn from the global center of gravity previously defined and perpendicular to the plane of the upper surface of the tip of the bow horn meets the arc horn at the reception area.

In the same spirit, we can impose that the distance between the reception area and the flange lateral located in the considered half-space is less than the distance between the center of overall gravity and the lateral flange. We can also add the condition that the distance between the reception area and the rear wall of the chamber is greater than the distance between the global center of gravity and the posterior wall.

Empirically, we obtain a good positioning of the reception areas by imposing that the distance between the reception area and the lateral flange located in the half-space considered is less than half the distance between the flange and the median plane, and therefore less than a quarter of the width of the chamber measured between the flanges. In others terms, the lower bow horn comprises, for each lateral half of the chamber, at minus a point located, relative to the flange located in the half of the chamber considered, at a distance less than a quarter of the width of the chamber. We can add that this point is also located, with respect to the rear wall of the chamber, at a distance less than a third or a quarter of the width of the chamber, to characterize the fact that it it is indeed the posterior part of the bow horn. However, the distance between the horn lower arch and the rear wall of the chamber is inherently less critical.

Furthermore, the role of the narrow intermediate part 85 of the bow horn must be emphasized. lower, which allows centering of the root of the arch during its migration to the bottom of the chamber and which, once the root of the arch reaches the posterior part 84, tends to prevent the arc root from returning to the contact area.

Naturally, various modifications are possible.

In the embodiments presented, the arc always arises at the level of the contact zones, then migrate on the bow horns. However, the invention applies equally well to a circuit breaker arranged in such a way that the arc arises directly between the arc horn lower and the tip of the contact fingers.

In the embodiments presented, the bottom of the chamber and the gas-generating periphery constitute the same piece of gas-generating material. However, it is also possible to bring a perimeter made of gasogenic material to a non-gas-generating insulating background. The edge may be flush with the edge of the posterior part of the bow horn lower, or protrude slightly above the rim of the posterior part of the bow horn.

It also applies to non-limiting circuit breakers, in which there is no of articulation between a support cage and contact fingers, but a contact assembly forming a non-deformable solid coupled to the mechanism.

The invention applies both to single-pole circuit breakers and to circuit breakers multipolar. The shape of the mechanism is arbitrary, with or without a bar switching. The bar, if it exists, can pivot around its longitudinal axis or around of a distant geometric axis.

Claims (7)

Pole for an electric circuit breaker (10) comprising a housing (12) and a control mechanism (14) capable of passing from a closed position to an open position, said pole comprising: a fixed contact member (20) of conductive material, comprising a contact zone (36), a movable contact member (22) comprising one or more contact fingers (46, 48) of conductive material, the movable contact member being able to be coupled to said mechanism, and to pass from a closed position in which the or the contact fingers are in contact with the contact zone of the fixed contact member, in an open position where the two contact members are separated, an arc extinguishing chamber (24), comprising: two parallel lateral flanges (68) of insulating material, located at equal distance from a median longitudinal geometric plane (70) of the chamber, the longitudinal median plane thus delimiting two lateral geometrical half-spaces each containing one of the lateral flanges, a rear wall (72) comprising one or more gas exhaust orifices (74), separators (78) extending from one of the lateral flanges to the other, substantially perpendicular to the longitudinal median plane, a front opening (76) located near the contact area of the fixed contact member and facing the rear wall, a lower arc horn (34) of conductive material, electrically connected to the fixed contact member, comprising: a rear part (84) located near the rear wall and provided with a rim, an intermediate part (85) connecting the contact zone and the rear part, an upper bow horn (96) of conductive material, the separators being located between the lower bow horn and the upper bow horn, characterized in that: the rear part (84) has a width, measured parallel to an axis perpendicular to the median longitudinal plane, greater than the width of the intermediate part (85) measured parallel to the same axis, in each of the lateral half-spaces, the posterior part (84) of the bow horn has at least one point situated with respect to the lateral flange situated in the half-space considered, at a distance which is less than a quarter of the distance between the two side plates, the distance between the rear part (84) and each of the lateral flanges (68) is less than half the distance between each of the lateral flanges and the median plane, the rim of the rear part is bordered by a periphery (92) made of gas-generating material, which is interposed between the rim of the rear part (84) and the lateral flanges (68). Pole according to claim 1, characterized in that in each part of the chamber delimited by the longitudinal median plane, the said point is also situated in relation to the posterior wall at a distance which is less than a quarter of the distance between each of the side flanges. Pole according to claim 1, characterized in that the distance between the contact area of the fixed contact member and the bottom wall of the chamber is less than the distance between the side flanges of the chamber. Pole according to claim 1, characterized in that the arc horn less than one length, measured in the longitudinal median plane, which is less than the longest width of the posterior part of the bow horn, measured along a perpendicular axis in the median longitudinal plane. Pole according to claim 1, characterized in that the metal plates of the dividers have an anterior rim with an asymmetrical notch facing either side flange. Pole according to claim 1 characterized in that the periphery projects towards the interior of the chamber relative to the posterior part of the bow horn or flush with the level of the posterior part of the bow horn. Pole according to claim 1 characterized in that each lateral half-space comprises a part of the separators, this part of the separators having a geometric barycenter, in each lateral half-space, the distance between the first end zone and the lateral flange contained in the half-space is less than the distance between the barycenter located in the same half-space and said lateral flange.

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