FR2977067A1 - Arc guide device for ultra terminal type low-voltage circuit breaker, has arc guiding magnet to channel flux lines present during separation of contacts of circuit breaker so as to guide arc in separation of contacts - Google Patents

Abstract

The device has an arc guiding magnet (17) to channel flux lines present during separation of contacts (6, 7) of an ultra terminal type low-voltage circuit breaker so as to guide an arc in the separation of the contacts, where the arc is deflected laterally to one side or the other side of a plane containing the contacts under the influence of components of the circuit breaker. The arc guiding magnet includes a plate (19) formed of ferromagnetic material and positioned in vicinity of separation of the contacts, where the plate extends parallel to the plane. An independent claim is also included for an ultra terminal type low voltage circuit breaker.

Description

ARC GUIDING DEVICE IN AN ELECTRICAL PROTECTION APPARATUS AND ELECTRICAL PROTECTION APPARATUS COMPRISING SUCH A DEVICE.

The present invention relates to a device for guiding the arc in an electrical protection device, said device being housed in a housing and comprising two contacts housed between two facing walls relative to each other belonging to the housing, whose at least one is movable relative to the other, between a first position in which the contacts are closed and allowing the passage of current and a second position in which the contacts are separated and the current flowing between the two contacts is interrupted , the separation of the contacts causing the occurrence of an electric arc, said electric arc being subjected to the Laplace force tending to direct the arc to a prechamber of cutoff, said arc being able to be deflected laterally on one side or the other. other of the plane containing the two contacts under the influence of the constituent elements of the electrical protection apparatus.

Interruption of the electrical current by contact separation helps to protect goods and people from the effects of short-circuit currents.

The invention relates more particularly to the field of ultra-thin type protection circuit breakers. The incipient electric arc at the separation of the contacts is subjected to the force of Laplace which tends to direct it towards the prechamber. A problem arises more particularly during electrical endurance tests for very low currents. Indeed, the devices do not succeed the normative cycle imposed by the standard. After a certain number of cycles, it is observed that the side walls are burnt and destroyed, resulting in heavy pollution of the contact area. An in-depth examination shows that there is a particular side where this destruction appears, which suggests that Laplace's force is laterally deflected.

Currently, this problem in electrical endurance is not solved. The investigations carried out show the complexity of the impact on the arc start and the interactivity of all the elements constituting the circuit breaker, namely the current circuit itself with the magnetic coil, the moving contact, the braid , but also all the ferromagnetic parts such as the magnetic carcass, the breaking chamber, the bimetallic strip. To give an order of magnitude, the weight of the lateral component of the Laplace force is of the order of 40% of the propulsion component. This problem is a consequence of the use of the plunger actuators in the current circuit breakers and also the clockwise winding of the coils in top view of the apparatuses when these are mounted on a mounting bracket. As a consequence of the foregoing, the electric arc during the separation of the contacts is deflected laterally, which causes a degradation of the wall located in the vicinity of the contacts, which can lead to pollution of the contact zone and therefore to degradation. cutoff characteristics. Thus, the product does not end the normative cycle of electrical endurance.

Known arc blowing devices having two blower cheeks integral with the housing of the apparatus and capable of guiding the arc in the direction of the interrupting chamber when the arc has left the contacts after switching. .

The present invention solves these problems and proposes a device for guiding the arc in an electrical protection device making it possible to improve the characteristics of the cut-off and electrical endurance of the apparatus, as well as an electrical protection apparatus comprising such a device.

A and the effect of the present invention is a device for guiding the arc for an electrical protection device, this device being characterized in that it comprises magnetic guide means of the arc able to channel the lines of flux present during the separation of the contacts, in the vicinity of these contacts, on one side or the other of said plane, so as to guide the arc d separation of the contacts to recall it in the above plane.

According to a particular characteristic, the aforementioned guiding means comprise at least one part made of a ferromagnetic material positioned opposite and in the vicinity of the point of separation of the contacts, said part extending substantially parallel to the aforementioned plane.

According to a particular embodiment, the aforementioned part comprises a substantially parallelepiped-shaped plate, said plate having a height substantially corresponding to the separation distance of the contacts in the open position and having a width substantially corresponding to that of the contact patch fixed to the fixed contact. .

According to another embodiment, this part comprises an L-shaped plate comprising a first substantially parallelepiped-shaped portion positioned opposite and in the vicinity of the point of separation of the contacts, said portion extending substantially parallel to said plane, having a corresponding height. substantially at the separation distance of the contacts in the open position, and a second return portion adapted to be placed against the face of the fixed contact opposite to that supporting the wafer, this second part being facing substantially half of the contact patch .

According to a particular characteristic, this part is integrated with one of the walls 20 of the aforementioned housing during the molding of said housing. Advantageously, this piece is fixed to the aforementioned wall by tight fitting or gluing.

According to another embodiment, said part is coated with an insulating material and fixed on the fixed contact. Advantageously, said piece is clipped on the fixed contact. According to a particular characteristic, said piece has a thickness of about 0.8 mm.

According to another characteristic, the part is positioned on the side of the wall 30 opposite to that on which there is a degradation problem during electrical endurance tests for very low currents. The present invention further relates to a low-voltage circuit-breaker of the ultra-terminal type comprising a guiding device comprising the aforementioned characteristics taken alone or in combination.

According to a particular characteristic, this circuit breaker comprising a current circuit comprising an actuator comprising a magnetic coil, this circuit breaker is characterized in that, viewed from above the apparatus when it is fixed on a mounting bracket, the direction of winding of the turns of the actuator coil is a clockwise direction. But other advantages and features of the invention will become more apparent in the detailed description which follows and refers to the accompanying drawings given solely by way of example and in which:

FIG. 1 is a perspective view illustrating a circuit breaker according to the prior art, one of the parts of the cover having been removed so as to show the inner part of the circuit breaker,

FIG. 2 is a partial perspective view, illustrating part of the mechanism of the circuit breaker of the preceding figure,

FIG. 3 is a perspective view, illustrating a portion of the casing of a circuit breaker according to the invention, according to a first embodiment of the invention,

FIG. 4 is a partial perspective view, illustrating a part of the mechanism of a circuit breaker according to a second embodiment of the invention,

FIG. 5 is an enlarged view of FIG. 4; FIG. 6 is an enlarged view of a portion of FIG. 3;

FIG. 7 is a view identical to FIG. 3, but according to a third embodiment of the invention, FIG. 8 is a view identical to FIG. 4, but according to a fourth embodiment of the invention, FIG. 9 is an enlarged view of FIG.

FIG. 10 is an enlarged view of part of FIG. 7,

In Figure 1, we see a low-voltage electrical circuit breaker D to be placed in an electrical circuit so as to protect goods and people from the effects of short-circuit or overload currents. This apparatus is housed in a casing B of substantially parallelepiped shape having a rear face 1 for attachment to a mounting bracket (not shown), two faces (2,3), respectively upper and lower, having the upstream and downstream connection terminals 2a, 3a of the apparatus, and two main faces 4 by which said apparatus can be juxtaposed with a device of the same type. This apparatus comprises a fixed contact 6 and a movable contact 7, a thermal tripping device 8 capable of causing the separation of the contacts when a current overload occurs in the circuit, as well as a magnetic tripping device 9 suitable for opening the contacts in the event of a short circuit. The thermal tripping device 8 comprises, in known manner, a bimetallic strip 10 traversed by the current to be monitored and adapted to cooperate with a trigger bar 11 of the mechanism, said bar 11 being able to release a device allowing the movement of the movable contact 7 towards the opening position. The magnetic trip device 9 comprises a magnetic coil 12 traversed by the current, and a core 13 placed in the center of the coil and able to move an actuating rod 14 of the trip bar 11 when the current exceeds a certain threshold. As is more particularly illustrated in Figures 2, 4 and 8, one 12a of the ends 12a, 12b of the coil 12 is electrically connected to a terminal 3a of the mechanism while the other end 12b of the coil is electrically connected. The fixed 6 and movable contacts 7 are located in a space 15 of the apparatus called pre-chamber, in which place the arc appears before being driven into the breaking chamber 16 by Laplace force. According to the invention, and as illustrated in FIGS. 4 to 10, the circuit breaker comprises a device for guiding the arc 17, able to act on the arc as soon as it is formed, so as to straighten it by increasing the Propulsion component of the Laplace force and decreasing its lateral component. According to the invention, this guiding device comprises one or more ferromagnetic parts 19,20 arranged in the immediate environment of the point of separation of the contacts.

According to a first particular embodiment of the invention illustrated in FIGS. 4 and 5, this guiding device comprises a piece 19 in the form of a parallelepiped-shaped plate of small thickness, of approximately 0.8 mm, said part being fixed in contact with each other. fixed 6 so as to extend in a plane parallel to the plane of the main faces 4 of the housing B of the apparatus and to be located opposite the point of separation of the contacts. Advantageously, the height h of this plate 19 covers the opening distance d of the movable contact 7 and the width 1 of this plate is adapted to that of the contact pad. Advantageously, the fixing of this plate on the fixed contact can be achieved by clipping this piece on the fixed contact after coating said plate with an insulating material. According to a second embodiment illustrated in Figures 3 and 6, the part 19 is integrated with the wall 21 during molding and is fixed in a housing 22 of the wall 21 by tight fitting or gluing. According to a third embodiment illustrated in Figures 7 to 10, this part is an L-shaped plate 20, or half-U, of the same thickness as the parallelepipedal part 19 of the previous embodiment. The vertical part 20a of this half-U is positioned in the same way as the flat part 19 of the previous embodiment, that is to say opposite the separation point of the contacts and in a plane extending substantially parallel to the plane of the contacts. main faces 4 of the housing. According to the embodiment illustrated in FIGS. 8 and 9, this part 19 is coated with an insulating material and clipped onto the fixed contact 6. According to a fourth embodiment illustrated in FIGS. 7 and 10, this L-shaped part is integrated into the wall 21 of the housing during molding. The horizontal part 20b of this plate is placed so as to be located opposite half of the fixed patch 18 of the fixed contact 6. The height k of the vertical part 20a of this L-shaped part covers the opening distance d contact. Its width is adapted to that of the contact pad. This plate 20 is positioned automatically or manually in the envelope by embedding said plate in a housing 22 of the housing provided for this purpose. Maintaining the piece relative to the housing is achieved by a tight fitting of the piece in the housing, or by a bonding of the piece on the housing. If we consider a plane of symmetry passing through the middle of the point of separation of the contacts, in which plane is the two contacts 6,7, and parallel to the main faces 4 of the housing, these parts 19,20 are positioned relative to each other. at this plane on the side of the wall 21 opposite to that on which are noted the problems of degradation of the walls during endurance tests. A magnetic effect is obtained by virtue of the invention, in which the lateral component of the Laplace force is reduced by a factor of 5, which is sufficient to prevent the aforementioned deteriorations. Moreover, there is also another effect on the propulsion component. This is increased by about 25%. The other advantages presented by the invention are that the apparatus according to the invention has a very small footprint in the case of the use of the parallelepiped-shaped piece, which is interesting for architectures whose step would be inferior. at 18mm. This plate also has the advantage of being integrated in a rib of the envelope for the case of the L-shaped piece and therefore, can be used to position the fixed contact.

Note that the size of the plate will be adapted so that its dimensions are of the same order of magnitude as those of the contact pads that can be used to equip these electrical contacts. Among the other elements that can impact the Laplace force components on the arc as soon as the contacts open, the investigations showed the importance of the winding direction of the turns of the actuator coil. It is observed that by choosing a counter-clockwise direction for the winding direction of the circuit breaker coils, that is to say a direction opposite to that usually chosen, it is observed that the lateral component of the Laplace force is canceled.

Thus, by virtue of the invention, the field density around the arc is increased and, since this plate is arranged on only one side, the existing asymmetry is corrected. Thus, an increase of Laplace's force is combined with a rectification of the arc. By thus channeling the flow lines on the right side, the lateral component of the Laplace force is reduced. By reversing the winding direction of the actuator coils, these lateral components are canceled. A device for guiding the arc acting on the arc from the separation of the contacts has thus been realized thanks to the invention, so that this arc penetrates into the prechamber without being deflected laterally, by increasing the magnetic field at the contacts and channeling the flow lines on one side of the contacts, this having the effect of preventing degradation of the walls and thus improve the breaking characteristics and in particular the electrical endurance.

The invention is particularly applicable to all miniature electrical protection devices comprising actuators with electromagnetic coil and especially when it is necessary to reduce the space requirement of the devices for various applications.

Of course, the invention is not limited to the described and illustrated embodiments which have been given by way of example only.

On the contrary, the invention comprises all the technical equivalents of the means described and their combinations if they are carried out according to its spirit. 30

Claims (12)

CLAIMS: 1. A device for guiding the arc in an electrical protection device, said device being housed in a housing and comprising two contacts housed between two facing walls relative to each other belonging to the housing, at least one of which is movable relative to the other, between a first position in which the contacts are closed and allow the passage of current and a second position in which the contacts are separated and the current flowing between the two contacts is interrupted, the separation of the contacts resulting in the occurrence of an electric arc, said electric arc being subjected to the Laplace force tending to direct the arc to a cut-off prechamber, said arc being deflected laterally to one side or the other of the plane containing the two contacts under the influence of the constituent elements of the electrical protection apparatus, characterized in that it comprises magnetic guide means (17) of the arc channeling the flux lines present during the separation of the contacts (6, 7), in the vicinity of these contacts (6, 7), on one side or the other of said plane, so as to guide the arc d separation of the contacts (6,7) to recall it in the aforementioned plan. 2. Guiding device according to claim 1, characterized in that the aforementioned guide means (17) comprise at least one piece (19,20) made of a ferromagnetic material positioned opposite and in the vicinity of the point of separation of the contacts, said piece (19,20) extending substantially parallel to said plane. 3. Guiding device according to claim 2, characterized in that the aforementioned part comprises a plate (19) of substantially parallelepiped shape, said plate having a height (h) corresponding substantially to the distance (d) of separation of the contacts in position. open and having a width (1) substantially corresponding to that of the contact pad (18) fixed to the fixed contact (6). 4. Guiding device according to claim 2, characterized in that this part comprises a plate (20) L-shaped having a first portion (20a) of substantially parallelepipedal shape positioned opposite and in the vicinity of the point of separation of the contacts ( 6.7), said portion extending substantially parallel to said plane, having a height (k) substantially corresponding to the separation distance (d) of the open contacts and a second returnable portion (20b) against the face of the fixed contact opposite to that supporting the wafer (18), this second part (20b) facing substantially half of the contact pad (18). 5. Guiding device according to any one of claims 2 to 4, characterized in that this piece (19,20) is integrated with one (21) of said housing walls B during the molding of said housing. 6. Guiding device according to claim 5, characterized in that this piece (19,20) is fixed to the aforementioned wall (21) by tight fitting or gluing. 20 7. Guiding device according to any one of claims 2 to 4, characterized in that said piece (19,20) is coated with an insulating material and fixed on the fixed contact (6). 8. Guiding device according to claim 7, characterized in that said piece (19,20) is clipped on the fixed contact (6). 9. Guiding device according to any one of claims 2 to 8, characterized in that said piece (19,20) has a thickness of about 0.8mm. 10. Guiding device according to any one of claims 2 to 9, characterized in that the part (19,20) is positioned on the side of the wall (21) oppositée to that on which is noted a problem of degradation during electrical endurance tests for very low currents. 11. An ultra-low voltage type circuit breaker comprising an arc guiding device (17) according to any one of claims 1 to 10. 12. Circuit breaker according to claim 11 comprising a current circuit comprising an actuator comprising a magnetic coil (12), characterized in that, seen from above the apparatus when it is fixed on a mounting bracket, the direction of winding of the turns of the coil (12) of the actuator is a clockwise direction. 20 25 30