FR2987162A1 - Mobile contact/contact carrier assembly for circuit breaker, has traction spring fixed to mobile contact and contact carrier based on orientation such that spring exerts torques in stability positions from positioning change of spring - Google Patents

Abstract

The assembly has a mobile contact (1) mounted to rotate in a contact carrier between stable positions. A traction spring (4) with single or double strands is fixed to the mobile contact and the contact carrier according to an orientation perpendicular to a rotation axis of the mobile contact in the contact carrier such that the spring exerts distinct torques in stability positions limiting an angular variation of the mobile contact in the contact carrier. The stability positions result from a change of positioning of the spring with respect to the axis or the mobile contact.

Description

The present invention relates to a movable contact / contact-holder assembly for circuit-breaker type electric line protection apparatus, in which the mobile contact (s) is (are) rotatably mounted in a contact carrier with an angular displacement allowing dissociation of displacements of the mobile contact (s) and the contact carrier. Such a possibility of relative rotation is sought to improve the operation of the apparatus, as much in a closed position of the line, where it makes it possible, if necessary, to compensate for the wear of the contacts, than during an abrupt opening subsequent to a problem on a line, where the rotational independence makes it possible to accelerate the opening of the contacts even before the lock which equips this kind of products does not rock. In the latter case, the electrodynamic repulsion effect between the fixed contact and the moving contact, also known as a loop effect, is used, which nevertheless implies a particular configuration of the arrival of the current in the fixed contact to create the conditions for such a contact. loop with the arm of the moving contact. The electrodynamic repulsion causes the opening of the contacts at the earliest, in practice as soon as the value of the current in the line has exceeded a few tens of times the rated current, without approaching the rated breaking capacity of the device. This possibility of accelerated opening of the movable contact is useful for example in a circuit breaker with high breaking capacity, in which the aforementioned repulsion effect is used in order to separate as quickly as possible the movable contact from the fixed contact, the rapid increase in the distance between them allowing to have the highest possible arc voltage as soon as possible. To preserve the benefit of this rapid displacement of the decorrellated mobile contact of the movement of the contact carrier, it is necessary to provide that at the end of the stroke, caused by the collision of said contact with any stop, for example a wall of the apparatus, said collision does not cause rotation in the opposite direction, reducing the distance between the contacts and consequently the arc voltage. The rotational displacement of the movable contact in the contact carrier is for this purpose organized between two stable positions, for example by means of the tension spring otherwise used to ensure the contact force, which urges the moving contact in one direction and in a direction. direction generally promoting closure of the contacts, and which can take two positions depending on whether the axis of the spring is located on one side or the other of the axis of rotation of the movable contact. There is therefore a stable position maintaining the movable contact in the remote contact holder of the fixed contact while the contact carrier has not yet begun to rotate. The tripping of the circuit breaker, via the mechanical lock that equips it, then releases the contact carrier, which is for example in the form of a contact bar in the multipolar products, and the contact / contact assembly mobile (in its second stable position) therefore switches. The movable contact then returns to its initial position relative to the contact carrier, ie in its first stable position, following a collision on a stop of the product at the end of tilting, marking the beginning of an inverse rotation of the mobile contact relative to the contact carrier impulsed by said stop. The assembly is then found in the normal opening position of the contacts of the circuit breaker, but configured so that the relative position of the movable contact and the contact carrier allows a closure in the stable position corresponding to such a state. The invention presents original configurations of moving contact / contact-contact assemblies, making it possible to ensure the bistable character of the mobile contacts with technical solutions favoring industrialization under the best manufacturing conditions, leading to favorable economic effects. According to the invention, these solutions are based on a configuration such that, the movable contact being rotatably mounted in the contact carrier between two stable positions, at least one tension spring is fixed on the one hand to the moving contact and on the other hand part of the contact carrier, in an orientation perpendicular to the axis of rotation of the movable contact in the contact carrier. The spring means are arranged such that they can exert two distinct pairs in two stability positions limiting an angular deviation of the movable contact in the fixed contact, said stability positions resulting from a change in positioning of the spring relative to either the axis of rotation of the movable contact is in the moving contact. According to a first variant, the movable contact comprises two symmetrical parts each presenting: an arm fixed to its symmetrical counterpart, a contact pad being placed at the free end of the adjoining arms protruding beyond the contact carrier, and a portion located at the inside of the contact carrier, pivoting between side flanges of the contact carrier, and forming with its symmetrical counterpart a stirrup between the branches of which extends a tension spring fixed on the one hand to the movable contact and on the other hand to the contact carrier, in an orientation perpendicular to the axis of rotation. According to one possibility, one of the homologous parts comprises a tab coming from cutting with the second portion and protruding therefrom towards the other part, and on which a first end of the spring is hooked. Said tab also has a hooking notch of the end of the spring. The second end of the spring is in turn hooked to an axis connecting the side flanges of the contact carrier. In this variant, the rotation of the movable contact in the contact carrier is not implemented by a traversing shaft, because of the need to let the spring change orientation and location relative to the contact carrier between its two stable positions. Thus, the movable contact has on the outer faces of the second portions apart from each other cylindrical-shaped studs pivotable in facing housings formed in the side flanges.

For ease of assembly, said housings have a channel opening at the periphery of the flanges.

According to a second variant of the invention, the movable contact / contact carrier assembly is characterized in that it comprises at least one traction spring fixed in an orientation parallel to the axis of rotation on the one hand in contact with mobile and secondly to a shaft connecting the two flanges of the contact carrier, the ends of said shaft being housed in lateral recesses formed in the flanges allowing it a clearance caused by its interaction with a profile of the movable contact located in the vicinity of the shaft when the moving contact rotates, said profile having a protuberance forming a hard point between a stable support in the lateral recesses and a bearing zone of the profile housing the shaft, corresponding to two stable angular positions for the moving contact. The solution of the second variant is based on the combination between the force of the spring and the profile and more generally the connection of the shaft to the contact carrier, allowing two stable positions of the movable contact.

The recesses housing the ends of the shaft are of trapezoidal shape with rounded inner corners and sides of dimension greater than the diameter of the shaft, and they open at the periphery of the flanges. The displacements, although limited, of the ends of the shaft in the lateral recesses, are necessary mainly to pass over the protuberance forming a hard point when the moving contact rotates, the traction of the spring allowing the stability of the support of the shaft in the bearing area of the profile and in the lateral recesses, imparting a correlative stability to the two angular positions of the movable contact in the contact carrier. More precisely, this profile comprises a protuberance followed by a rounded concavity and an indentation, the protuberance and the concavity having a radius of curvature of the order of the radius of the shaft. Preferably, according to the invention, the spring is a single or double coil spring. The variants of the invention will now be described in greater detail, with reference to the appended figures, for which: FIG. 1 is a perspective view of the moving contact according to the first solution, with the spring and the shaft cooperating with the contact carrier; - Figure 2 shows, still in perspective, the two homologous parts forming the movable contact; FIG. 3 shows, in perspective view, part of a multipole contact bar; FIGS. 4 to 6 show the invention, ie the moving contact / contact carrier assembly, in a circuit breaker box, in its three positions, respectively closed contact, moving contact in the repulsion phase, and open contacts. when the lock has tilted; - Figure 7 is a perspective view of the movable contact according to the second variant; - Figure 8 illustrates in perspective a portion of a multi-pole contact carrier seen from the side which exceeds the movable contact; FIG. 9 is a perspective view of a multipolar contact carrier viewed from the opposite side; - Figures 10 to 12 show the second variant of the assembly of the invention, movable contact / contact carrier, in its three positions, respectively closed contact, moving contact in the repulsion phase and open contacts once the lock tilted, FIG. 10 further showing their implantation in a circuit breaker box. With reference to FIG. 1, the movable contact 1 consists of two symmetrical parts 2 and 3 each having an arm (2a, 3a) and a portion internal to the contact carrier. (2b, 3b) (see below).

Each piece (2, 3) forms with its symmetrical counterpart (3, 2) a stirrup between the branches of which extends a tension spring (4). This tension spring (4) is fixed between a lug (5) in one piece with the workpiece (3) (see FIG. 2) and having a notch (6) for holding the bent end of the spring (4). ).

The other end of the spring (4) clings to a shaft (7) retained in the housing of the contact carrier.

The portions (2b, 3b) of the parts (2 and 3) have, on their outer face, prominent studs (8) intended to pivot in corresponding recesses (9) formed in the lateral flanges of the contact carrier (10) ( see figure 3).

The tab (5) is cut with the piece (3), it is folded to a housing (5 ') provided in the part (2). The pads (8) are made by extrusion of a trimming in the portions (2b) and (3b) of the parts (2) and (3). The operation appears in FIGS. 4 to 6. In FIG. 4, the portion of the circuit-breaker shown is represented with the contacts closed, which means that the patch (11) soldered to the free end of the arms (2a, 3a) is press on the fixed contact (12). The path of the current I is represented by the arrows. When, due to a fault on the line, said current I becomes equal to several tens of times the nominal value of normal operation of the circuit breaker, the current I passing through the contacts (1, 11, 12) creates by electrodynamic effect a tensile force to open the movable contact (1), as shown in FIG. 5. The particular form of the fixed contact (12) and its arrangement relative to the arm of the movable contact (1) promote an electrodynamic repulsion effect due to the flow of electric current I in opposite directions in the two contacts (1, 12), creating a loop effect. It can be seen, in particular in FIG. 5, that at the level of the fixed (12) and movable (1) contacts, the arrows of the current I are in the opposite direction, which is simply obtained by a particular form of the contacts, in particular the fixed contact (12) which induces a current path in the opposite direction to that which flows in the arm of the movable contact (1) in the vicinity of the contact pads (11, 12). This visible repulsion effect in FIG. 5 accelerates the displacement of the moving contact (1), which then precedes any rotational movement of the contact carrier (10), which requires the tilting of the lock.

In the position of Figure 4, the axis (A, A ') of the spring tension force is located to the left of the pivot axis (R) of the contact carrier (10), and said spring (4) ) therefore exerts a torque that urges the movable contact (1) to a stable position, contacts (1, 12) closed. When the moving contact (1) is abruptly pushed back due to the loop effect, as results from FIG. 5, the axis (A, A ') of the spring (4), materializing the axis of application of the pulling force passes on the other side of the axis of rotation (R), and is positioned to the right of it. The traction force therefore exerts a torque in the other direction, preventing the movable contact (1) from closing when it abuts on a stop for example consisting of a wall of the product.

The purpose is to extinguish the electric arc as quickly as possible, and to achieve this the maximum distance between the movable contact (1) and the fixed contact (12), to increase the arc voltage and to extinguish it more easily. When the circuit breaker trips by tilting the lock, as shown in Figure 6, the contact carrier (10) operates in the direction of the arrow (F), that is to say, it goes into the same direction as the direction of repulsion of the moving contact (1). The assembly then undergoes this rotation and the moving contact (1), continuing to move in the same direction, hits a stop of the product, and initiates a reverse rotation relative to the contact carrier (10). The rotational movement of the contact carrier (10) towards its open position "catches" in sum the movable contact (1), which tends to return to its other stable position because the spring passes back to the other side of the axis of rotation (R). When the movable contact (1) arrives in the vicinity of the stop (14) of the contact carrier (10), stop to which it was already, in the closed position (see Figure 4), the movable contact (1) and the door -contact (10) move together to the normal position, open contacts of the circuit breaker, position that appears in Figure 6. The second variant of the invention is shown in Figures 7 to 12, in which the references which are kept s' apply to the same elements or their equivalent strictures. Thus, the movable contact (1) of Figure 7 is movable about a shaft (30) passing through its orifice (20), the shaft whose ends are housed in recesses (9) formed in the faces or flanges facing contact carrier (10) (see figure 8). It comprises a notch (6) for hooking the end of a double tension spring (4) and, at its end close to the orifice (20), it has a particular profile composed of a protuberance ( 21) followed by a rounded cavity (22) and an indentation (23). The precise operation of this profile will be given below, with reference to FIGS. 10 to 12. FIG. 9 shows the side of the contact holder (10) located close to said profile, in operation. The side faces of the contact holder (10) comprise at this level lateral recesses (24) facing towards the periphery of said faces and intended to house a shaft (7) on which it is intended to hang the other end or ends of the spring means (4). The mounting of the shaft (7) is facilitated by the open nature of the recesses (24), the shaft (7) (see Figure 10) being maintained by the tension of the spring or springs (4). Referring to Figure 10, which shows the invention in a circuit breaker (D) which will not be described, not being the subject of the invention, the movable contact assembly (1) / contact holder (10) is represented in the closed position of the contacts (1, 12), the patch (11) of the movable contact (1) being in contact with the patch of the fixed contact (12). The traction spring (4), in this case doubled since there are two located on either side of the movable contact (1), connected by an inverted U-shaped rod inserted in the notch (6) serves contact spring in this position. The torque that it creates plate indeed the movable contact (1) against the fixed contact (12) and catches in particular the possible wear of the contact pads (11, 12). The arm of the movable contact (1) is, in this position, in the vicinity of the stop (14) of the contact carrier (10). The shaft (7) is below the protuberance (21), the ends housed to the left of the recesses (24). This is a stable position of the movable contact (1) relative to the contact carrier (10) When the force due to the electrodynamic effect, exactly under the same conditions as for the configuration subject of the first variant, violently pushes the movable contact (1) by generating a torque opposite to that created by the springs (4) to a position as shown in Figure 2, without the contact carrier (10) still moving, the shaft (7) begins to move towards the wall to the right of the lateral recess (24), against which it comes into abutment because it is pushed by the protuberance (21). Then, the rotation of the movable contact (1) continuing with respect to the contact carrier (10), said shaft (7) crosses the protrusion (21) assisted in this by the possibility of play of the shaft (7) towards the outside opening of the recess (24). Past the hard point constituted by the protuberance (21), the movable contact (1) is in a new stable position, shown in FIG. 11. Thus, even if the moving contact (1) has struck the cover (25), it does not return beyond this second stable position. FIG. 12 is very similar to FIG. 11, but after rotation of the contact carrier (10) which had not turned in FIG. 11. This rotation, induced by the lock of the circuit breaker (D), causes the surface (25) to strike. ) of the contact carrier (10) against the wall (26), causing the occurrence of a new torque which tends to rotate the movable contact (1) in reverse rotation, so that the shaft (7) returns to the protrusion (21) in the opposite direction, returning to the relative position of the contact carrier (10) / movable contact (1), which is shown in FIG. 10.20

Claims (11)

REVENDICATIONS1. Mobile contact assembly (1) / contact carrier (10) for circuit breaker-type electrical breaking device, wherein the movable contact (1) is rotatably mounted in the contact carrier (10) between two stable positions, characterized in that a traction spring (4) is fixed on the one hand to the movable contact (1) and on the other hand to the contact carrier (10), in an orientation perpendicular to the axis of rotation of the movable contact (1). ) in the contact carrier (10) so that it can exert two distinct couples in two stability positions limiting an angular deviation of the movable contact (1) in the contact carrier (10), said stability positions resulting from a change of positioning of the spring (4) with respect to either the axis of rotation (R) of the movable contact (1) or to the moving contact (1). 2. Mobile contact assembly (1) / contact carrier (10) according to the preceding claim, characterized in that the movable contact (1) comprises two parts (2, 3) symmetrical each having: - an arm (2a, 3a) fixed to its symmetrical counterpart, a contact pad (11) being placed at the free end of the arms (2a, 3a) contiguous projecting from the contact carrier (10) - and a portion (2b, 3b) located inside the contact carrier (10), pivoting between side flanges of the contact carrier (10), and forming with its symmetrical counterpart a stirrup between the branches of which extends a tension spring (4) fixed on the one hand to the movable contact (1) and on the other hand to the contact carrier (10), in an orientation perpendicular to the axis of rotation (R). 3. A movable contact assembly (1) / contact carrier (10) according to the preceding claim, characterized in that one of the parts (3) comprises a tab (5) cut with and protruding from the second portion (3b ) towards the other piece (2), and on which a first end of the spring (4) is hung. 4. A movable contact assembly (1) / contact carrier (10) according to one of the preceding claims, characterized in that said lug (5) has a notch (6) for hooking the end of the spring (4). . 5. Contact assembly movable (1) / contact carrier (10) according to one of the preceding claims, characterized in that the second end of the spring (4) is attached to a shaft (7) connecting the side flanges of the carrier contact. 6. Mobile contact assembly (1) / contact carrier (10) according to one of the preceding claims, characterized in that the movable contact (1) has on the outer faces second portions (2b, 3b) spaced apart. on the other cylindrical-shaped studs (8) able to pivot in facing recesses (9) in the lateral flanges. 7. Mobile contact assembly (1) / contact carrier (10) according to the preceding claim, characterized in that said housing (9) have a channel opening at the periphery of the flanges. 8. A movable contact assembly (1) / contact-carrier (10) for electrical circuit breaker-type line breaking apparatus, wherein the movable contact (1) is rotatably mounted in the contact carrier (10) between two stable positions according to claim 1, characterized in that it comprises at least one tension spring (4) fixed on the one hand to the movable contact (1) and on the other hand to a shaft (7) connecting the two flanges of the contact carrier (10), in an orientation parallel to the axis of rotation, the ends of said shaft (7) being housed in lateral recesses (24) formed in the flanges allowing a clearance caused by its interaction with a profile (21, 22 23) of the movable contact (1) situated in the vicinity of the shaft (7) when the moving contact (1) rotates, said profile comprising a protuberance (21) forming a hard point between a stable support in the recesses (9) and a bearing zone (22) of the profile housing the shaft (7), corresponding to two angular positions stable fluxes for the moving contact (1). 9. A movable contact assembly (1) / contact carrier (10) according to the preceding claim, characterized in that the recesses (24) are of trapezoidal shape with rounded inner corners and sides of dimension greater than the diameter of the shaft ( 7), and opening at the periphery of the flanges. 10. The movable contact assembly (1) / contact carrier (10) according to one of claims 8 and 9, characterized in that said profile comprises a protrusion (21) followed by a rounded concavity (22) and a indentation (23), the protuberance (21) and the concavity (22) having a radius of curvature of the order of the radius of the shaft (7). 11. The movable contact assembly (1) / contact carrier (10) according to one of the preceding claims, characterized in that the spring (4) is a single or double coil coil spring.