CZ301014B6 - Low-voltage multipolar switch exhibiting great electrodynamic force, whose pole shaft is incorporated in a bay accommodating poles - Google Patents

Abstract

In the present invention, there is disclosed a low-voltage multipolar switch (10) exhibiting great electrodynamic force being formed of a casing from insulating material, divided into frontal section (12), in which, there is located a control mechanism (24), which controls switching on and off of the switch and a rear section (14), isolated from the frontal section (12) with a central wall (20). The rear section (14) is divided into independent sections (36) by separating partitions (38), where in each independent section (36), there is placed one pole (56) of the switch. The control mechanism (24) is connected with a pole shaft (78), common for all poles (56). The pole shaft is located in the rear section (14) and is carried in bearings passing through the separating partitions (38).

Description

Low voltage multi-pole switch with high electrodynamic force, the pole shaft of which is located in the compartment where the poles are located

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a low current multipole circuit breaker with high current and high electrodynamic force.

BACKGROUND OF THE INVENTION

In the past, high-current circuit breakers (indicatively between 630 A and 6300 A), acting as the basic switchgear for feeder and feeder in high-power installations, consisted of composite elements mounted on a metal frame, hence called "open" circuit breakers . However, devices of this magnitude have inherited part of the technology of the lower power circuit breakers, called "pressed housing" circuit breakers, as they are characterized by an insulating protective cover, usually molded of reinforced polyester, containing the arc chute poles, control mechanism and tripping device. The protective cover makes it possible to reduce the overall dimensions of the device by helping to reduce tripping and its external effects, integrating pole distribution, and improving insulation between the power circuit and the auxiliary devices.

EP-A-0 322 321 discloses a circuit breaker of this type, the housing of the circuit breaker being formed by a central housing assembly, a lid forming a front panel of the circuit breaker and a rear panel.

The front face of the middle housing divides the housing into a front compartment bounded by the front and lid and a rear compartment for receiving the poles and electrically insulated from the front compartment. In the front compartment there is a control mechanism acting on a transverse switching shaft common to all poles, called a pole shaft. This shaft is mounted in bearings mounted on the front face of the center bush. The rear compartment is further divided by insulating partition walls into separate pole locations. In addition, the front wall of the central housing includes an opening for each pole to access a corresponding separate compartment. Each pole consists of a pair of detachable contacts with fixed contact and movable contact and an arc arc chute. Each movable contact is mechanically coupled to the transverse shaft by means of a connecting rod passing through the front wall of the central housing through a corresponding access opening.

Each rod connecting one of the movable contacts to the transverse shaft is arranged such that, in the closed position of the contacts and in a plane cross-section perpendicular to the axis of rotation of the pole shaft, the distance between the straight line through the axis of rotation of the coupling rod and the axis of rotation is small.

In other words, the lever transmission of the resulting force applied by the contacts to the pole shaft is small, which ensures that the connecting rod generates only a small torque at the shaft level when transmitting large electrodynamic forces. In static equilibrium in the closed position of the contacts, the actuating mechanism exerts a torque on the shaft which counteracts the electrodynamic forces transmitted by the connecting rods. This torque generates only small forces at the operating mechanism level. The resultant of the reaction forces at the level of the shaft guide bearings is large and counteracts the forces transmitted by the tie rod and the control mechanism. This architecture is characteristic of circuit breakers with high electrodynamic force. These circuit breakers must by definition be able to withstand the generated fault currents, which generate large electrodynamic forces that tend to separate contacts to achieve time selectivity in the electrical installation. The corresponding arrangement of the pole shaft, the connecting rods with movable contacts and the connecting rods to the actuating mechanism must be such that these forces do not cause separation of the contacts or switching off the actuating mechanism. In this case, the selected arrangement allows these forces to be transmitted to the housing by means of shaft bearings so that the actuating mechanism is not subjected to excessive forces or torques.

However, guiding the pole shaft and transmitting forces to the switch housing are not entirely satisfactory.

The transverse shaft must in fact be sized, arranged and supported so that its deformation is limited and does not block operation. In addition, the bearings of the pole shaft must be well secured in the housing because the high forces transmitted to them tend to pull them out of the front face of the middle housing to which they are attached. The formation of the rigid assembly involves the use of expensive and bulky fastening parts and bearings and the entire housing arrangement. The circuit-breaker assembly requires a large number of parts, resulting in high cost and demanding assembly. In addition, this architecture limits the miniaturization of the switch.

In addition, numerous holes for the passage of the connecting rods between the pole shaft and each pole are detrimental to the tightness of the arc chute. The electric arc and the endothermal vapor produced by this arc at the level of some of the elements of the quench chambers increase the positive pressure and gas flow that must be directed to the outlet openings provided with suitable filters. In order not to impede the entry of the arc into the arc chute, it is wise to place these outlet openings on the bottom of the arc chute. Thus, the presence of connecting rod openings located just above the contacts in the inlet of the chambers hinders the flow of gases to the outlet openings. This allows uncontrolled flow of gases through the front compartment and the front face openings directly out, without any protective filter.

SUMMARY OF THE INVENTION

It is therefore an object of the invention to overcome the disadvantages of the prior art and in particular to increase the stiffness of the circuit-breaker mechanism with high electrodynamic forces at low cost.

In accordance with the invention, this problem is solved by a low-voltage, high electrodynamic force switch with a housing made of insulating material consisting of a control mechanism coupled to a pole shaft housed in bearings securely attached to the housing of a plurality of poles wherein each pole comprises at least one detachable pair contact portions, wherein at least one of the contact portions of each pair, called the movable contact portion, is mechanically coupled to the pole shaft and the pole shafts, wherein the actuation mechanism and the movable contact portion are able to move between an open position corresponding to separation of the contact portions of each pair and a closed position corresponding to the contact between the contact portions of each pair, wherein the switch housing is formed by a front compartment in which the control mechanism is located and a rear compartment separated from the front o a partition by means of a central wall and further subdivided into separate compartments by means of separating walls, wherein in each separate compartment one of the circuit breaker poles is located, the axis of rotation of the circuit breaker pole shaft being located in the rear compartment.

In the state of the art, devices whose pole shaft is located in the front compartment must ensure a minimum distance between the pole shaft and the movable contact parts in the open state. The connection between the movable contact portions and the shaft is essentially formed across the central wall between the front compartment and the rear compartment. The arrangement according to the invention makes it possible to significantly reduce and even eliminate this distance, since there is no longer any part between the shaft and the contact parts. The overall dimensions of the device can thus be reduced.

This arrangement also allows the electrodynamic forces acting on the contacts to be absorbed by the housing without causing large distortions of the central portion. This actually allows the bearing bearings to be placed in the rear compartment. If at least partial attachment of these bearings to the central wall is proposed, it is then easy to ensure that, in response to the electrodynamic forces exerted on the movable contact parts, the fastening parts operate under pressure instead of in the market.

-2GB 301014 B6

This arrangement further allows the elimination of holes for the passage of the connecting rods between the pole shaft and each movable contact portion. This reduces contamination of the front compartment and improves the flow of cut-off gases to the outlet openings of the arc chute base.

The assembly is simplified since it is no longer necessary to mount the connection between the pole shaft and each connecting rod through the holes of the central crossbar.

Preferably, each of the separating bars carries one of the above-mentioned bearings and the pole shaft extends through each bar at the level of one of the bearings. This arrangement makes it possible to multiply the bearings and distribute them regularly along the pole shaft without increasing the overall dimensions of the assembly.

Alternatively, it is also possible to form the bearings so that they are between the separation walls of the chambers on autonomous supports. Preferably, each separating bar comprises a separating element molded together with a central wall, at the edge of which a semi-cylindrical sector forming part of the corresponding bearing is formed. This provides a multifunctional part that makes assembly easier and reduces costs.

In a preferred embodiment, the central wall comprises a window for the passage of the mechanical coupling portion between the pole shaft and the actuating mechanism.

The outer surface of the pole shaft is preferably of an electrically insulating material, in particular of a thermosetting polyester plastic. This arrangement makes it possible to achieve electrical insulation both between the poles and with the actuating mechanism. The thermosetting material provides the advantage of good dielectric strength after switching off. In practice, the shaft may be made of a compact thermosetting material. Alternatively, the shaft may have a metal body covered with an insulating material.

The switch preferably comprises at least one connecting rod between the pole shaft and each movable contact portion connected to the pole shaft by a pivot so that in a certain relative position of the shaft and the rod, called the mounting position, the rod can slide freely in a direction parallel to the pivot axis. Once the bar has been mounted and moved away from this storage position, a connection is prevented to prevent the bar from sliding in a direction parallel to the pivot axis, the mounting position being such that the pole shaft and the bar will never assume this position in working condition.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail by means of specific exemplary embodiments illustrated in the drawings, in which:

Fig. 1 is a perspective cross-sectional view of the circuit breaker according to the invention; Fig. 2 is an exploded view of the pole shaft and part of the switch housing according to the invention; Fig. 3 cross section of the switch of Fig. 1 in closed position; Fig. 5 is a perspective view of the pole shaft and the connecting rod to one of the poles in the position preceding their assembly; Fig. 6 is a perspective view of the pole shaft and connecting rod to connect one of the poles to each other. Fig. 7 is a perspective view of the pole shaft to which the connecting rod is mounted relative to each other when the circuit breaker is open; Fig. 8 is a perspective view of the pole shaft to which the connecting rod is attached to each other when the circuit breaker is closed; .

-3GB 301014 B6

DETAILED DESCRIPTION OF THE INVENTION

According to FIGS. 1 to 3, the low-voltage, non-limiting circuit breaker 10 with high electrodynamic force is arranged in a molded housing formed by a front compartment 12 and a rear compartment 14. The front compartment 12 is defined by a front panel 16, side panels 18 cast with a front face and a central wall 20 separating it from the rear compartment 14. It comprises on the front panel 16 openings for the passage of the rotating handle 22 for resetting the switch operating mechanism 24, an opening and closing button and a closing button. The control mechanism 24 is located in the front compartment 12.

The rear section 14 is defined by a central wall 20, a rear panel 26 forming a rear panel, and side panels 28, part of which is cast with the rear panel 26 and a portion molded with the middle wall 20. The rear panel 26 carries connection strips 30 to connect the switch 10 to the external electric circuit. The back plate 26 and the middle wall 20 are connected to each other by means of fixing screws 32 sized to be able to withstand high shear stresses. A window 34, particularly visible in FIG. 2, is formed in the central wall 20 to allow connection between the front compartment 12 and the rear compartment 14. The rear compartment 14 is further subdivided into separate compartments 36 by means of separating walls 38. Each separating partition 38 comprises two lateral portions arranged on each side of the central portion. Each side portion is formed by a dividing element 40 molded with the back plate and a dividing element 42 molded with the central plate 20, wherein the dividing elements 40, 42 are connected to the assembled unit. The central portion comprises a dividing member 44 molded with a rear plate having a greater height than the adjacent side dividing members 40. This dividing member 44 comprises ribs 46 cooperating in assembly with additional grooves 48 of the side dividing members 42 that are securely connected to the central wall 20 The central partition member 44 of the backplate has a smooth semi-cylindrical surface 50. The middle wall 20 comprises an additional middle partition member 52 of lower height, which also has a smooth semi-cylindrical surface 54 positioned opposite this surface of the member securely connected to the rear panel.

The switch pole 56 is located in a separate compartment 36. Each pole 56 is comprised of an arc chute 58 and a detachable contact device. The detachable contact device comprises a fixed contact portion 60 electrically coupled to a switch connecting strip 30 passing through the backplate 26 of the insulating housing and a movable contact portion 6L The movable contact portion 61 is provided with a plurality of contact fingers 62 connected in parallel to the first transverse axis 64 supported by the support tunnel 66 The foot of each thumb 62 is connected by a flexible conductor 68 formed by a metal braided band to the second switch strip 30 of the switch. Each thumb 62 comprises a contact insert 70 cooperating with the insert 72 of the fixed contact portion 60 in the closed position of FIG. 3. The tunnel 66 is U-shaped (FIG. 5). Its end located near the second connection strip is provided with an axle 74 mounted in a bearing securely attached to the insulating sleeve so as to allow the tunnel 66 to rotate between the closed position of pole 56 shown in FIG. 3 and the open position shown in FIG. A contact pressure spring 76 is disposed in the notch of tunnel 66 and forces the contact fingers 62 to rotate counter clockwise about the first axis 64,

The arc chute 58 comprises a stack of arc deionization plates produced by the pole separation as well as openings for extinguishing gases. Further details of the pole structure 56 can be found in FR-AA-2,650,434, the disclosure of which is incorporated herein by reference.

The pole shaft 78 is positioned between the semi-cylindrical sectors 50, 54, which upon assembly form tight bearings supporting the pole shaft 78 as it rotates about its axis 79. The pole shaft 78 is molded from a thermosetting polyester. Each of the tunnels 66 is connected to the pole shaft 78 by a pair of parallel transfer bars 80 rotating around a geometric axis that is identical to axis 64. Each rod 80 is connected to the pole shaft 78 by a pivot pin 8L.

-4GB 301014 B6

The control mechanism 24 is comprised of an on / off device with an energy storage device and an off device. This mechanism is known per se and reference can be made to the document for further details

FR-A-2 589 626. It will only be recalled that the opening device comprises an articulated device comprising two rods 82, 84 articulated to each other by means of a pivot axis 86, wherein the lower transmission rod 82 is mechanically connected to the pole shaft 78 by a pivot axis 88 cooperating with a bearing formed in the crank 90 securely connected to the pole shaft 78. The release spring 92 is fixed between the axis 88 and the fixed safety guide pin. Giant. 3 shows that the window 34 formed in the central wall 20 serves in the closed position to allow the passage of the lower transmission rod 82 and the release spring 92. In the on position, the lever action of the bars 80 on the pole shaft 78 is noticeably lower than that of the transmission bar. 82. In other words, the distance between the axis 79 of the pole shaft 78 and the plane in which the axes 64, 81 of the pivot pins of the rods 80 is less than the distance between the axis 79 of the pole shaft 78 and the plane in which the axes 86, 88 In practice, the ratio of the two distances is less than 0.3.

In the on position shown in Fig. 3, it can be seen that for each pole 56, the contact inserts 70 of the contact fingers 62 are pressed against the contact insert 72 of the fixed contact portion 60. The contact pressure is generated by a spring device 76 which allows to compensate any mechanism play and wear The electrodynamic forces applied to the contact fingers 62 are converted to the level of the tunnel 66 by the surfaces of the spring bearings 76 and the axis 64 and generate a moment about the axis of rotation 74 of the tunnel 66, resulting in the tunnel 66 tending to rotate contacts. This torque is compensated by the opposite torque exerted by the rods 80 on the tunnel 66 at the level of their relative axis of rotation 64. Thus, in dynamic equilibrium, the rods 80 are subjected at the level of their connecting pivot 64 connecting them to the tunnel 66 with a force directed towards their connecting pivot 81 connecting them to the pole shaft 78. This force, transmitted to the pivot 81, generates a moment about the axis 79. The same phenomenon occurs at each pole. The torque generated by the lower transmission rod 82 of the release articulation device is opposite to the sum of the moments of forces exerted by all the bars 80 and the release spring 92 on the pole shaft 28. Due to the relative position of the bars 80, the transmission rod 82 and the pole shaft 78. compared to the lever action of the transfer bar 82, the resultant forces at the level of the transfer bar 82 remain small. Thus, the characteristics of the high electrodynamic force switch can be found here, since the electrodynamic forces on the contact portions create only limited pressures on the actuating mechanism, so that the actuating mechanism can counter them. In equilibrium, the pole shaft 78 exerts compressive forces at the level of the bearing bearings, the resultant of which is a reaction force counteracting the sum of the forces exerted by the rods 80 and the transmission rod 82.

Upon opening of the circuit breaker, the rod 82 terminates the counterclockwise rotation of the pole shaft 78. This rotation, generated jointly by the release spring 92 and the resultant of the electro40 dynamic forces at the level of the connecting pivot 81 of the rods 80 and the pole shaft 78, will bring all tunnels 66 to the off position shown in Fig. 4. emerges from window 34.

Giant. Figures 5 to 8 describe the mounting of a pivot connection between the pole shaft 78 and the connecting rods 80 with the tunnel 66. The pole shaft 78 comprises for each pole an arm 94 carrying two coaxial pivot pins 81 eccentric with respect to the axis of rotation 79 of the pole shaft 78. pivot pins 81 are disposed in the notch 98 of the side face 100 of the arm. The tab 102 extending over the notch 98 forms a groove 104.

On the side intended to cooperate with the pole shaft 78, each rod 80 comprises a cylindrical bore 108, intended to form a bearing one of the pivot pins 81, and a straight portion 110. During assembly, the rod 80 is laid so that the flat portion 110 is parallel to the lower edge of the tab 6. It is then possible to insert the pivot pins 81 into the cylindrical bores 108. After assembly, the assembly formed by the rods 80 and the pole shaft 78 is placed in a housing where

-50101014 B6 oscillates between two extreme positions: the contact opening position shown in Fig. 7 and the contact opening position shown in Fig. 8. In both these positions and in all intermediate positions, the rod 80 they fit into corresponding grooves 104 of the pole shaft 78, which form a guide preventing any movement of the rods 80 in a direction parallel to the axis of rotation 80. Thus, a simple direct connection is achieved which does not require the use of any additional intermediate parts.

Of course, the invention is not limited to the example described above. For example, it is clear that the axis of rotation of the bars 80 on the tunnels 66 does not necessarily have to be the same as the axis of rotation of the thumbs 62. Only one pole 80 per pole can be used. Furthermore, the arrangement can be designed to increase the tightness at the level of the bearings passing through the crossbars. Thus, angular section bearings with a central circular groove can be used, working in conjunction with the additional roughness of the shaft surface. Additional bearings may also be provided at the level of the outer side walls of the housing. The switch described in the examples includes an energy storage mechanism. However, any type of pole shaft actuation mechanism may be used within the scope of the invention. The mechanism described may be replaced by any known mechanism, be it a manual or motor controlled re-adjustment mechanism.

Claims (6)

PATENT CLAIMS 25 1. A high electrodynamic force low voltage switch (10) with a housing made of insulating material, comprising a control mechanism (24) connected to a pole shaft (78) housed in bearings securely attached to a housing, a plurality of poles (56), each the pole (56) is formed by at least one pair of detachable contact portions (60, 61), wherein at least one of the contact portions of each pair, called the movable contact portion (61), is mechanically 30 coupled to a pole shaft (78) and a pole shaft (78), wherein the control mechanism (24) and the movable contact portion (61) are able to move between an open position corresponding to the separation of contact portions (60, 61) of each pair and a closed position corresponding to a contact between the contact portions (60, 61) of each pair, wherein the switch housing is formed by a front compartment (12) in which the control mechanism (24) is located and a rear compartment (14) separated from the front 35 of a compartment (12) by means of a central wall (20) and further subdivided into separate compartments (36) by means of partition walls (38), wherein each separate compartment (36) is provided with one of the poles (56) of the switch (10). in that the axis of rotation (79) of the pole shaft (78) is located in the rear compartment (14). 40 The low-voltage circuit breaker according to claim 1, characterized in that each of the separating bars (38) carries one of the bearings and that the pole shaft (78) extends through each of these separating bars (38) at the level of these bearings. Low-voltage switch according to claim 2, characterized in that each of the separating partition walls (38) comprises a separating element (52) molded together with a central wall (20), wherein a semi-cylindrical sector (20) is formed at the edge of said central wall (20). 54) forming part of the corresponding bearing. Low-voltage switch according to any preceding claim, characterized by 50, wherein the central wall (20) comprises a window (34) for the passage of the mechanical coupling portion (82) between the pole shaft (78) and the actuating mechanism (24). -6GB 301014 B6 Low-voltage circuit breaker according to any preceding claim, characterized in that the outer surface of the pole shaft (78) is of an electrically insulating material, in particular of a thermosetting polyester plastic. 5 The low-voltage circuit breaker according to any one of the preceding claims, characterized in that it comprises at least one connecting rod (80) between the pole shaft (78) and each movable contact portion (61), the connecting rod (80) being connected to the pole shaft. (78) with a pivot (81) such that in a certain relative position of the pole shaft (78) and the rod (80), called the mounting position, the connecting rod (80) can be freely moved in a direction parallel to the pivot axis (91); once the coupling rod (80) is supported and moved from this mounting position, a coupling is prevented to prevent the coupling rod (80) from sliding in a direction parallel to the pivot axis (81), the mounting position being such that in the operating state the shaft (78) and the connecting rod (80) do not assume this mounting position.