NO180559B - Automatic circuit breaker especially wiring protection switch - Google Patents

Description

The invention relates to an automatic switch according to the preamble of claim 1.

Such switches with specially designed extinguishing chambers are known in a number of designs. For example, reference should be made to the items for DE-PS 1 185 269 and DE-PS 1 185 274. The previously known switches contain within their housing of insulating material an arc chamber assigned to the contact point with extinguishing plates to effectively extinguish the switching arc formed by short-circuit disconnection.

Further developments of these basic chamber forms are e.g. described in DE 27 16 619 B1, DE 33 37 562 A1, EP 0 123 090 B1, EP 0 158 124 A2 and EP 0 251 160 A2. All these extinguishing devices have in common that they have several extinguishing plates arranged at a distance next to each other and two insulating plates standing transversely in front of these in the so-called pre-chamber area and which flank the contact device. The insulating plates, which mostly consist of ceramics or a glass material, are each arranged at a distance from the house's outer walls. This makes it possible to respectively recirculate the plates of arc gases or pressure equalization.

With these extinguishing devices, there is a disadvantage with the two extra insulation plates which, in addition to the parts costs, also require a corresponding assembly cost. In addition, there is a significant risk of breakage when the ceramic plates are not inserted exactly or shift due to wear and tear of the housing components. Functional disturbances of the switch due to broken pieces of the insulation boards flying around in the house can therefore easily be the consequence.

In order to dispense with the insulating plates, it is already known from FR 25 75 861 Bl to provide a circuit breaker with integrated arc guide means in the pre-chamber area. They consist of oppositely formed rows of ribs on the inner walls of the housing of the arc chamber. Between the rows of ribs, which have a tree-like structure or can also be designed as individual straight walls, a central channel is obtained. Depending on the shape of the ribs, these are surrounded by grooves or incisions which, in turn, contain a deionized cold gas reserve and, in the event of a disconnection, must ensure a return of gas in the direction of the contact zone. The freely arranged rows of ribs approximately in the middle of the pre-chamber area only make the creepage path between the contacts wider without this leading to a targeted control of the switching arc and also of the arc gases. In this connection, the shape and position of the grooves are mainly adjusted to maintain a uniform thickness of the ribs in order to exclude lumps as well as unevenness in the housing's components. Design-related as well as form-technical measures are also in the foreground in the execution of the rows of ribs for this switch. However, an optimized return of gas as well as a rapid progress of the switching arc from the contact points in the extinguishing plates is not provided with an extinguishing chamber of this kind.

The purpose of the invention is, with an automatic circuit breaker of the type mentioned above, to simplify the extinguishing chamber within its pre-chamber area and provide an improved arc control as well as to provide a particularly low flow resistance in the pre-chamber space so that a faster and safer progression of the switching arc from the contact point and to the extinguishing plate stack is ensured.

This purpose is achieved by an automatic switch with the features indicated in the characteristics of claim 1. Further developments and advantageous embodiments of the invention are the subject of the independent claims.

The design of the extinguishing chamber according to the invention is advantageous to the extent that the switching arc is driven between the projecting upper sides of closely adjacent steps and is narrowed in the lateral direction by the end surfaces of several columns distributed in the antechamber space respectively. taps and goes in a narrow slot. This results in a high arc acceleration at low gas pressure in addition to better arc control. At the same time, the driving effect of the gas-emitting material in the steps and columns is purposefully utilized to exert an additional driving force on the arc. With closed side plates, however, this effect is usually already strong. Furthermore, the gas pressure formed in front of the traveling arc can be reduced in the free space between the columns, so that the switching arc only encounters a low flow resistance in the direction of the extinguishing plates and can thus proceed quickly and safely from the contact point. During the arc travel, any inhibiting pressure difference in front of and behind the arc is effectively equalized by the return flow of the gas between the columns. This pressure equalization also ensures good deionization of the area at the contact points behind the arc and which is exposed to re-ignition. In addition, the ladder-like sealing walls increase the creep paths at the point of contact. As the step edges are only slightly stressed by the arc, a high insulation strength is obtained with opened contacts. A particular advantage of the invention is also that the high arc speed and the low gas pressure in the antechamber space can, alongside the above-mentioned effects, be achieved by the immediate formation of the columns and also the sealing walls when manufacturing the housing parts from a hard plastic or thermoplastic and thus without cost increase. By omitting the two former, which are usually common insulation boards in the antechamber areas, a significant cost saving is thus achieved in total.

In connection with the drawing, the invention will be explained in more detail in the following in connection with an embodiment example. Fig. 1 shows a simplified circuit breaker with an open upper casing in the area of the extinguishing chamber. Fig. 2 shows a section through the extinguishing chamber along the line II-II which is reproduced in fig. 1. Fig. 3 shows a perspective view of an inventive extinguishing chamber area in a half-house shell. Fig. 4 shows a schematic, expanded outline of the internal contours of two mutually separated house half-shells in the area of the extinguishing chamber.

The circuit breaker, which is made in a narrow construction, has a housing 1 composed of two housing shells 1a, 1b, which in the upper part has a merely indicated connection and release mechanism 2. In the plinth area below, the housing 1 made of hard plastic or thermoplastic molding compound is predominantly made as extinguishing chamber 3, which is for the most part filled with an extinguishing plate stack 4 arranged parallel to the bottom surface lc of the breaker. The depth of the extinguishing chamber between its two internal side surfaces 3a, 3b is in that connection based on the standardized breaker width determined in advance by the house's outer walls la' ,1b' as a structurally normal wall thickness.

The extinguishing plate stack 4 inserted in the extinguishing chamber and with its left-sided narrow end surfaces by a house wall ld provided with blow-out openings is limited by the arc runner rails 6 and respectively on its upper and lower longitudinal sides. 7 which in turn is directed towards the area of a contact device 5 located in the antechamber space 3c of the extinguishing chamber. With, for example, nine extinguishing plates 4a of ferromagnetic material arranged next to each other at a distance, the extinguishing plate stack between the two inner side plates 3a, 3b fills the box-shaped part of the extinguishing chamber on the side of the antechamber space 3c completely and is fixed there immovably in a manner not shown in detail.

The contact point with single interruption arranged at the upper right edge of the extinguishing chamber in the roughly funnel-shaped antechamber space 3c consists of a fixed contact piece 5a which is connected above power line parts 10a and a release coil 10 to an output terminal 11 and a contact arm 5b which can be pivoted about a fixed axis in the housing. This stands above movable wires 12a, 12b with the inclusion of a thermal release 12 in connection with an input terminal 13 and oscillates clockwise during the switch-off sequence. The fixed contact piece 5a and the contact arm 5b constitute, at the actual contact contact point together with their current supplies, an approximately U-shaped current loop which is oriented vertically in the direction of the extinguishing plates 4a. The individual extinguishing plates have on their end sides facing the antechamber space 3c approximately V-shaped incisions 4b which improve the arc inlet and with the thus formed end contour cover the entire open cross-section of the antechamber space which is predominantly surrounded by wall parts towards the other areas of the house. Only one recess necessary for the swinging movement of the contact arm 5b is taken out in the wall parts le, so that the pre-chamber space 3c in connection with the arc conductor cheeks 6,7 is made almost pressure-tight in the direction of the coupling and release mechanism.

Of significant importance are two respective narrow steps 3d, 3e in the antechamber space 3c from the two side surfaces 3a, 3b and towards the center of the house projecting prismatic, which in the usual case have a square cross-section, but can also be designed trapezoid-like or step-like. They are directly formed on the two housing shells la,lb from the bottom of the outer wall la',lb<1> and approximately to the pivot plane of the movable contact arm 5b and end with their upper side preferably at the same height at a distance from the side surfaces. In the extinguishing chamber plane, i.e. in the drawing plane in fig. 1, the approximately equally wide steps 3d, 3e, however, extend in different arcs and that from the area of the contact device to the end contour of the extinguishing plate stack.

In this connection, the upper step 3d lies close to the fixed contact piece 5a and follows its contact horn 5a' from the side facing the antechamber space and to the extinguishing chamber wall in the area of the upper arc runner rail 6. Together, these steps 3d in both housing shells comprise fixed contact pieces on the contact side as well as the two narrow sides in such a way that only a gap is left in the middle between the steps 3d corresponding to the width of the contact arm 5b extending the arc horn 5a'.

Something similar applies to the step 3e along the lower light-arc rail 7. This is likewise at the longitudinal edges and up to the antechamber space 3c on both sides so narrowly contained by the steps 3e that here too only a gap is exposed with approximately the same width as the contact arm and which serves to the base point formation for the switching arc 9. Narrowed by the upper sides of the steps 3d, 3e, the arc within the gap can thus enter the extinguishing plate stack. A slightly projecting rail 7' on the lower arc runner rail in the vicinity of the slot also supports the rectilinear running direction of the arc foot point. The progress of the arc is also positively influenced by the parts of the wide, ferromagnetic arc guide rail 7 covered by the steps 3e in the lateral direction, as the larger material cross-section improves the arc driving effect.

A further main feature of the invention is several columns arranged in the antechamber space 3c or also studs 3f, hereinafter simply referred to as columns, which are arranged approximately evenly distributed in the free cross-section between the steps 3d, 3e. In this connection, the cross-section round or angular columns 3f have to the steps 3d, 3e as well as to each other an approximately equal distance and each reach from the side surfaces 3a, 3b and almost to the swing plane of the contact arm 5b, so that there remains exclusively a narrow, continuous gap between their end faces 3f'. The end surfaces of the two pillar groups thus flank a switching arc 9 led at the contact point in connection with the preferably even-height steps 3d, 3e very narrowly in the lateral direction, while its foot points on the contact horn 5a<1> as well as on the arc runner rails 6,7 are pulled apart and driven accelerated from the contact area in the direction of the extinguishing plate stack 4 (arc position 9',9'')-

The columns 3f are preferably arranged in a slight zigzag shift to an ideal center line between the two steps 3d, 3e from the contact point areas in the direction of the extinguishing plate end sides, but can however also be arranged directly in a row on this ideal line. Two columns are ideally arranged (fig. 1, fig. 3) exclusively in the funnel-shaped, extended area directly in front of the extinguishing plates 4a. On each housing half-shell la, lb, according to the design example, seven columns 3f are formed immediately during the production of the housing parts, so that the columns are preferably formed in a slightly truncated cone shape with an average diameter of approx. 2 mm and a height of approx. 6 mm. Since in the case of circuit breakers, due to the shape of the contact device and its position in relation to the arc runners on the one hand, both for the number of extinguishing plates and their arrangement in the extinguishing chamber, as well as on the other hand for the design of the antechamber space, different technically meaningful solutions are possible, the arrangement of the columns 3f also depending on the aforementioned criteria. The number of columns on each part of the house depends mainly on the size of the antechamber space, while with regard to their position, they must be arranged as evenly as possible between the contact point area and the extinguishing plate end sides. Ideally, the column groups in the two house half-shells are each arranged offset in the opening, which is particularly indicated in fig. 2. Thus, despite the narrow routing of the switching arc 9, the friction acting on it due to the columns 3f is reduced, as during the course of the arc in practice only one of the respective end surfaces in the two column groups is alternately in operation.

Regardless of the number, size and position of the columns, these take up approximately a base area of between 5 and 15% of the remaining area of the antechamber space between the steps 3d, 3e, so that around the columns 3f open flow channels 8 are obtained which are shielded from the rest of the switch by those that act as sealing walls steps and wall parts 3d,3e,le. Due to the low volume of the columns 3f in relation to the overall pre-chamber space, an optimally large gas expansion space is thus obtained, even if the arc is narrowly controlled and its current density is consequently kept as high as possible. The resulting high electrodynamic driving force as well as the practically negligible friction on the end surface of the columns cause a safe and rapid progression of the switching arc from the contact point into the extinguishing plate stack. The existing expansion space and the flow channels around the columns correspondingly ensure a low gas pressure, which in turn reduces the ion concentration and limits the risk of re-ignition behind the arc. In this connection, the space behind the fixed contact piece 5a can serve as a kind of buffer as well as a cooling air mass reserve when the step 3d which includes the contact horn until the upper arc runner rail 6 ends approximately with the upper side of the contact point. There is thus between the end of the step 3d and the wall part le a transverse flow channel 8' which enables a pressure equalization over the contact point of the actual antechamber space 3c.

The arrangement of the columns described above and shown in the figures as well as the overall design of the antechamber for a circuit breaker can, taking into account the criteria mentioned, also be used for other automatic circuit breakers. In this connection, the person skilled in the art can adapt the columns and steps to the spatial dimensions of the extinguishing chamber and the antechamber space in the individual case, without ending up outside the scope of the inventive concept.

Claims (10)

1. Automatic circuit breaker with a housing (1) made of insulating material and receiving a switching mechanism (2) and with an extinguishing chamber (3) surrounded by the housing and having a pre-chamber space (3c) flanking a contact arrangement (5) and having auxiliary means (3f) for arc guidance integrated in the housing and projecting from this for guidance of a switching arc (9, 9', 9'') from the contact point to an arc extinguishing area, in particular an extinguishing plate stack (4) which in turn terminates the pre-chamber space (3c) which extends in a funnel form from the contact arrangement (5) to the extinguishing plates (4) and is provided with arc runner rails (5a<1>, 6, 7) on the side remote from the contact point, characterized in that steps (3d, 3e) of insulating material that begin at the contact arrangement (5), from there lie along the arc runner rails (5a<1>, 6, 7) and which enclose these towards the antechamber space (3c), apart from a slot in the contact opening plane, and at the same time forming sealing walls against the coupling mechanism (2), is arranged in the antechamber space (3c) on at least one side surface of the side surfaces (3a, 3b) facing inwards in the housing (1) and which are arranged approximately parallel to the plane of the contact opening movement of the contact arm (5b), that a series of columns or pins (3f) projecting from the bottom of the side surfaces (3a, 3b) in the direction of the contact opening plane, are arranged in the remaining flow channel (8) in the pre-chamber space ( 3c) between the sealing walls (3d, 3e; le) so that they are approximately evenly distributed<p>/å<en> such that they at their end surfaces (3f) and in cooperation with the steps (3d, 3e) cause a tight lateral guiding the switching arc (9) with a small contact surface, and that, despite the tight guide, a large gas expansion chamber is maintained between the columns or pins (3f). 2. Switch according to claim 1, characterized in that the columns (3f) are arranged within the flow channel (8) distributed between the sealing walls (3d, 3e; le) as well as mutually distributed in such a way that if their footings are imaginary circles of approximately the same diameter both collide with each other and also touch each of the sealing walls on the circumferential side. 3. Switch according to one of the claims 1-2, characterized in that the columns (3f) are arranged at approximately equal distances in a row and exactly one after the other. 4. Switch according to one of claims 1-3, characterized in that the columns (3f) with their foot points are arranged on an ideal arc line approximately in the middle between the curved steps (3d, 3e). 5. Breaker according to one of claims 1-3, characterized in that the columns (3f) with their foot points are approximately evenly distributed in a zigzag line on the side surfaces (3a, 3b) between the steps (3d, 3e) in the flow channel (8). 6. Switch according to one of claims 1-5, characterized in that the columns (3f) on one side surface (3a) are each arranged offset in relation to the openings between those on the other side surface (3b) in the housing (1). 7. Switch according to one of the claims 1-6, characterized in that the columns (3f) on a side surface (3a or 3b) are each made with the same height as the associated steps (3d, 3e) and have end surfaces (3f) which is located in a plane. 8. Switch according to one of the claims 1-7, characterized in that the steps (3d, 3e) and also the columns (3f) are directly formed during the production of the housing parts (la, lb). 9. Switch according to one of the claims 1-8, characterized in that the columns (3f) are made round or angular and have a diameter and side length of approx. 2 mm. 10. Switch according to one of claims 1-9, characterized in that the steps (3d, 3e) are designed for positioning and fixing on the fixed contact piece (5a) together with the contact horn (5a') on one side and a lower arc runner rail (7) on the other hand.