SE500191C2 - automatic switch - Google Patents

Abstract

The switch has an insulating housing with an arc extinction chamber receiving a stack of arc extinction plates (4) and a funnel-shaped pre-chamber (3c) receiving the contacts. The inside face (3a) of the pre-chamber (3c) hasa a pair of ribs (3d,3e) in the opening plane of the pivoted contact lever (5b), wioth the spaced between them filled with a series of evenly spaced cylindrical cones (3f) to define a narrow path for the switching arc (9). The gas press preceding the arc (9) is released via the flow channels (8) between the columns.

Description

The flange rows, which have a tree-like structure or can also be designed as individual straight walls, remain a central channel. Depending on the design of the flanges, these are surrounded by grooves or grooves which in turn contain a deionized cold gas reserve and in the event of a break must ensure gas return in the direction of the contact zone. The flange rows arranged independently in the middle of the atrium area only widen the creep path between the contacts without any directional control of the arc and also the arc gases being achieved. In this case, the shape and position of the grooves are mainly adapted to maintain an even flange thickness in order to exclude cavities and irregularities in the housing parts. Design and press technical measures are thus at the forefront in the design of this switch's flange rows. On the other hand, no optimized gas return and a rapid movement of the switch arc from the contact point to the extinguishing plates are ensured in such an extinguishing chamber.

The object of the invention is to simplify the extinguishing chamber in its antechamber area in the case of an circuit breaker of the type initially indicated in order to achieve improved arc guidance and a particularly low flow resistance in the antechamber chamber so that a fast and reliable movement of the arc from the refractory arc the contact point of the fire extinguisher stack is secured.

This task is solved with a circuit breaker which exhibits the features specified in the characterizing part of claim 1. Further developments and advantageous embodiments of the invention are subject to the subclaims.

The design of the extinguishing chamber according to the invention is advantageous in that the breaking arc of the magnetic field of the arc busbars is driven between the projecting upper sides of adjacent bridges and laterally narrowly bounded by the end sides of several pillars respectively in a narrow gap. As a result, in addition to better arc control, a high arc acceleration with low 10 15 20 25 30 35 * * SUG 19Éí 3 gas pressure arises. At the same time, the driving effect of the gas-emitting material in the bridges and columns is used to exert an extra driving force on the arc. With closed side plates, however, this effect is often already too strong.

Furthermore, the gas pressure arising in front of the traveling arc can be equalized in the free spaces between the columns so that the refractive arc now only meets a low flow resistance in the direction of the extinguishing plates and thus can quickly and safely leave the contact point. During the arc migration, a possible inhibiting pressure difference in front of and behind the arc is effectively equalized by backflowing the gases between the columns. This pressure equalization also ensures a good deionization of the newly ignited area at the contact point behind the arc. Furthermore, the bridge-like sealing walls increase the creep paths at the contact point. As the bridge edges are only slightly loaded by the arc, high insulation resistance is obtained even when the contacts are opened. A special advantage of the invention further consists in that the high arc velocity and the low gas pressure in the atrial chamber in addition to the previously described effects can be achieved by direct design of the columns and also the sealing walls in the housing parts' manufacture of any duroplast or thermoplastic and thus cost neutral . Due to the loss of the two hitherto most common insulating material plates in the atrial area, a considerable cost saving thus arises overall.

The invention will now be explained in more detail below in connection with an exemplary embodiment shown in the accompanying drawings. Fig. 1 shows in simplified form a circuit breaker for pipes with an upper housing bowl opened in the extinguishing chamber area, Fig. 2 a section through the extinguishing chamber along the line II-II in Fig. 1, Fig. 3 is a perspective view of the extinguishing chamber area of a house half bowl and Fig. 4 in schematic exploded view of the inner contours of the two separate house half bowls in the firebox area. lO 15 20 25 30 35 CH CJ \ C .... .i 4 The narrowly constructed circuit breaker for wires has one of two housing shells 1a, the upper part occupies a housing 1 only indicated by a circuit breaker and tripping, which in the canism 2 In the underlying base area, the housing 1 made of duroplastic or thermoplastic molding material has predominantly been designed as an extinguishing chamber 3, which is for the most part filled with a extinguishing plate stack 4 arranged parallel to the bottom surface 1c of the switch. The extinguishing chamber depths between its two inner side surfaces 3 , 3b is then based on the standardized switch width predetermined by house outer walls 1a ', 1b' with a wall thickness customary in terms of manufacturing technology.

The extinguishing stack 4 in the fire chamber, with its narrow end surfaces on the left side against a house wall ld provided with exhaust openings, is on its upper and lower longitudinal side limited by arc guide rails 6 and 7, respectively, which in turn are directed into the area of a the extruder chamber 3c of the extruder chamber existing contact device 5. With, for example, nine spaced-apart extinguishing plates 4a of ferromagnetic material, the extinguishing plate stack between the two inner side surfaces 3a, 3b fills the plate-shaped part of the extinguishing chamber on the side of the atrium and the holding chamber 3c completely. is steadfastly maintained in an unspecified manner.

The contact point arranged on the right upper edge of the extinguishing chamber in the approximately funnel-shaped antechamber chamber 3c with single break consists of a fixed contact piece Sa, which is connected via current line parts 10a and a release coil 10 to an output terminal 11 and a shaft pivotable about a fixed arm. . The latter is connected via flexible lines 12a, 12b by connection of a thermal trigger 12 to an input terminal 13 and is pivoted counterclockwise when breaking. The fixed contact piece 5a and the contact arm 5b form at the actual contact contact point together with their current leads a approximately U-shaped current loop, which is oriented at right angles to the direction of the extinguishing plates 4a. 10 15 20 25 30 35 “jöß fi 193 S The individual extinguishing plates have on their end face facing the antechamber chamber 3c an approximately V-shaped notch 4b which improves the arc inlet and with the end contour thus formed covers the entire open cross-section of it predominantly towards the other housing areas. wall sections smile enclosed atrium. Only a recess required for the pivoting movement of the contact arm 5b has been recessed in the wall parts 1e so that the atrium chamber 3c together with the arc guide rails 6, 7 is almost pressure-tightly formed against the breaking and release mechanism.

Of essential importance are each two in the atrium chamber 3c on both side surfaces 3a, 3b towards the center of the house prismatically projecting, narrow bridges 3d, 3e, which normally have a rectangular cross-section, but can also be trapezoidal or They are directly formed at the lb 'bottles step-shaped. both housing shells 1a, 1b from the outer walls 1a ', approximately to the pivot plane of the movable contact arm 5b and terminate with their upper side preferably at an equal distance from the side surfaces. In the extinguishing chamber plane, ie in the drawing plane in Fig. 1, the approximately equally wide bridges 3d, 3e, however, run with different arcuate shapes, more precisely from the area of the contact device towards the end contour of the extinguishing plate stack.

The upper bridge 3d then lies close to the fixed contact piece Sa and follows its contact horn 5a 'on the side facing the antechamber chamber all the way to the extinguishing chamber wall closest to the upper arc guide rail 6. Together the bridges 3d on both housing cups grip the fixed contact piece on the contact side and on both narrow sides in such a way that in the middle between the bridges 3d practically along the arc horn 5a 'a gap is left which corresponds to the width of the contact arm Sb.

The same applies to the bridge 3e along the lower arc rail 7. This is also at its longitudinal edges tightly framed against the atrium chamber 3c on either side by bridges 3e so that here too an approximately contact arm-wide gap is left which is intended for focal point formation of UW 10 15 20 25 30 35 CT) C) ..__ \. \ Û 6 switch arc 9. Narrowed by the 3d, 3rd upper sides of the bridges, the arc in the gap can thus run into the extinguishing plate stack. An insignificantly projecting sickle 7 'on the lower arcuate guide rail near the gap further supports the straight running direction of the arc base. The drive of the arc is also positively affected by the parts of the wider, ferromagnetic arc guide rail 7 covered by the bridges 3e on the sides, since the larger material cross-section improves the arc-driving effect.

A further main feature of the invention are several pillars or pins 3f arranged in the atrium chamber 3c - hereinafter referred to only as pillars - which are arranged approximately evenly distributed in the free cross-section between the bridges 3d and 3e. The pillars 3f have a round or even angular cross-section and thereby approximately equal distance from the bridges 3d, 3e and extend from the side surfaces 3a, 3b almost all the way to the pivot plane of the contact arm 5b so that only a narrow gap remains free between their end surfaces 3f '. The end surfaces of both column groups thereby flank a breaking arc 9 drawn at the point of contact together with the preferably equally high bridges 3d, 3e narrowly laterally while its foot points on the contact horn 5a 'and the arc rails 6 and 7 are pulled apart and out of the contact area and accelerated. in the direction of the extinguishing plate stack 4 (arc positions 9 ', 9 ").

The pillars 3f are preferably arranged with some zigzag displacement relative to a central ideal line between the two bridges 3d, 3e from the area at the point of contact in the direction of the extinguishing plate end sides, however can also be arranged directly in a row on this ideal line. Only in the funnel-shaped expanding area directly in front of the extinguishing plates 4a are ideally two pillars arranged (Fig. 1, Fig. 3). On each housing half shell 1a, 1b, according to the exemplary embodiment, seven pillars 3f are designed directly during the manufacture of the housing parts, the pillars preferably being slightly frustoconally shaped with an average diameter of approximately 2 mm and a height of 10 15 20 25 30 35 7. about 6 mm. Since with circuit breakers due to the shape of the contact device and its position relative to the arc guide rails on the one hand and the number of extinguishing plates and their placement in the extinguishing chamber on the other hand different technically meaningful solutions are possible regarding the design of the antechamber, the pillars 3f location also depends on mentioned criteria. The number of pillars on each part of the housing will then to a significant extent depend on the size of the atrium chamber, while those with respect to their position should be as evenly distributed as possible arranged between the contact point area and the fire plate end sides. Ideally, the column groups in the two housing half-bowls are arranged offset from each other, as specifically indicated in Fig. 2. In this way, despite tight control of the switch-off arc 9, the same influencing effect through the columns 3f is reduced, since practically when the arc travels always only one end surface of the two pillar groups is alternately active.

Irrespective of the number, size and position of the columns, these occupy approximately a bottom area of between 5 and 15% of the remaining surface of the atrium chamber between the bridges 3d and 3e, so that around the columns 3f flow channels 8 are left which are separated from them as sealing walls. active bridges and wall parts 3d, 3e, smile towards the switch otherwise. Due to the small volume of the columns 3f in relation to the entire atrium chamber, an optimal gas expansion space is thus obtained despite the fact that the arc is controlled narrowly and thus its current density is kept as large as possible.

The resulting high electrodynamic drive as well as the practically negligible friction against the end surfaces of the columns results in a safe and fast deflection of the cut-off arc from the contact point to the extinguishing plate stack. The existing expansion space for the flow channels around the columns also creates low gas pressure, which in turn lowers the ion concentration and thus limits the risk of re-ignition behind the arc. As a kind of buffer and as a cooling air mass reserve, the space behind the fixed connector 5a about the bridge 3d which grips the contact horn up to the upper arc guide rail 6 can be used approximately at the height of the cone 500- 391 10 15 20 25 30 35 8. top of the beat. As a result, a cross-flow channel 8 'remains between the end of the bridge 3d and the wall part le, which enables pressure equalization above the contact point towards the actual atrium chamber 3c.

The placement of the pillars described above and shown in the drawing figures, as well as the entire design of the atrium chamber for a circuit breaker for pipes, can also be used for other circuit breakers, taking into account the mentioned criteria. In this case, the person skilled in the art will need to adapt the columns and bridges to the spatial dimensions of the extinguishing chamber and the antechamber room in the individual case without leaving the frame of the inventive idea.

Claims (16)

1. 'jBQÛ 39? CLAIMS 1. Circuit breaker with a housing made of insulating material which receives the switching mechanism, and with a fire-extinguishing chamber enclosed by the housing, which has an atrium chamber flanking the contact device, with arc travel aid for moving the arc from the contact point to a light point , which in turn terminates from the contact device towards the extinguishing plates funnel-shaped divergent, with atrium rails provided with atrium rails at the side facing away from the point of contact, characterized in that in the atrium chamber (3c) on at least one side surface of the approximately parallel to the plane of the contact opening movement (contact arm 5b) the existing side surfaces (3a, 3b) of the housing (1), starting approximately at the contact device (5) and from there adjacent bridges (3d, 5a ', 6, 7) abutting 3e) of insulating material are provided, which grip the arc rails (5a ', 6' 7) with the exception of a gap in the edge the opening plane towards the atrium chamber (3c) and at the same time forms sealing walls against the breaking mechanism (2), and that in the atrium chamber (8c) remaining flow channel (8) between the sealing walls (bridges 3d, 3e; wall part le) several pillars and pins (3f) projecting from the bottom of the side surfaces (3a, 3b) in the direction of the contact opening plane are arranged approximately evenly distributed in such a way that they with their end surfaces (3f ') and in cooperation with the bridges ( 3d, 3e) entails a tight lateral control of the switch-off arc (9) with a small contact area and that between the pillars and pins (3f) - hereinafter only referred to as pillars - despite the tight control a large gas expansion space remains. 500- 119? 10 Circuit breaker according to Claim 1, a particularly narrow circuit breaker for cables, characterized in that a housing (1) formed in one of two half-cups (1a, 1b) has a contact device (5) comprising a fixed contact piece (Sa) and a movable contact arm (5b) with single break, which together form a U-shaped current loop, and with an extinguishing plate stack (4) inserted in the extinguishing chamber (3) approximately at right angles to the current loop, which has from its outer extinguishing plates towards the contact device (5) directed arc guide rails (§a ', 6, 7) for controlling the arc foot points, the atrium chamber (3c) on both inner side surfaces (3a, 3b) of the housing (1) is provided with the pivot plane directed towards the contact arm (5b), bridge-shaped sealing walls (bridges 3d, 3e), which with the exception of a narrow gap left in the pivot area of the contact arm (5b) and adapted to its width, are almost arranged against the contact horn (5a ') of the fixed contact piece (Sa) as a part of the upper arc barrel the rail (6) and also along the, elongated, lower arc travel rail (7) cooperating with the movable contact arm (Sb), and that in the thus formed flow channel (8) between the sealing walls (bridges 3d, 3e, wall parts le) from the both side surfaces (3a, 3b) the pins (3f) are arranged distributed between the contact point area (Sa, 5b) and the end sides of the extinguishing plates (4a). Circuit breaker according to one of Claims 1 or 2, characterized in that the columns (3f) are arranged inside the flow channel (8) between the sealing walls (bridges 3d, 3e, wall parts 1c) and are mutually distributed in such a way that around imaginary circles of approximately the same diameter at their points of contact are tangential to both adjacent such circles and also the sealing walls. Automatic circuit breaker according to one of Claims 1 to 3, characterized in that the columns (3f) are arranged at approximately equal distances in a row at one point in succession. ll Automatic circuit breaker according to one of Claims 1 to 4, characterized in that the columns (3f) with their foot points are arranged on an imaginary arcuate line approximately in the middle between the curved extending bridges (3d, 3e). Circuit breaker according to one of Claims 1 to 4, characterized in that the columns (3f) with their foot points are arranged almost evenly distributed in a zigzag line on the side surfaces (3a, 3b) between the bridges (3d, 3e) in the flow channel. (8). Circuit breaker according to one of Claims 1 to 6, characterized in that the columns (3f) on one side surface (3a) are arranged offset relative to the columns on the other side surface (3b) of the housing (1). Circuit breaker according to one of Claims 1 to 7, characterized in that the columns (3f) on one side surface (3a and 3b, respectively) are designed with the same height as the associated bridges (3d, 3e) and have a plane existing in one plane. end surfaces (3f '). Automatic circuit breaker according to one of Claims 1 to 8, characterized in that the bridges (3d, 3e) and also the columns (3f) are designed directly in connection with the manufacture of the housing parts (1a, 1b). Circuit breaker according to one of Claims 1 to 9, characterized in that preferably between five and nine pillars (3f) are arranged on each side surface (3a and 3b, respectively) inside the atrium chamber (3c). Automatic circuit breaker according to one of Claims 1 to 10, characterized in that approximately 5 to 15% of the total area of the flow channel (8) between the sealing walls (bridges 3d, 3e, wall parts le) is covered by the base surfaces of the columns (3f). Automatic circuit breaker according to one of Claims 1 to 11, characterized in that the columns (3f) are round or polygonal and have a diameter and a side length of approximately 2 mm. 503-19? 12 Circuit breaker according to one of Claims 1 to 12, characterized in that the columns (3f) on either side of the contact opening plane have a height of approximately 6 mm. Automatic circuit breaker according to one of Claims 1 to 13, characterized in that the columns (3f) are designed with a conicity of approximately 10 ° tapered in the direction of the contact opening plane. Circuit breaker according to one of Claims 1 to 14, characterized in that the gap between the end surfaces (3f ') of the columns (3f') and the upper sides of the bridges (3d, 3e) in the two half-shells (1a, 1b) of the housing (1) has a width of approximately 3 mm. Circuit breaker according to one of Claims 1 to 15, characterized in that the bridges (3d, 3e) are designed for positioning and holding on one side the fixed contact piece (Sa) together with the contact horn (5a ') and on the other hand. of the lower arc guide rail (7).