FI96254C - Automatic switch, in particular circuit breaker - Google Patents

Description

- 96254

Automatic switch, in particular circuit breaker

The invention relates to an automatic switch according to the preamble of claim 1, in particular to a narrow line circuit breaker of construction.

Such switches, especially with shaped shut-off chambers, are known in numerous embodiments. As examples, reference is made to German Patents 1,185,269 and 1,185,274. The switches known from the present 10 include an arc chamber with extinguishing plates arranged in connection with the contact point inside the housing for efficient extinguishing of the switching arc generated in the event of a short circuit.

Further development forms of these basic chamber shapes are described, for example, in DE 2 716 619 B1, DE 3 337 562 A1, EP 0 123 090 B1, EP 0 158 124 A2 and EP 0 251 160 A2. What all these extinguishing devices have in common is that they comprise a plurality of spaced-apart extinguishing plates arranged side by side and two insulating material plates arranged transversely in front of them on the sides of the contact device 20 in the so-called pre-chamber area. Insulation sheets, usually made of ceramic or also plastic, are fitted at a distance from the outer walls of the housing. Thus, the flow of arc gases around the plates and, respectively, pressure equalization is enabled.

25 The disadvantage of these fire extinguishers is both of the additional insulation boards, which, in addition to the partial costs, also require the corresponding installation costs. In addition, there is also a considerable risk of breakage if the ceramic plates are not precisely positioned or slid when the housing parts are closed. Clutch malfunctions caused by fractions of insulating material plates flying around the housing can therefore easily result.

In order to save the insulation boards, it is already known from 35 FR 2 575 861 B1 to provide the line protection switch 96254 2 with arc control means included in the pre-chamber area. These consist of rows of ribs formed opposite each other on the inner walls of the arc chamber housing. Between the rows of ribs, which may have a wooden structure 5 or which may also be made as individual straight walls, a central channel remains. According to the design of the ribs, these are surrounded by grooves or notches, which in turn contain a deionized cold gas supply and which, when disconnected, must guarantee the return of the gas in the direction of the contact zone. Rows of ribs arranged to stand freely approximately in the middle of the pre-chamber area propagate only the creep path between the contacts without leading it to the intended control of the switching arc or also of the arc gases. In this case, the shape and location of the grooves are substantially determined so that the thickness of the ribs is kept the same in order to avoid cavities and irregularities in the housing parts. Thus, design and compression techniques are a priority in the design of the ribs of this switch. On the other hand, optimized gas recovery and faster passage of the switching arc from the point of contact to the extinguishing plates is not guaranteed in connection with such an extinguishing chamber.

The object of the invention is to simplify the extinguishing chamber from its pre-chamber area in connection with an automatic switch of the above-mentioned quality and to provide improved arc control and in particular to provide lower flow resistance to the pre-chamber space, so as to ensure faster and safer switching of the switching arc from the contact point to the extinguishing plate stack.

This object is solved by an automatic switch having the features indicated in claim 1. Developments and preferred embodiments of the invention are the subject of dependent claims.

The design of the extinguishing chamber according to the invention is advantageous in that the switching arc is the arc of the arc! 96254 3 accelerated by the magnetic field of the rails between the protruding upper sides of the tightly adjacent strips and guided tightly laterally by a number of columns or pins arranged to be divided into a pre-chamber space, and 5 runs in a narrow gap. Thus, in addition to improved arc control, good arc acceleration is created at low gas pressure. At the same time, the accelerating effect of the gas-donating material of the strips and columns is exploited as intended to further accelerate the arc 10.

In the case of closed side panels, on the other hand, this effect is often already too strong. Furthermore, the gas pressure generated in front of the traveling arc can start in the free spaces between the columns, so that there is only a small flow resistance in front of the switching arc 15 in the direction of the extinguishing plates and thus the arc can leave the point of contact quickly and safely. In connection with the shift of the arc, the potentially preventive pressure-20 difference due to the backflow of gases between the columns is effectively equalized in front and behind the arc. At the same time, this pressure equalization ensures good deionization of the area exposed to re-ignition at the point of contact behind the arc. Since the arcs load the edges of the strips only to a small extent, the result is also good insulation strength in the case of the 25 open contacts. A further advantage of the invention is further that a high arc speed and a low gas pressure in the pre-chamber space can be achieved with the direct design of the columns and also the sealing walls 30 by manufacturing the housing parts from duroplastic or thermoplastic and thus at low cost. The omission of both the most common insulation boards to date from the pre-chamber area thus means considerable cost savings.

96254 4

The invention is described in more detail below in connection with the drawing by means of an exemplary embodiment.

Fig. 1 shows in a simplified manner a line protection switch comprising an upper casing 5 opened in the region of the extinguishing chamber, while Fig. 2 shows a section of the extinguishing chamber according to line II-II in Fig. 1.

Fig. 3 shows the area of the extinguishing chamber essential to the invention of the housing half-shell in a perspective view, while Fig. 4 shows a schematic exploded view of the inner contours of the two separated housing half-shells in the area of the extinguishing chamber.

The line protection switch comprises, as a narrow design 15, a housing 1 connected by two housing shells 1a, 1b, the upper part of which receives only the coupling and tripping mechanism 2 indicated with reference. The base area below it has a housing 3 made of duroplastic or thermoplastic molding compound. for the most part filled with extinguishing plate surfaces 4 arranged parallel to the bottom surface le of the coupling. The depth of the extinguishing chamber between its two inner side surfaces 3a, 3b is then from the standardized coupling width to the outer walls 1a 'of the technically conventional wall thickness. Ib 'prescribed.

The fire-extinguishing plate stack 4 placed in the extinguishing chamber and pressed against the housing wall Id with its left-hand narrow end faces with blow-out openings is 30 on both its upper and lower longitudinal sides of the arc running rails 6 and resp. 7, which in turn are directed to the region of the contact device 5 in the pre-chamber space 3c of the extinguishing chamber. For example, with nine mutually spaced extinguishing plates 4a of ferromagnetic raw material, as well as a stack of mud flaps 96254 5 completely fills the box-like part of the extinguishing chamber between both inner side surfaces 3a, 3b on the side of the pre-chamber space 3c. .

The contact point with single disconnections arranged in the approximately upper funnel-shaped pre-chamber space 3c on the upper right edge of the extinguishing chamber consists of a fixed contact piece 5a connected to the starting point 11 via the electrical conductor parts 10a and the release coil 10 and pivoted about the shaft. This is via the moving lines 12a, 12b according to the thermal trigger 12, in connection with the input pin 13, and turns counterclockwise in connection with the disconnection. At the actual contact point of the contact, the fixed contact body 5a and the contact arm 5b together with their power supply lines form an approximately U-shaped current loop directed perpendicular to the direction of the extinguishing plates 4a. The individual extinguishing plates have an arc-enhancing, approximately V-shaped section 4b on their end side facing the pre-chamber space 3c and cover the entire open cross-section of the pre-chamber space substantially closed by the wall portions le with the end contour thus formed. The opening 25 required only for the pivoting movement of the contact arm 5b is notched in the wall portions le, so that the pre-chamber space 3c is made almost pressure-tight with respect to the switching and tripping mechanism in connection with the arc guide rails 6, 7.

However, the two pre-chamber spaces 3c on both side surfaces 3a, 3b with narrow prismatic protruding, narrow strips 3d, 3e with respect to the center of the housing, which normally have a rectangular cross-section, but which can also be made trapezoidal or stepped, are essential. They are formed directly on both housing shells 1a, Ib from the bottom of the outer walls 35la ', Ib' to the pivot plane 96254 6 of the movable contact arm 5 and their upper sides preferably terminate at the same distance from the side surfaces. However, in the plane of the extinguishing chamber, i.e. in the plane of the drawing of Fig. 1, strips 3d, 3e of approximately equal width run in different shapes as arcs from the area of the contact-5 device to the end contour of the extinguishing plate stack.

The upper strip 3d then presses tightly against the fixed contact piece 5a and follows its contact horn 5a 'on the side facing the pre-chamber space up to the wall of the extinguishing chamber 10 in the region of the upper arc running rail 6. The strips 3d of both housing shells engage the fixed contact piece together on the contact side as well as on both narrow sides, so that in the middle between the strips 3d there is practically only a gap corresponding to the width of the contact arm 5b along the arc horn 5a '.

Correspondingly, the same applies to the strip 3e along the lower arc running rail 7. This is likewise fixed tightly to the longitudinal edges with respect to the pre-chamber space 3c on both sides by means of the strips 3e, so that there is only a gap about the width of the contact arm which forms the base of the switching arc 9. With the help of the upper sides of the strips 3d, 3e, the arc can thus enter the fire plate stack in the gap. The slightly protruding groove 7 ', located on the lower rail of the arc 25 in the vicinity of the gap, further supports the straight direction of travel of the base of the arc. The acceleration of the arc is further positively affected by the parts of the wide ferromagnetic arc running rails 7 covered by the strips 3e from the side, since the larger cross-section of the material 30 enhances the arc-accelerating effect.

Another main feature of the invention is a plurality of columns arranged in the pre-chamber space 3c or also pins 3f - hereinafter referred to only as columns - which are arranged in the free cross-section between the strips 3d, 3e approximately evenly distributed. The circular or angular columns 3f of the cross-section are then equally spaced with respect to the strips 3d, 3e and with each other and extend from the side surfaces 3a, 3b almost to the pivot plane of the contact arm 5b, so that only the narrow gap remains free as a continuous end. between the surfaces 3f '. The end faces of both column groups thus tightly protect the coupling arc 9 drawn to the point of contact from the side together with preferably equally high strips 3d, 3e, while its heels ve-10 are filled with the contact horn 5a 'and the arc running rails 6, 7 apart and from the contact area. in the direction of their motion accelerates (arc positions 9 ', 9 ").

The columns 3f are preferably arranged with a light zig-15 sak displacement with respect to their ideal centerline between the two strips 3d, 3e from the contact area in the direction of the end sides of the extinguishing plates, but they could also be arranged directly in a row on this ideal line. Only two columns are preferably arranged in the funnel-like expanding area immediately in front of the extinguishing plates 4a (Fig. 1, Fig. 3). According to an exemplary embodiment, seven columns 3f are formed for each housing half-shell 1a, Ib immediately in connection with the manufacture of housing parts, the columns being preferably lightly conical in shape with an average diameter of 2 mm and a height of about 6 mm. Since in connection with the line protection switch, due to the shape of the contact device and its position with respect to the arc rails, both the number of extinguishing plates and their fitting to the extinguishing chamber are possible, different technically feasible solutions for pre-chamber design are possible, the arrangement of columns 3f also depends on said criteria. The number of columns in each housing part then depends essentially on the size of the pre-chamber space, while their position should be as evenly spaced as possible distributed between the contact area and the end sides of the extinguishing plates. Ideally, the column groups are arranged in both housing half-shells, always interleaved, as shown in particular in Figure 2. Thus, in spite of the strict control of the switching arc 9, the friction acting on it is reduced due to the columns 3f, because practically only one end surface of both groups of columns is acting alternately when the arc passes.

Irrespective of the number, size and location of the columns, these require a base surface of about 5 to 15% of the pre-chamber bridge surface between the strips 3d, 3e, so that the flow channels 8 separated by the sealing walls 15 and the wall sections remain open around the columns 3f. 3d, 3e, le change the switch.

Due to the small volume of the columns 3f with respect to the entire pre-chamber space, an optimally large gas expansion space is thus obtained, even if the arc is tightly controlled and therefore its current density is kept as high as possible. The resulting strong electrodynamic operation as well as the practically insignificant friction on the end surfaces of the columns ensure a safe and fast passage of the switching arc from the point of contact to the extinguishing plate stack. At the same time, the existing expansion space and flow channels 25 around the columns are responsible for the low gas pressure, which in turn lowers the ion concentration and prevents the risk of re-ignition behind the arc. The space behind the fixed contact piece 5a can then act as a kind of buffer as well as a cooling air mass reserve when the strip 3d surrounding the contact horn up to the upper arc running rail 6 ends approximately on the upper side of the contact point. Thus, between the end of the strip 3d and the wall part le, a transverse flow channel 8 'remains, which enables pressure-sealing above the point of contact towards the actual pre-chamber-space 3c.

96254 9

The arrangement of the columns described above and shown in the figures of the drawing, as well as the entire design of the pre-chamber space for the line protection switch, can also be used for other automatic switches, taking into account the mentioned criteria. In this case, in individual cases, the columns and strips must be adapted by the person skilled in the art to the dimensions of the extinguishing chamber and the pre-chamber space without departing from the scope of the idea of the invention.

Claims (11)

An automatic circuit breaker comprising a housing (1) made of insulating material intended to receive the coupling mechanism (2), and a quenching chamber (3) surrounded by the housing and having at the sides of the contact device (5) a chamber space (3c) ) with light-beacon aid for passing the coupling light-beacon from the contact point to a light-beacon extinguishing area, in particular a extinguishing plate stack (4), which in turn closes a pre-chamber space (3a), which extends funnel-shaped from the contact device (5) and is provided with light-beacon grooves (6, 7) from the side facing away from the contact point, characterized in that at least one side surface of the inner side surfaces (3a, 3b) of the housing (1) has at least one side surface of the housing (1). ), which are located almost parallel to the contact opening's pivot (contact lever 5b), provided moldings (3d, 3e) of insulating material, starting approximately from the contact device (5) and abutting from this unit. ll towards the light bend rails (5a ', 6, 7), the strips enclosing the light bend rails (5a', 6, 7) all the way to the gap which is on the contact plane of the contact and leads to the chamber chamber (3c), simultaneously forming sealing walls against the coupling mechanism (2), and having in the flow channel (8) leaving in the chamber (3c) between the sealing walls (strips 3d, 3e; wall portion 1c) is provided with a plurality of pillars or pins (3f) which extend from the bottom of the side surfaces (3a, 3b) in the direction of the contact plane of the contact and have been distributed approximately evenly by means of their end ends (3f ') and in conjunction with the strips (3d, 3e), a narrow side-length control of the coupling light beams (9) at a small contact surface is allowed and that between the pillars or pins (3f) -in the following they will be called only pillars - 35, despite the tight control, leaves a lot of room for gas expansion. li 96254 15 Automatic circuit breaker according to claim 1, in particular a narrow protective conduit coupler and having a housing of two half shells (1a, 1b), in which conduit protective coupler is provided a contact device (5) consisting of a fixed contact piece (5a) and a movable contact lever (5b) with one-off refraction, which together form a U-shaped current loop, and a roughly vertical extinguishing plate stack (4) directed to the current loop, which is arranged in the extinguishing chamber (3) and comprising light-bending rails (5a ', 10, 6). 7) directed from the outermost extinguishing plaques to the contact device (5) for controlling the coupling light beacon points, characterized in that the anterior chamber space (3c) is provided on the inner side surfaces (3a, 3b) of the housing (1) with molded sealing walls (3). , 3e), which is directed towards the pivot plane of the contact lever (5b) and is in addition to the narrow gap, which remains free and is intended to form the solder point of the coupling light beacon (9), the pivoting area of the contact lever (5b) and adapted to its width almost in contact with the contact horn (5a ') of the fixed contact piece 20 (5a) as part of the upper light rail running rail (6) and likewise along the extended, lower light rail rail (7) with the movable contact lever, and that the flow channel (8) thus formed between the sealing walls (strips 3d, 3e, wall portion 1c) is formed in a plurality of columns (3f) which protrude from the two side walls ( 3a, 3b) bottom and are approximately evenly distributed between the contact area area (5a, 5b) and the end ends (4a) of the extinguishers, which are pillar-facing end ends (3f ') abutting closely from the contact point (5a, 5b) against the sides of the coupling light beam ( 9), which runs on light rail running rails (5a 'and 6, 7, respectively),. on the one hand, on its way to the extinguishing plate stack (4), on the other hand, it targets a small, current resistance generated by the surface friction. 96254 16 Automatic switch according to claim 1 or 2, characterized in that the pillars (3f) are arranged on the inside of the flow channel (8) between the sealing walls (strips 3d, 3e, wall parts 1c) and among themselves distributed in such a way that the circles which are intended to preferably around the solder points and having the same diameter, the bed tangles each other in the case of adjacent circles and the sealing walls at the periphery. Switch according to claims 1-3, characterized in that the columns (3f) have been arranged in a row at approximately equal distances like points in succession. Switch according to claims 1-4, characterized in that the pillars (3f) are arranged in such a way that their solder points are located on an ideal bending line approximately in the middle of the billowing strips (3d, 3e). Switch according to claims 1-4, characterized in that the pillars (3f) are arranged in such a way that their solder points are likewise on a zigzag line 20 on the side surfaces (3a, 3b) almost evenly distributed between the strips (3d, 3e) in the flow channel (8). Switch according to claims 1-6, characterized in that one pillar (3a) of the side surface (3f) has always been arranged in relation to the pillar of the other side surface (3b). Switch according to claims 1-7, characterized in that the columns (3f or 3b) of the second side surface (3f) have been made as high as the corresponding strips (3d, 3e) and have end ends (3f) located on same piano. Switch according to claims 1-8, characterized in. characterized in that the strips (3d, 3e) and also the columns (3f) have been formed immediately in connection with the manufacture of the housing parts (1a, 1b). u 96254 17 Switch according to claims 1 to 9, characterized in that the columns (3f) are made round or also angular and have a diameter or side length of about 2 mm. Switch according to any one of claims 1 - 10, characterized in that the strips (3d, 3e) have been made for laying and pouring the fixed contact piece (5a) and the contact horn (5a ') as well as the lower light rail running rail (7). .