HU207903B - Interrupter switch - Google Patents

Description

Scope of the description: 8 pages (including J page) ί

There are several columns (3f) disposed approximately between the two side surfaces (3a) upwardly between the two side surfaces (3a) between the contacts and the front faces of the arcuate plates (4a), with their facing faces (3f '). ) define a narrow arc guide channel and a low surface friction arc guide surface.

The present invention relates to a circuit breaker, in particular a cable protection switch, in a narrow version. The circuit breaker has a housing for receiving the switching device and an arcing chamber surrounded by the housing. In the arcing chamber there is a front chamber adjacent to the contact structure. In the pre-chamber space there are arc guide elements through which the switching arc enters an arc burner from the point of contact. Particularly as an extinguishing part, an arc-extinguishing plate package is used. The arc extinguishing disk package closes the front chamber chamber with the arc guiding rails from the contact structure to the arcuate plates, on the side opposite to the point of contact.

There are a number of embodiments of such switches with a specially designed arcing chamber. By way of example, reference is made to DE-PS 1 185 209 and DE-PS 1 185 274. Inside the housing of the known switches made of insulating material, there is an arcing chamber associated with the point of contact, and there are arcuate sheets in this arcing chamber which effectively deactivate the switching arc of the short circuit.

Further enhancements to these chamber-base forms are described for example in DE 2716619 B1, DE 3 337562 A1, EP 0123 090 B1, EP 0158124 A2 and EP 0251 160 A2. A common feature of all these arc extinguishing devices is that in the so-called pre-chamber section there are a plurality of arcuate sheets disposed adjacent to each other in a certain distance and, in front of them, insulating sheets surrounding the contact structure. In most cases, insulating sheets made of ceramic or plastic are at a certain distance from the exterior walls of the house. This allows pressure equalization and the arc gases to flow around the sheets.

These arcing devices have the disadvantage of using two additional insulating sheets. In addition to the cost of the component, these require an appropriate installation effort. In addition, there is a serious risk of breakage when the ceramic tiles are not inserted correctly when the parts of the house are closed or these sheets slip. This can easily be the result of the disruption of the free-flowing pieces in the housing from the insulation sheets, causing malfunction at the switch.

It is already known from FR 2 575 861 Β1 that, in order to save the insulating sheets, a wire shield switch having integrated arc guiding means in the front chamber portion is used. These arc guiding means are rows of ribs arranged opposite each other on the inner walls of the arc chamber. Between the rows of lines, which may have a tree-like structure, or can be formed as some straight walls, a central channel remains. Depending on their shape, the ribs are surrounded by grooves or grooves that contain deionized cold gas reserves and, when disconnected, must provide gas recirculation towards the contact zone. In the pre-chamber part, roughly centrally free rows of freestanding ribs only widen the creep path between the contacts without targeting the switching arc or arc gases. When determining the shape and position of the grooves, only the uniform thickness of the ribs is intended to exclude the unevenness and sprawl of the parts of the house. The forming rows of this switch therefore have shaping and pressing aspects in the foreground. However, in the case of such arcing chambers, optimum gas recirculation and the fastening of the coupling arc from the point of contact to the arc sheet are not ensured.

It is an object of the present invention to provide a circuit breaker in which the arc chamber is pre-chambered, the arc is better guided and the flow resistance in the pre-chamber space is particularly low to provide a quick and secure discharge of the switching arc from the point of contact to the arcing plate package.

In accordance with the invention, this task is solved by the fact that legaf of one of the inner side surfaces of the housing in the pre-chamber space parallel to the plane of the contact movement of the contact arm is made of insulating material, starting at about the contact structure and along the arc guide rails. there are tongues which, by omitting a gap in the arc guide rails, encircle the arc guide rails towards the front chamber and at the same time form sealing walls towards the coupling device. In the remaining flow channel of the pre-chamber space, several columns or studs extending from the base of the side to the contact opening plane of the tongue and tongue between the tongues and the wall portion are arranged approximately uniformly so that they conduct tightly on their face surfaces and tongues with a small contact surface laterally despite the tight conduction, there is a large gas expansion space between the coupling arc and the columns and pins, hereinafter referred to as columns only.

In another preferred embodiment of the circuit breaker according to the invention, the housing of the switch consists of two housing halves. In the housing there is a single contact contact with a fixed contact element and a movable contact arm. The former together form a U-shaped current loop. In the switch, the arc loop is inserted approximately perpendicularly into the arcing chamber by an arc extinguishing disk packet, the outer sheet 55 of the outer sheet 55 and the arc guide rails directed towards the contact structure guiding the base of the switching arc. In the pre-chamber space, there are tongue-sealing walls facing the movement plane of the contact arm on the two inner sides of the housing. These sealing walls have a loose gap, which is freed from the bottom of the coupling arc for the sole

By leaving the contact arm in the turning space of the contact arm and its width, the fixed contact member is hinged almost to the contact arm, as part of the upper arc guide rail, and along the extended lower arc guide rail cooperating with the movable contact arm. In the flow channel thus formed, there are several columns upwardly from the base of the sidewalls between the sealing walls, disposed approximately uniformly between the contact points and the front sides of the arcuate plates. The front faces of these columns facing each other from the point of contact to the arc guide rails are narrowly bounded on the side by way of the arcing disc package, on the other hand, they exhibit low flow resistance against the arc caused by the surface friction.

It is preferred that the columns in the flow channel, between the sealing walls and between each other, be arranged so that the circles of approximately equal diameters around their base points touch each other and the circumference of the sealing walls.

It is also advantageous if the columns are arranged in a row, exactly behind each other, at approximately the same distance from each other. There are also other advantageous ways of positioning the columns.

Preferably, the tongues and the columns may be formed directly on them when producing the housing halves.

In the pre-chamber space, there are preferably between five and nine columns on each side surface and about 5 to 15% of the total surface area of the flow channel between the sealing walls is covered by the column faces.

The columns may be either wheels, angular and have a diameter or side length preferably of about 2 mm.

The design of the arcing chamber according to the invention is advantageous because the arc of the arc driven by the magnetic field of the arc guiding rails between the protruding upper sides of the tongues which are firmly held there is laterally tightly bounded by the columns or pins disposed in the pre-chamber space, and the arc runs in a narrow gap. This improves arc conduction and at the same time ensures high acceleration of the arc at low gas pressure. At the same time, the tongues are used specifically to drive the thrust of the columns to release the additional force on the arc. It can expand in the space between the gas pressure and the columns in front of the advanced arc, so that the arc of arc encounters only a small flow resistance in the direction of the arched plates and thus can quickly and safely run off the contact area. As the arc moves, the return of the gases between the columns can effectively compensate for the differential pressure before and after the arc. At the same time, this pressure equalization ensures good de-ionization of the retarded area at the point of contact behind the arc. In addition, the tongue sealing walls increase the creep paths at the point of contact. Even with open contacts, the insulation strength is high, as the arc only slightly overloads the edges of the tongues. A further advantage of the invention is that the high velocity of the arc and the low gas pressure in the pre-chamber can be achieved without the above-mentioned effects, without increasing the cost, by also removing the columns and sealing walls directly from the thermoplastic or thermoplastic plastics. can be formed. Thus, with the absence of two sheets of insulating material commonly used in the pre-chamber section, significant cost savings can be achieved.

The invention will now be described in more detail with reference to the accompanying drawings, of which:

Figure 1 is a simplified view of a wire shield switch with an upper housing half open at the arc chamber;

Figure 2 is a sectional view of the arcing chamber of Figure II-II. line;

Fig. 3 is a perspective view of one embodiment of a vaccine chamber according to the invention;

Figure 4 is a schematic exploded view of the inner contours of the two separated halves at the arched chamber.

The narrow-gauge cable protection switch has a housing (1) made of two (la, lb) housings (1). In the upper part of the housing (1) there is a switching and tripping device (2), which is indicated only. The base portion below is a housing (1) made of thermosetting or thermoplastic material, the largest portion (3) of which is formed as an arc extinguisher. Most of the arcing chamber (3) is filled with an arcing disc packet (4) disposed parallel to the bottom (down) surface of the switch. The depth of the arcing chamber (3) between the two inner surfaces (3a and 3b), starting from the standardized switching width, is predetermined by the usual wall thickness of the exterior (la 'and lb') walls of the housing.

With the narrow narrow faces of the left hand side inserted into the arcing chamber (3), the arcing disc packet (4) on the upper and lower longitudinal sides of the flange (4) with the outlet openings (ld) is bounded by the guide rails (6 and 7). The rails (6 and 7) are directed towards the contact structure (5) in the front chamber (3) of the arc (3c) chamber (3). For example, a nine-sheet arc-blocking plate (4) of ferromagnetic material (4a) spaced at a certain distance completely fills the box (3c) between the inner, (3a and 3b) side surfaces (3c) of the arc chamber (3c). and is fixedly fixed in a manner not shown therein.

On the right upper edge of the arcing chamber (3), a single interrupted (5) contact structure, located in the funnel-shaped (3c) pre-chamber space, consists of a stationary contact element (5a) and a movable contact bar (5b). The lower contact member (5a) is connected to the output conductor (10a) and a release (10) by means of a terminal (11). The contact arm (5b) can be rotated about an axis fixed to the housing, and movable (12a, 12b) and through the interlock (12) between the input terminals (12). The contact arm (5b) turns counterclockwise when switching off.

The stationary contact element (5a) and the contact arm (5b), together with their current leads at their actual contact point, have a U-shaped current loop 3

EN 207 903 nek is located perpendicular to the direction of the arcuate sheets (4a). On the front side of each arcuate sheet (4a) facing the front chamber (3c), there is an approximately V-shaped (4b) notch. This cut (4b) improves arc penetration. The curved plates (4a) cover the entire open cross-section of the front chamber (3c) surrounded by wall portions (predominantly) relative to the other housing portions so formed. Only the recess required for the pivoting movement of the contact arm (5b) is formed in the wall sections (down). Thus, the pre-chamber (3c), together with the rails of the arc guide (6, 7), is formed close to the push and release device (2).

There is a very significant arrangement of narrow (3d and 3e) tongues extending in the front chamber (3c) on the two sidewalls (3a and 3b) towards the center of the housing. These are normally rectangular rectangular in cross-section, but may be trapezoidal or stair-shaped. The tongues (3d and 3e) are formed directly from the two halves (1a and 1b), extending from the outer (la ', lb') walls to the moving plane of the movable contact arm (5b), and preferably extending at the same distance from the side surfaces. . In the plane of the arcing chamber (3), i.e. in the plane of Fig. 1, the tongue contour of the arcing plate package (4) extends from the contact structure (5) to the tongues of approximately the same width, but of different arches (3d, 3e).

The upper (3d) tongue rests firmly on the stationary contact element (5a) and follows the contact horn (5a ') on the side facing the front chamber (3c), up to the wall of the arcing chamber (3), at the upper arc guide (6) rail. The tongues (3d) of the two housewives (la and lb) together surround the stationary contact element (5b) on its contact side and two narrow sides such that between the tongues (3d) there is practically only one gap remaining in the center, corresponding to (5b) the width of the contact arm along the contact arm (5a ').

The same applies to the tongue (3e) along the rail of the lower arc guide (7). The lower arc guide (7) rails (3e) on the longitudinal edges towards the front chamber (3c) are closely surrounded on both sides, so that there is only one gap left there that is roughly the same as the contact arm (5b). This gap is used to form the base of the switching arc (9). The arc, which is tightly surrounded by the upper sides of the tongues (3d, 3e), can thus be inserted into the arcing disc packet (4) within the gap. A slightly protruding rib (7 ') on the rail of the first arc guide (7) adjacent to the slot further promotes the straight-line travel of the base of the arc. The arc drive is furthermore positively influenced by the wider portions of the ferromagnetic arc guide (7) by the tongues (3e), as the larger material cross section improves the arcing effect.

According to the present invention, a plurality of columns (3f) or pins (3c) are referred to in the prior art chamber (hereinafter referred to as columns only), which are distributed approximately uniformly in the free cross-section between the tongues (3d, 3e). The distance between the columns (3f) of the round or square cross-section (3f) is roughly the same as the tongues (3d, 3e). The column (3f) extends from the side surfaces (3a, 3b) to the movement plane of the contact arm (5b), so that only one narrow, through-gap between their front surfaces (3f ') remains free. Thus, the front surfaces of the two column groups are tightly bounded on the side of the coupling arc (9) drawn at the point of contact, preferably with the same high tongue (3d, 3e). The points of the arc of the arc (5a ') and the arc guide (6, 7) are folded out of each other and accelerated from the contact area in the direction of the arcing disc package (4). These situations are indicated by the switching curves (9 ”and 9”).

The columns (3f) are preferably slightly zigzagged between the two (3d and 3d) tongues, in the direction of the arcuate plates (4a) from the point of contact. However, they can be placed in a straight line on this ideal line. Only the funnel-expanding portion directly in front of the arcuate plates (4a) has ideally two columns, as shown in Figures 1 and 3. Both housewives (1a and 1b), according to the exemplary embodiment, form seven (3f) columns directly with them in the production of the housing halves. The columns preferably have a truncated cone shape with a center diameter of about 2 mm and a height of about 6 mm. Since, in the case of the wire protection switches, on the one hand, depending on the shape of the contact structure and the position of the arc guide rails, on the one hand, and the number of arcing plates and their arrangement in the arcing chamber on the other, various technically suitable solutions are possible, therefore the arrangement of columns (3f) also depends on the said criteria. The number of columns on each side of the house depends essentially on the size of the front chamber. As far as their position is concerned, the columns should be distributed as evenly as possible between the contact area and the sides of the arched plates. Ideally, the column groups in the two housings are positioned so that there is a column space opposite the column on one side. This is most evident in Figure 2. Thus, in spite of the tight guiding of the switching arc (3), the columns (3f) reduce the curve effect on the arc, since only one of the two faces of the column column alternates with the arc when running the arc.

Columns - regardless of their size, size and position - occupy 5 to 15% of the base surface remaining between the pre-chamber (3d, 3e) tongues (3c), with flow (8) channels remaining around the columns (3f) , separated by tongue walls (3d, 3e) and (down) walls from the rest of the switch. Due to the small volume of the columns (3ij relative to the entire pre-chamber space, an optimally large gas expansion space is created, despite the fact that the arc is tightly guided and therefore kept its current density as high as possible. The resulting large electrodynamic drive and practically negligible on the forehead surfaces of the columns friction ensures a safe and fast flow of the switching arc from the contact area to the arcing disc packet, while the existing expansion space and the flow channels around the columns reduce the gas flow.

EN 207 903 Β, which in turn reduces ion concentration and limits the risk of re-collapse behind the arc. The space behind the stationary contact element (5a) may serve as a compensating space and as a cooling air mass reserve, when the tongue (5a ') extending to the upper arc guide (6) extends approximately to the upper side of the contact area. Thus, there is a cross-flow (8 ') channel between the end of the (3d) tongue and the (down) wall portion, which allows pressure equalization over the contact area to the actual pre-chamber (3c).

The arrangement of the columns, as described above and illustrated in the drawings, adapted to the wire protection switch, and the entire design of the front chamber, can be applied to other circuit breakers, taking into account the said criteria. To this end, the skilled artisan must adapt the columns and tongues to the spatial dimensions of the arc chamber and the pre-chamber, according to the individual case, without breaking the thought content of the invention.

Claims (16)

PATENT CLAIMS 1. A circuit breaker with an insulating material receiving housing for a switch and release mechanism and an arcuate chamber having a contact structure enclosed with the housing, wherein the pre-chamber defining the contact structure is laterally guided to the arcuate space, closure of the pre-chamber with arcuate rails extending towards the arch plates on the side opposite to the point of contact, characterized in that in the pre-chamber space (3c) , 3b) at least one of which comprises tongues (3d, 3e) made of insulating material starting in the region of the contact structure (5) and lying thereon along the curved rails (6, 7) and the contact horn (5a '). which surround the arcuate rails (6,7) and the contact horn (5a ') by a gap in the opening plane of the contact, towards the pre-chamber space (3c) and at the same time form sealing walls towards the switch and release device (2); in the remaining flow passage (8c) of the pre-chamber space (3c) between the tongues (3d, 3e) serving as sealing walls and the wall portions (le), the columns (3f) extending from the base of the side surfaces (3a, 3b) to the contact opening plane; that the end faces (3f ') of the columns (3f) are connected to the resulting coupling arc (9) with a small contact surface, to form a narrow channel for close lateral guidance of the coupling arc (9) and the tongues (3d, 3e), and there is a large gas expansion space between the columns (3f) despite the narrow channel. Breaker switch, in particular a narrow circuit breaker with a housing (1) consisting of two housing halves (1a, 1b), a single contact element (5) consisting of a stationary contact element (5a) and a movable contact arm (5b), which together forming a current loop and an arc plate plate (4) approximately perpendicular to the current loop and inserted into the arc chamber (3), the conductor rails (6,7) and the contact horn (5c ') of the outer arc plates (4a) facing the contact structure (5). guiding the base points of the switching arc (9), characterized in that they are tongues (3d, 3e) in the anterior chamber (3c) of the arching chamber (3) on the two inner side surfaces (3a, 3b) of the housing (1) ) are provided with sealing walls which, by leaving a narrow gap left open for forming the base point of the switching arc (9), are provided in the pivot area of the contact arm (5 b) en and its width, they lie almost on the contact horn (5a ') of the stationary contact element (5a) as part of the upper curved rail (6) and along the extended lower rail (7) cooperating with the movable contact arm (5b) in the formed flow passage (8), a plurality of columns disposed between the tongues (3d, 3e) and wall portions (le) serving as sealing walls, extending from the base of the two side surfaces (3a, 3b) roughly evenly between the contacts and (3f) having facing faces (3f ') defining a narrow arc guiding channel and having a low surface friction arc guiding surface. The circuit breaker according to claim 1 or 2, characterized in that the columns (3f) in the flow passage (8) are between the tongues (3d, 3e) and wall portions (le) which also serve as sealing walls, and with each other they are arranged so that imaginary circles of substantially the same diameter around their base points touch each other and the circumference of the sealing walls. 4. Breaking switch according to any one of claims 1 to 3, characterized in that the posts (3f) are arranged exactly one behind the other, preferably at the same distance from each other. 5. Breaker according to any one of claims 1 to 3, characterized in that the columns (3f) with their base points are preferably located centrally between the tongues (3d, 3e) on the curve. 6. Breaking switch according to any one of claims 1 to 3, characterized in that the columns (3i) are circularly distributed with their base points on the side surfaces (3a, 3b) between the tongues (3d, 3e) in the flow channel (8). 7. A circuit breaker according to any one of claims 1 to 3, characterized in that the columns (3f) of one side surface (3a) of the housing (1) are disposed opposite to the column space between the columns of the other side surface (3b). 8. Breaking switch according to any one of claims 1 to 4, characterized in that the columns (3f) of one of the side surfaces (3a, 3b) are of the same size and are flush with the respective tongues (3d, 3e) and their face surfaces (3f '). 9. meg5 according to any one of claims 1 to 5 EN 207 903 Β breaking switch, characterized in that the tongues (3d, 3e) and the columns (3f), together with the housing halves (la, lb), are made in one piece. 10. Breaker according to any one of claims 1 to 3, characterized in that the number of columns in each of the side surfaces (3a, 3b) of the pre-chamber space (3c) is preferably between five and nine. 11. Breaker according to any one of claims 1 to 3, characterized in that 5-15% of the total surface area of the flow passage (8) between the tongues (3d, 3e) and the wall portions (le) is also covered by the base surfaces of the columns (3f). 12. Breaking switch according to one of Claims 1 to 3, characterized in that the columns (3f) are round or square and have a diameter or side length of 2 mm. 13. Breaking switch according to any one of claims 1 to 4, characterized in that the height of the posts (3f) on each side of the contact opening plane is 6 mm. 14. Breaking switch according to any one of claims 1 to 5, characterized in that the columns (3f) are tapered to about 10 ° tapering towards the opening plane of the contact. 15. A circuit breaker according to any one of the preceding claims, characterized in that the columns The width of the gap between the front faces (3f ') of the housing 10 (3f) and the upper sides of the tongues (3d, 3e) of the two housing halves (la, lb) of the housing (1) is 3 mm. 16. A circuit breaker according to any one of the preceding claims, characterized in that the tongues (3d, 3e) are designed for insertion and holding of the stationary contact element (5a) and the horn (5a ') on the one hand and of the lower arc guide rail (7) on the other hand.