DE1182323B - Electric switch with a chimney used to extinguish the arc - Google Patents

Description

Electric switch with a chimney used to extinguish arcing The requirement to increase the breaking capacity of the electrical switch more and more, leads to increasing stress on these switching devices. This stress, the work done in the device and the work that occurs when switching The power peak is decisive for the dimensioning of the switch. If the switch size is to remain the same or even smaller, so must the switching work and this power peak are reduced as the breaking capacity increases will. This requirement means that the short-circuit current through the switch as possible must be severely limited. It is known to limit the short-circuit current an impedance, in particular an ohmic resistance, to be used when switching takes effect.

One approach taken so far is that the impedance is immediately is switched in series with the interruption path when switching off. Such switches have not worked satisfactorily so far. If the limiting resistance is so great, that it causes a real current limitation, then the current commutation is on this Resistance difficult and stresses the switch similar to a full shutdown. This does not result in any improvement. If, in order to facilitate commutation, If the resistance is kept sufficiently small, this resistance then limits the short-circuit current too little. This is also of no advantage. Another disadvantage of this well-known, With limiting impedance operating switches is that they have a larger Have more work on contact parts and additional heat loss. The additional Contact parts also require a separate drive mechanism.

Another known way is that the breakpoint an impedance is assigned that only occurs after an arc has occurred on the Interruption point to limit the current becomes effective. It becomes this Purpose in the vicinity of the movement path of the movable contact part an intermediate electrode used, which is connected to the stationary contact part via the impedance. on The arc jumps over this intermediate electrode from the stationary contact part. Switches of this type have hitherto only been used for switching high voltage. You have a switching chamber assigned to the interruption point. It is known, to use a cylindrical switching chamber with its axis in the direction of the Path of movement of the movable contact part lies. Between the stationary contact part and the intermediate electrode is the wall of the switching chamber from the building material of the as Impedance serving ohmic resistance formed itself. The intermediate electrode covers this part of the switching chamber by being designed as a plate and has a hole for the movable contact part to pass through. The rest of the Switching chamber consists of insulating material. Such a construction of the switching chamber is because of the large space required for switches used in low voltage systems cannot be used.

For electrical high-speed switches that have the task of being undisturbed Operation of a consumer to short-circuit a protective resistor for the consumer and to let the protective resistor take effect in the event of a fault, it is known the interruption point formed by a stationary and a movable contact part to assign a chimney serving to extinguish arcs, the metallic one, as a running surface has chamber walls serving for the arc roots. This fireplace that comes with a additional magnetic means to accelerate the arc roots is provided; is divided by a central chamber wall made of insulating material consists. The one outer chamber wall. stands with the stationary contact part and the other outer chamber wall with the movable contact part in conductive connection. The middle chamber wall also serves as a switch for two electrodes to which the ends of an auxiliary blowing coil are connected. There is also electrical switches known as a quenching device for the arc created at the point of interruption one under the action of a blow coil standing fireplace made of insulating material to be provided in which there are also several insulating fireproof housings, the auxiliary blowing coils with high intrinsic resistance and with external electrode connections contain. Due to the auxiliary blower flows, it is already under the effect The arc standing at the main blower has a high speed. On electrical Switches that are used to achieve a strong, locally limited blown field have strong current constriction on the contact parts, one has additionally as Arc extinguishing equipment installed in a chimney consisting of a single room, which is penetrated by an insulated magnetic core of a blowing device. In the chimney, horizontally arranged spark horns are effective with the contact parts stay in contact. After all, you already have electrical switches with a fireplace provided for the extinguishing device, the walls of which are made of magnetic material.

The invention relates to an electrical switch with a stationary one and a movable contact part as well as one assigned to the interruption point, for the arc extinguishing chimney, which is in metallic, as a running surface for the Chamber walls serving arc root points is divided, with the one outer chamber wall with the stationary contact part and the other outer chamber wall with the movable one Contact part connected and an additional magnetic means for acceleration the run of the arc roots is provided. According to the invention, this also serves metallic middle chamber wall serving as a running surface for the arc fuselage points as an intermediate electrode for connecting an ohmic resistor with a large temperature coefficient trained impedance connected to the stationary contact part, wherein the metallic chamber walls are preferably made of magnetic material. The switch according to the invention is characterized by a high switching capacity very little switching work and small power peaks in the switching chamber the end. This reduced thermal and dynamic stress leads to a special small space required for the switch. The invention is therefore of great advantage to apply to switches for low-voltage systems, which z. B. as an automatic switch are trained. The size of such switches can be kept particularly small. Another advantage ; is that except for the switch according to the invention the two contact parts, which are required anyway, and the intermediate electrode further contact parts that would represent additional heat sources in nominal operation, are necessary. ; In addition to the drive mechanism for the only moving contact part is an additional drive mechanism for further contact parts or electrodes not mandatory. This reduced effort also contributes to keeping them small of the switch according to the invention.

An exemplary embodiment of the invention is shown in the drawing. The F i g. 1 to 4 show the individual parts essential for the invention of the switch according to the invention in a schematic representation. The F i g. 5 and 6 show an embodiment suitable for practice for the switch according to the invention. First of all, let the F i g. Considered 1: The electrical switch according to the invention has a single break point. The interruption point consists of the single stationary contact part 1 and the single movable contact part z. Both contact parts 1 and 2 are each provided with a power supply line 3, 4 . The stationary contact part 1 is horn-shaped and sits on an insulating body 5. The movable contact part 2 is in the form of a switching lever and can be rotated about the axis 6. A switching chamber 7 is assigned to the interruption point. This switching chamber is formed by a chimney which extends approximately perpendicular to the movement path of the movable contact part 2 and which has two chimney spaces A and B. The plane of the three chamber walls 8, 9 and 10 is transverse to the movement path of the movable contact part. They are metallic. They can be made of copper. However, they are advantageously made of magnetic material. The chamber walls 8, 9 and 10 serve as running surfaces for the base points of the arcs that arise in the switching chamber. The other walls of the switching chamber are made of insulating material in the usual way.

The one outer chamber wall 8 is in direct conductive connection with the stationary contact part 1. The end of the horn-shaped contact part 1 is expediently brought up directly to the chamber wall 8. The other outer chamber wall 10 is in conductive connection with the movable contact part 2. According to the invention, the middle chamber wall 9 is designed as an intermediate electrode. It is led empty in the vicinity of the path of movement of the movable contact part 2 without the movable contact part 2 being touched by it. It is expediently done in such a way that the middle chamber wall is provided with a recess 11. through which the movable contact part moves when switching. The intermediate electrode 9 is connected to the stationary contact part 1 via an impedance 12. An ohmic resistor (limiting resistor) with a large temperature coefficient is used as the impedance. The purest iron, which can change its resistance between 20 and 100 ° C by a factor of around 15, is particularly suitable for this. Nickel and tungsten would also be suitable as resistance materials.

The shutdown process on the one shown in FIG. 1 switch shown runs as follows: The F i g. 1 shows the switch in the switched-off state, in which the movable contact part 2 is at its greatest distance from the stationary contact part 1. If the switch is switched on, the movable contact part 2 assumes the position in which it touches the stationary contact part l. As soon as the interruption point opens, an arc is formed between the stationary contact part i and the movable contact part z. If the movable contact part moves past the intermediate electrode 9 or if the arc expands significantly beforehand, the arc jumps over to the intermediate electrode 9. A partial arc now forms between the stationary contact part 1 and the intermediate electrode 9 and a partial arc between the intermediate electrode 9 and the movable contact part 2. The base of the partial arc on the contact part 1 first moves on this in the direction of the outer chamber wall 8 and jumps up this chamber wall over. There is now a partial arc in the chamber space A between the chamber walls 8 and 9. When the movable contact part 2 moves further, the base of the partial arc located on it jumps over to the outer chamber wall 10, so that a partial arc between the outer chamber wall 10 and the middle chamber wall 9 is present. The base points of both partial arcs run along the metallic chamber walls 8, 9, 10 , specifically in a direction facing away from the point of interruption. In this case, the partial arc between the chamber walls 8 and 9 extinguishes very early. As soon as this has happened, a current flows only through the impedance 12. This impedance reduces the current flowing through the interruption point of the switch. The partial arc located in chamber space B can no longer be maintained for long and goes out. The shutdown process is now complete.

On the switch according to the invention, the intermediate electrode 9 acts as a collecting electrode. The limiting resistor can be dimensioned in such a way that the arc between the intermediate electrode 9 and the stationary contact part 1 only requires a small operating voltage for current commutation. This happens because the resistance has a small value before the current commutation. As soon as the current has been commutated to it, the resistance increases sharply as a result of the heating by the current. At the same time, the remaining switching path is dimensioned in such a way that the partial arc located between the intermediate electrode 9 and the outer chamber wall 10 also has a small amount of fuel build-up. It is particularly favorable if the operating voltage of the partial arc in chamber space B is lower than that of the partial arc in chamber space A. The last remaining partial arc in chamber space B burns at most until the next current zero crossing.

On the switch according to the invention, the switching chamber is provided with an additional magnetic means which accelerates the run of the arc base points on the metallic chamber walls 8, 9, 10. In FIG. 2, the switch is designed so that the additional magnetic means is formed by a blowing coil 13 which is connected in series with the interruption path of the switch. A magnetic blown coil in this circuit is known per se. In FIG. 3, such a blowing coil 14 is also used for accelerated extinguishing of the partial arcs. This blow-out coil is formed by the ohmic resistance itself, which acts as an impedance.

It is advisable to use the middle chamber wall, which serves as an intermediate electrode specially trained. This training is from FIG. 4 can be seen. The middle Chamber wall is formed by two mutually insulated plates 9 ', 9 ". Both Plates are only connected to one another on the side facing the interruption point conductively connected. It is also advantageous for the arc roots to run quickly, to arrange the line connections for the metallic chamber walls at preferred locations. As the F i g. 4 shows that one outer chamber wall 8 is connected to the stationary contact part 1 and the other outer chamber wall 10 with the movable contact part 2 on the Interruption point facing side in conductive connection. Against it is Ohmic resistance 12, effective as impedance, with one end to the outer chamber wall 8, which is in communication with the stationary contact part 1, and with the other End to this outer chamber wall 8 opposite plate 9 'of the middle Chamber wall connected on the side facing away from the point of interruption. at this formation of the switching chamber and the line connections arise during the flow of the currents through the chamber walls and the partial arc magnetic fields, which endeavor to turn away the partial arc in one of the interruption point Direction to drift away. The magnetic fields are in individual places in the switching chamber represented in such a way that the magnetic lines of force, the, by the viewer as seen from the drawing, enter the drawing plane with a plus sign, and the magnetic lines of force emerging from the plane of the drawing to the viewer flow are marked with a dot symbol.

The in the F i g. 2 to 4, which contribute to To accelerate the run of the arc roots on the chamber walls can be done individually or can be used in combination.

The F i g. FIGS. 5 and 6 show an embodiment of an electrical switch suitable for manufacture which has the type shown in FIGS. 1 and 4 used construction principle. The switch, which is designed as a line circuit breaker, has a particularly flat shape. Its housing is formed by a box-shaped housing part 15 and a cover-shaped housing part 16. The box-shaped housing part 15 receives the individual parts of the switch and holds them, while the cover-shaped housing part 16 also secures the position of the individual parts. For this purpose, both housing parts are provided with projections, lugs or the like. Both housing parts, which are made of insulating material, are at the points 17 by clamping means, for. B. screws held together.

Inside the housing, the two contact parts 1 and 2 and the Schaltkammei.7 are housed. The stationary contact part 1 is in conductive connection with the terminal 19 via the rail 18 and the bimetallic release 30. The movable contact part 2, which is designed as a double-armed lever and is rotatable about the axis 6, is under the action of a counterclockwise rotating spring, not shown. At its free end it is coupled to the armature 20 of the release magnet 21. The F i g. 5 shows the movable contact part in the switched-on position, in which it is pressed against the stationary contact part 1 by the spring (not shown). The movable contact part 2 is in conductive connection with the terminal 23 via the release magnet 21 and the rail 22. Both connection terminals 19, 23 are housed in external pockets of the housing. 31 is the mechanism that interacts with the armature 20 of the magnetic release 21 and the bimetallic release 30. The switching chamber 7 has the two outer metallic chamber walls 8, 10 and the intermediate double-walled metal, serving as the intermediate electrode chamber wall 9 ', 9 ". The remaining walls of the switching chamber are formed by the two housing parts. 24 is an insulating body, which largely between the two Plates 9 ', 9 "of the inner chamber wall is inserted and bent at an angle outside of the two plates. The chamber space A is provided with a large number of extinguishing plates 25 to increase the extinguishing voltage of the partial arc occurring in it. The quenching plates are made of magnetic building material. As the F i g. 5 shows, they are transverse to the path of movement of the movable contact part 2 and are arranged at a distance from one another. Their shape is shown in FIG. 6 can be seen. Each quenching plate has a slot 26 which tapers in its width in the direction facing away from the contact parts. In the area of the contact parts 1, 2, the slots 26 of the quenching plates are lined with insulating plates 27 on both sides (FIG. 6). The quenching plates 25, as shown in FIG. 5 shows, alternately offset from one another so that the edges of the slots form steps. By such quenching plates, great forces can be exerted on the partial arc created in chamber space A, which elongate it and immediately cause it to be extinguished. Since the legs of the quenching plates extend beyond the point of interruption, the partial arc is detected as soon as it arises due to the action of the quenching plates. The chamber space B, on the other hand, does not have to be provided with quenching plates, since the increase in the quenching voltage of the arc is undesirable in this space. The ohmic resistor 12 serving as an impedance is accommodated in a special space 28 of the housing. It is carried by a core 29 and its ends are connected to the outer chamber wall 8 and the plate 9 'of the central chamber wall.

If the switch according to the invention switches off by the triggering magnet 21 responding, the armature 20 of the triggering magnet jerks the movable contact part 2 into the switched-off position. The arc which initially arises between the stationary contact part 1 and the movable contact part 2 is divided into two partial arcs, one of which is taken up by the chimney spaces A and B each. The base points run along the metal chamber walls. First the partial arc in chimney A goes out, then the partial arc in chimney B goes out, its extinction being accelerated by the fact that the current flowing through it is greatly weakened by the ohmic resistance, which increases with heating. The F i g. 5 and 6 show the small amount of space required for the contact parts and the switching chamber in a switch according to the invention.

Claims (6)

Claims: 1. Electrical switch with a stationary and a movable contact part and with a chimney assigned to the interruption point, serving to extinguish the arc, which has metallic chamber walls serving as a running surface for the arc base points and is divided by a central chamber wall, the one outer chamber wall with the stationary contact part and the other outer chamber wall connected to the movable contact part and an additional magnetic means is provided to accelerate the run of the arc base points, characterized in that the likewise metallic, as a running surface for the arc base points serving middle chamber wall (9) as an intermediate electrode for Connection of an impedance (12) designed as an ohmic resistance with a high temperature coefficient and connected to the stationary contact part (1 ) is used, the metallic chamber walls preferably being made of magnetic material. 2. Switch according to claim 1, characterized in that the central metal chamber wall is formed by two mutually insulated plates (9 ', 9 ") which are conductively connected to one another only on the side facing the interruption point. 3. Switch according to claim 1 and 2, characterized in that the stationary contact part (1) to the one outer chamber wall (8) and the movable contact part (2) to the other outer chamber wall (10) on the side facing the interruption point, however the ohmic resistance (12) acting as impedance with one end to the outer chamber wall (8) and with the other end to the plate (9 ') of the middle double-walled chamber wall opposite the last-mentioned outer chamber wall (8) on the side facing away from the interruption point connected. 4. Switch according to claim 1, characterized in that the switching chamber (7) in the area between the with the stationary contact part (1) in communication chamber wall (8) and the central chamber wall (9) in a known manner with a plurality is provided transversely to the movement path of the movable contact part (2) standing, spaced apart magnetic sheets (25) (quenching sheets), which drive the arc away from the contact parts (1, 2) through their shape and arrangement. 5. Switch according to claim 1; characterized in that the switching chamber (7) is in a manner known per se under the action of a magnetic blowing coil (13) which is connected in series with the interruption path of the switch. 6. Switch according to claim 1, characterized in that the ohmic resistance effective as the impedance is also designed as a blower coil (14) for the switching chamber. Considered publications: German Patent Nos. 395 098, 408129, 540 927, 700 728; German Auslegeschriften No. 1015 893, 1052499.