Power circuit breaker

Abstract

The invention relates to a power circuit breaker that is suitable for switching electrical voltages. The power circuit breaker according to the invention comprises two main electrodes, to each of which a respective pole of the voltage to be switched can be connected. During the switching process, at least one of said main electrodes follows a switching path. The power circuit breaker is characterized in that secondary electrodes are additionally provided, which protrude into the vicinity of the switching path and are designed and arranged in such a way that arcs can be produced (a) between the main electrodes and the secondary electrodes and (b) between the individual secondary electrodes during the switching process. The power circuit breaker according to the invention can be advantageously used in vehicles and in ultra-high-voltage AC and HVDC (high-voltage direct current) transmission systems and causes arcs to be extinguished as early as possible during the switching process.

Claims

1. A power circuit breaker for switching electrical voltages, having a first electrode, which can be connected to a first pole (A) of the high voltage to be switched, and a second electrode, which can be connected to a second pole (B) of the voltage to be switched, with switching means being provided, which are suitable to move at least one of the electrodes along a switching path depending on a switching state and thereby to move the electrodes toward each other or away from each other, wherein at least one secondary electrode is present, which is situated in a vicinity of the switching path, and wherein more than one of the secondary electrodes is present and these secondary electrodes have a greater distance from one another in a region of the switching path than on a side facing away from the switching path.

2. The power circuit breaker according to claim 1, further characterized in that a distance between the switching path and the secondary electrode is one of less than 10 mm, and between 0.5 and 1 mm.

3. The power circuit breaker according to claim 1, further characterized in that it is designed as a vacuum power circuit breaker.

4. The power circuit breaker according to claim 1, further characterized in that the at least one secondary electrodes is designed in a shape of a ring or flat area and has an opening through which the switching path passes.

5. The power circuit breaker according to claim 1, further characterized in that one of the electrodes is arranged inside the power circuit breaker in nearly fixed position and the other one of the electrodes can be moved along the switching path.

6. The power circuit breaker according to claim 1, further characterized in that at least individual ones of the secondary electrodes are connected electrically to one another by means of a grid that contains at least one varistor and/or at least one resistor.

7. A power circuit breaker for switching electrical voltages having a first electrode which can be connected to a first pole (A) of the high voltage to be switched, and a second electrode, which can be connected to a second pole (B) of the voltage to be switched, with switching means being provided, which are suitable to move at least one of the electrodes along a switching path depending on a switching state and thereby to move the electrodes toward each other or away from each other, wherein at least one secondary electrode is present, which is situated in a vicinity of the switching path, and wherein the at least one secondary electrode has a contour such that it is thinner in a region of the switching path than on a side facing away from the switching path.

8. A power circuit breaker for switching electrical voltages, having a first electrode, which can be connected to a first pole (A) of the high voltage to be switched, and a second electrode, which can be connected to a second pole (B) of the voltage to be switched, with switching means being provided, which are suitable to move at least one of the electrodes along a switching path depending on a switching state and thereby to move the electrodes toward each other or away from each other, wherein at least one secondary electrode is present, which is situated in a vicinity of the switching path, and wherein more than one of the secondary electrodes is present and these secondary electrodes have a greater distance from one another in a region of the switching path than their minimum distance from the switching path.

9. A power circuit breaker for switching electrical voltages, having a first electrode, which can be connected to a first pole (A) of the high voltage to be switched, and a second electrode, which can be connected to a second pole (B) of the voltage to be switched, with switching means being provided, which are suitable to move at least one of the electrodes along a switching path depending on a switching state and thereby to move the electrodes toward each other or away from each other, wherein at least one secondary electrode is present, which is situated in a vicinity of the switching path, and wherein the at least one secondary electrode is designed in a shape of a ring or flat area and has an opening through which the switching path passes, and has a contour such that it is thinner in a region of the switching path than on a side facing away from the switching path.

10. A power circuit breaker for switching electrical voltages, having a first electrode, which can be connected to a first pole (A) of the high voltage to be switched, and a second electrode, which can be connected to a second pole (B) of the voltage to be switched, with switching means being provided, which are suitable to move at least one of the electrodes along a switching path depending on a switching state and thereby to move the electrodes toward each other or away from each other, wherein at least one secondary electrode is present, which is situated in a vicinity of the switching path, and wherein more than one of the secondary electrodes is present and these secondary electrodes have a greater distance from one another in a region of the switching path than on a side facing away from the switching path, and have a greater distance from one another in a region of the switching path than their minimum distance from the switching path.

11. The power circuit breaker according to claim 10, further characterized in that the at least one secondary electrode is designed in a shape of a ring or flat area and has an opening through which the switching path passes, and has a contour such that it is thinner in a region of the switching path than on a side facing away from the switching path.

12. A power circuit breaker for switching electrical voltages, said power circuit breaker comprising a first electrode which is connected to a first pole of a high voltage that is to be switched, a second electrode which is connected to a second pole of a voltage to be switched, a switching device for moving at least one of the electrodes along a switching path that extends between the electrodes and depending on a switching state, said switching device for moving the electrodes toward each other or away from each other, and at least one secondary electrode which is situated in the vicinity of the switching path, and wherein more than one of the secondary electrodes is present and these secondary electrodes have a greater distance from one another in a region of the switching path than on a side facing away from the switching path.

13. The power circuit breaker according to claim 12, further characterized in that a distance between the switching path and the secondary electrode is one of less than 10 mm, and between 0.5 and 1 mm.

14. The power circuit breaker according to claim 12, further characterized in that it is designed as a vacuum power circuit breaker.

15. The power circuit breaker according to claim 12, further characterized in that the at least one secondary electrodes has a contour such that it is thinner in a region of the switching path than on a side facing away from the switching path.

16. The power circuit breaker according to claim 12, further characterized in that more than one of the secondary electrodes is present and these secondary electrode have a greater distance from one another in a region of the switching path than their minimum distance from the switching path.

17. The power circuit breaker according to claim 12, further characterized in that one of the electrodes is arranged inside the power circuit breaker in nearly fixed position and the other one of the electrodes is moveable along the switching path.

Description

DESCRIPTION OF THE DRAWINGS

(1) In the following, further details and advantages of the present invention are described on the basis of preferred exemplary embodiments. Shown are:

(2) FIG. 1 a symbolic illustration of a power circuit breaker

(3) FIG. 2 a cross-sectional illustration of the power circuit breaker

(4) FIG. 3a schematically illustrates a first position of the main electrodes and the secondary electrodes

(5) FIG. 3b schematically illustrates a second position of the main electrodes and the secondary electrodes

(6) FIG. 3c schematically illustrates a third position of the main electrodes and the secondary electrodes

(7) FIG. 3d schematically illustrates a fourth position of the main electrodes and the secondary electrodes

(8) FIG. 3e schematically illustrates a fifth position of the main electrodes and the secondary electrodes

(9) FIG. 3f schematically illustrates a sixth position of the main electrodes and the secondary electrodes

(10) FIG. 3g schematically illustrates a seventh position of the main electrodes and the secondary electrodes

(11) FIG. 3h schematically illustrates an eighth position of the main electrodes and the secondary electrodes

(12) FIG. 4 an enlarged illustration of the secondary electrode 30a from FIG. 2

(13) FIG. 5 secondary electrodes having a triangular contour

(14) FIG. 6 another embodiment of the power circuit breaker with circuitry.

DETAILED DESCRIPTION

(15) Identical and similar means are provided in the figures with identical reference numbers. A repeated description occurs only insofar as it seems necessary for understanding the invention or exemplary embodiments. Although the exemplary embodiments describe the switching of high voltage, it is pointed out once again that the power circuit breaker according to the invention is suitable for the switching of electrical voltages of any value.

(16) FIG. 1 shows a symbolic illustration of a preferred power circuit breaker 10, which is suitable for switching direct voltages of up to 100 kV and more. It is preferably designed as a vacuum circuit breaker in which a pressure of approximately 10.sup.6 mbar usually prevails. The preferred embodiment is essentially circularly symmetrical or cylindrically symmetrical in design. This means that the housing of the power circuit breaker 10 comprises an essentially cylindrically shaped insulator 12 as well as a top end plate 14 and a bottom end plate 16, each of which is nearly disc-shaped. The power circuit breaker 10 further contains a top main electrode 18 having a top shaft 20 and a bottom main electrode 22 having a bottom shaft 24. A high voltage can be switched on or interrupted via the main electrodes 18, 22. The two shafts 20, 24 are electrically conductive and each of them is in both mechanical and electrically conductive connection with its respective main electrode 18 and 22.

(17) The top shaft 20 is fastened to the top end plate 14, so that the top main electrode 18 is nearly fixed in position inside of the power circuit breaker 10. A top junction port A, to which the first pole of the high voltage to be switched can be applied, is connected to the top main electrode 18 via the electrically conductive top shaft 20. The bottom shaft 24 can be moved perpendicularly back and forth along the arrow 26 through an opening, which is not depicted here, inside of the bottom end plate 16. In this way, it is thus possible to move the bottom main electrode 22, that is, up and down, along a switching path, which is indicated here by the dashed lines sl and sr. The second pole of the high voltage to be switched can be applied via a bottom junction port B. This port B is in electrically conductive connection with a sliding contact 28, which, in turn, makes possible a contact between the electrically conductive bottom shaft 24 and thus also to the bottom main electrode 22.

(18) The power circuit breaker 10 further comprises five secondary electrodes 30a, . . . , 30e, each of which is designed nearly disc-shaped and each of which is retained by the respective retainer 31a, . . . , 31e. The retainers 31 are preferably formed as metal plates, which are fastened to the insulator 12 or to one of the end plates 14, 16 (see also FIG. 2) and thus retain the secondary electrodes in a stable position. Alternatively, it is also possible for the retainers 31 to be designed as crosspieces or the like.

(19) The secondary electrodes 30 each have an opening 32a, . . . 32e in the center portion, said openings being designed and arranged in such a way that the movable bottom main electrode 22 can be moved through it there. Preferably, the openings 32 are symmetrical to the positions of the bottom main electrode 22 along the perpendicular switching path thereof. When these positions are in the center of the openings 32, there is a minimum distance d between the exterior of the main electrode 22 and the interior of such an opening 32, as shown in FIG. 1. This distance d between the switching path sr and the secondary electrode 30 is less than 10 mm, with values of between 0.5 and 1 mm having especially proven useful. It is also possible that the topmost secondary electrode 30a is arranged in such a way that the top main electrode 18 is situated in the region of the opening 32a. Such designs are illustrated in FIGS. 3a-3h and 4, for example.

(20) FIG. 2 shows a cross-sectional illustration of the preferred power circuit breaker 10, whichas already mentioned aboveis designed in an essentially circularly symmetrical or cylindrically symmetrical shape. For reasons of clarity, only three of the secondary electrodes 30a, . . . , 30e were illustrated. FIG. 2 shows, in addition, further possible modifications. Thus, in this case, the insulator 12 has first sections 12a, which are electrically conductive, as well as second sections 12b, which are electrically insulating. The first sections 12a are preferably made of metal. The second sections 12b are made of conventional material, such as ceramic or the like. Moreover, the top main electrode 18 is designed to be quite large in FIG. 2, so that the lateral dimension thereof is greater than that of the bottom main electrode 22.

(21) Furthermore, the power circuit breaker 10 has a shielding metal plate 33 in this case. Together with the retainers 31a and 31e, which are preferably designed likewise as metal plates and thus also function as shielding metal plates, the dielectric face of the insulators 12 is thus shielded against flows of metal particles that ensue during creation and presence of an arc.

(22) Illustrated in FIG. 2 are also an electromagnet 34, a permanent magnet 36, and a spring 38, which, when there is appropriate switching and actuation by suitable means (not shown here), make possible a vertical actuation of the bottom shaft 24and thus also of the bottom main electrode 22and hence are able to bring about a desired switching process by interconnecting or separating the two main electrodes 18, 22.

(23) The arrangement of the magnets 34, 36 as well as the springs 38 shown in FIG. 2 is merely symbolic and indicates a power circuit breaker 10, which is realized as a gas-filled circuit breaker. For a vacuum circuit breaker, by contrast, the electromagnet 34 and the spring 38 are preferably mounted below the bottom end plate 16 and outside of the vacuum chamber.

(24) What is unique in the present invention are the secondary electrodes 30 shown in the exemplary embodiments. These enable the arcs that usually form during the switching process to be extinguished in a simple way. This will be explained in detail by means of the following FIGS. 3a-3h.

(25) FIGS. 3a to 3h schematically represent a sequence in the switching process regarding the main electrodes 18, 22 and the secondary electrodes 30a . . . 30e. During a switching process, in which the two main electrodes 18, 22 are separated from each other, various respective positions of the bottom main electrode 22 are shown in FIGS. 3a to 3h, one after the other. In addition, the secondary electrodes 30a, . . . , 30e are depicted as well as various arcs that can form during such a switching process. In the illustrated exemplary embodiment, the topmost secondary electrode 30a is situated essentially at the same height as the first main electrode 18, which is nearly fixed in position. It is assumed (not depicted here) that the bottom main electrode 22 was initially actuated in such a way that the two main electrodes 18, 22 came into contact and thereby a direct voltage of approximately 50 kV or more was switched. When the two main electrodes 18, 22 are separated, various arcs arise, which will be addressed in detail below. They are formed inside of a vacuum power circuit breaker in that metal particles are released from the material of the electrodes. Such arcs are unstable, however, and the occurrence or extinguishing thereof obeys statistical laws.

(26) FIG. 3a shows the two main electrodes 18, 22 shortly after the separation thereof; here, the bottom main electrode 22 has assumed a position in which it is situated at about the same height as the secondary electrode 30b. Initially, in the separation process, an arc 110 is formed between the two main electrodes 18, 22. An arc 112 (between the top main electrode 18 and the secondary electrode 30a), an arc 114 (between the secondary electrodes 30a, 30b), and an arc 116 (between the secondary electrode 30b and the bottom secondary electrode 22) also arise nearly simultaneously.

(27) FIG. 3b shows a situation in which the bottom main electrode 22 has moved further downward during the switching process. As a result, the distance between the main electrodes 18, 22 has become larger and the arc 110 that was originally present is extinguished. By contrast, the arcs 112, 114, and 116 are still present. For reasons of clarity, arcs that have already been described once are not provided separately with reference numbers again in the subsequent figures, as in the case here for the arcs 112, 114, and 116. Only in FIG. 3h are all arcs present there provided once again with reference numbers for completeness.

(28) In FIG. 3c, the arc 116 is extinguished. Instead of it, an arc 130 (between the secondary electrodes 30b, 30c) and an arc 132 (between the secondary electrode 30c and the bottom electrode 22) have newly arisen. In FIG. 3d, the bottom main electrode 22 is situated below the secondary electrode 30c. However, the same arcs are present as in FIG. 3c.

(29) In FIGS. 3e and 3f, the bottom main electrode 22 is situated at the same height as the secondary electrode 30d or just below it. As a result, the arc 132 is extinguished. However, an arc 150 (between the secondary electrodes 30c and 30d) and an arc 152 (between the secondary electrode 30d and the bottom main electrode 22) are formed.

(30) In FIGS. 3g and 3h, the bottom main electrode 22 is situated at the height of the secondary electrode 30e or just below it. As a result, the arc 152 is extinguished. However, an arc 170 (between the secondary electrodes 30d and 30e) and an arc 172 (between the secondary electrode 30e and the bottom main electrode 22) are formed.

(31) The arcs 112, 114, 130, 150, 170, and 172 that are present during the switching process as well as in the position according to FIG. 3h, in particular, have formed owing to the special design and positioning of the secondary electrodes 30 with respect to one another as well as with respect to the position of the top main electrode 18 and the switching path of the bottom main electrode 22. These arcs are connected virtually in series. This means that, when one of these arcs is extinguished owing to statistical laws, the entire spark gap is interrupted. As a result, arcs in the high-voltage power circuit breaker according to the invention are extinguished substantially earlier than in hitherto known power circuit breakers.

(32) FIG. 4 is a cutout of FIG. 2 and shows, in enlargement, particularly the first secondary electrode 30a. It is clearly shown here that this secondary electrode 30a has a contour for which, toward the switching pathindicated here by its left boundary sla smaller radius r is realized than on the opposite-lying side, where a larger radius R exists. This means, therefore, that it has proven useful in the preferred embodiments for at least individual secondary electrodes 30 to be designed to be thinner or more pointed in the direction of the switching path sl, sr than on the other side. In this way, on the one hand, the secondary electrodes 30 have a quite small distance of a few millimeters in the outer region, that is, on the side facing away from the switching path sl, sr, as a result of which the arcs 114, 130, 150, and 170 (see FIGS. 3a-3h) can form; on the other hand, the secondary electrodes 30 have a markedly greater distance from one another in the region of the switching path sl, sr than toward the switching path sl, sr itself, as a result of which the arcs 112, 116, 132, 152, and 172 (see FIGS. 3a-3h) can form.

(33) FIG. 5 shows two secondary electrodes 30a and 30b with an alternative contour, whichin perspective viewruns in each case from the switching path sl, sr outward in a triangular shape. In this way, it is possible for the distance between the secondary electrodes 30 to be greater in the region of the switching path sl or sr than on the outer side of the secondary electrode 30.

(34) FIG. 6 shows, in a symbolic manner, another exemplary embodiment of the power circuit breaker 10 according to the invention. What is unique in it is the electronic circuit 50, which is composed of a plurality of ohmic resistors 52 as well as a plurality of voltage-dependent resistors 54, which will be referred to as varistors below. The resistors 52 and the varistors 54 are each connected in series. It has proven useful for a high-voltage power circuit breaker for each of the resistors 52 to have a value greater than 100 k, with a range between 100 k and 1 M being especially advantageous. In the preferred exemplary embodiment, the varistors are designed in such a way that they have a limit voltage (threshold voltage) of approximately 1 kV.

(35) The preferred embodiment of the power circuit breaker 10 is designed in such a way that voltages in the range of approximately 200 kV can be switched. When five secondary electrodes 30a, . . . , 30e are present in this case (as also depicted), four gaps result between these secondary electrodes 30a, . . . , 30e. In order to make possible an optimal spark gap with the sparks 114, 130, 150, 170 (see FIGS. 3a-3h), a sufficient number of the resistors 54 are arranged between each of the two secondary electrodes (30a-30b, 30b-30c, 30c-30d, 30d-30e) such that, in each case, a limit voltage of 50 kV results. If, then, as assumed above, each of the varistors 54 has a limit voltage of 1 kV, then 50 varistors 54 are arranged between each of the secondary electrode pairs 30a-30b, 30b-30c, 30c-30d, 30d-30e, so as to make possible the desired limit voltages. A good voltage distribution between the secondary electrodes 30 is ensured by the resistors 52.

(36) In this embodiment, the electronic circuit 50 is connected as follows. The retainers 31 are each made of plate metal in this case, so that each of these retainer metal plates also functions as a shielding metal plate. The first metal retaining plate 31a is connected via a first electrical conductor 56 to the top main electrode 18 via the top shaft 20. Connected between the first metal retaining plate 31a and the second metal retaining plate 31b are a series of varistors 54, to which a series of resistors 52 are connected in parallel. In FIG. 6, six resistors 52 as well as six varistors 54 are shown between the first metal retaining plate 31a and the second metal retaining plate 31b. Six resistors 52 and six varistors 54 are also shown between each of the other adjacent metal retaining plates 31b-31c, 31c-31d, and 31d-31e. It is noted that this number is given only by way of example and can differ between adjacent metal retaining plates 31. This also means, furthermore, that the number of resistors 52 can be different from the number of varistors 54. Moreover, the last metal retaining plate 31e is electrically connected via a second electrical conductor 58 to the bottom main electrode 22 via the bottom shaft 24.

(37) The exemplary embodiments presented in the figures and hitherto described are preferred embodiments of the present invention, for which various further developments and modifications are possible.

LIST OF REFERENCE NUMBERS

(38) 10 power circuit breaker 12 insulator 12a first section of 12 (electrically conductive) 12b second section of 12 (electrically insulating) 14 top end plate 16 bottom end plate 18 top main electrode 20 top shaft 22 bottom main electrode 24 bottom shaft 26 arrow 28 sliding contact 30a, . . . , 30e secondary electrodes 31a, . . . , 31e retainers of secondary electrodes 32a, . . . , 32e openings in the secondary electrodes 33 shielding metal plate 34 electromagnet 36 permanent magnet 38 spring 50 electronic circuit 52 resistors 54 varistors 56 first electrical conductor 58 second electrical conductor 110, 112, 114, 116 arc in FIG. 3a, 3b (first time) 130, 132 arc in FIG. 3c, 3d (first time) 150, 152 arc in FIG. 3e, 3f (first time) 170, 172 arc in FIG. 3g, 3h (first time) A, B junction ports for high voltage d distance between boundary of the switching path and edge of 32 r radius of the secondary electrode in the region of the switching path R radius of the secondary electrode opposite the switching path sl, sr left and right boundary, respectively, of the switching path