EP0022535A1 - High voltage circuit breaker - Google Patents

Abstract

1. A high voltage power switch with at least one main breaker gap (10) and parallel thereto a series connection of at least one switch-on resistance (30) and at least one subsidiary breaker gap (20) for switching the switch-on resistance (30), with a common drive (6) for the main and subsidiary breaker gaps (10, 20), a drive element (22) of the subsidiary gap (20) being so connected to the drive (6) of the main gap (10) that upon switch-on the subsidiary gap (20) closes before the main gap (10) and upon switch-off the subsidiary gap (20) opens before the main gap (10) and that the subsidiary gap (20) has a switch pin (24) which is movable against the drive element (22), with a locking device (60 ; 60a ; 92) which in the switched-on state locks the movable switch pin (24 ; 96, 116), and with an unlocking device (80 ; 80a ; 128, 130) which releases the lock at the end of the switch-off movement, characterized in that the conductive part of the switch pin (24 ; 96, 116) of the subsidiary gap (20) comprises two tubes (24a, 24b ; 96, 116) which can be telescoped against the force of a spring (25 ; 140), and in that the locking device (60 ; 60a ; 92) is arranged between the tubes (24a, 24b ; 96, 116).

Description

The invention relates to a high-voltage circuit breaker according to the preamble of claim 1.

In the case of electrical circuit breakers for very high operating voltages, it is known to reduce the overvoltages that occur especially when switching on long, unloaded lines by using damping resistors. The damping resistances are parallel to the main switching sections. When switching on, the damping resistors (switch-on resistors) are switched on shortly before the main switching paths are closed by assigned auxiliary switching paths (isolating switches).

Switching on via resistors ensures that the long line to be switched on via the circuit breaker is temporarily connected to voltage only via a correspondingly dimensioned resistor until the main switching paths have completed the switch-on. On the other hand, when the circuit breaker is open, no current can flow through the resistance circuit, since this is interrupted by the disconnector. This maintains the full insulation capacity of the switch.

In such high-voltage switches with switch-on resistors, the first task is to switch on the switch-on resistor parallel to the main switching path about 10 ms before the main switching paths are switched on by the auxiliary switching path. When the switch is subsequently switched off, on the other hand, it must be ensured that the resistance current path is switched off in good time before the main contacts are disconnected. This second task can basically be solved by either immediately after switching on the auxiliary switching section automatically (regardless of whether there is already a switch-off command for the main switching section) or by first keeping the auxiliary switching section closed and only switching off in time when the switch is switched off externally.

A high-voltage circuit breaker of the type mentioned in the introduction, in which the auxiliary switching path switches off again immediately after it has been switched on, is known from DE-AS 21 08 915. In this high-voltage circuit breaker, the auxiliary switching point has a spring acting in the opening direction and is actuated by a crank via a rod with an elongated hole with a crank pin, the free path of which is limited depending on the position. This position-dependent releasable connection ensures that the auxiliary switching point is opened again immediately after the main switching point is closed, because the crank pulls the switching pin back after the extended position has been exceeded, and at the end of the pivoting movement the connection between the drive and the auxiliary switching point by unlocking the elongated hole is released so that the spring can bring the switching pin into the switch-off end position. The main control point remains closed regardless of this process.

Problems can arise with this principle of movement of the auxiliary switching path in such switching operations in which it must be switched off again immediately after switching on. In this case, the spring that moves the switching pin back must be dimensioned relatively strong, so that it is ensured that the electrical strength of the auxiliary switching path is always significantly greater than that of the main switching path, because the moving contact of the main switching path is greatly accelerated. With such a strong spring, the locking device must be dimensioned according to the high spring forces ^* or the unlocking causes difficulties due to the high spring forces, which can lead to malfunctions when the auxiliary resistor is switched off.

It is therefore the object of the invention to improve a high-voltage circuit breaker of the type mentioned at the outset in such a way that strong springs and appropriately dimensioned unlocking mechanisms are avoided in a structurally and operationally simple manner.

According to the invention, this object is achieved by the features characterizing patent claim 1.

The solution according to the invention is thus based on the second basic solution, in which the auxiliary switching path initially remains closed and only switches off in good time when the switch is switched off from the outside. The auxiliary switching section is rigidly coupled to the main switching section via a lever system. The translation of this lever system on the one hand and the contact spacing (and the contact strokes derived from it) of the main switching section and auxiliary switching section on the other hand are selected so that when the switch is switched on, contact is made earlier in the auxiliary switching section than in the main switching section. In the solution according to the invention, the advantages of a mechanically rigid switch-on process are achieved with great simplicity of the switch-on mechanism.

Since the spring acts in a completely different way in the solution according to the invention than in the known switch, insofar as it does not contribute to the switching-off process, it can be made very small. Accordingly, the auxiliary switching path, in particular also the locking and unlocking device, can be implemented very easily and without additional insulating parts on the switching pin of the auxiliary switching path.

An embodiment of the invention provides that the switching pin parts of the auxiliary switching path are two cylindrical tubes. In this embodiment, the spring can advantageously be arranged in the switching pin parts, which guide the spring. Further refinements of the invention provide that the locking device has at least one lever which is attached to the switching pin part assigned to the drive lever and connected to it by means of pivot pins and which engages in at least one catch in the locking position, and that the unlocking device has at least one conical stop or has a conical ramp surface which (or which) pivots the locking lever in the unlocked position. With this configuration, a simple and reliable locking and unlocking device is created.

According to a further embodiment of the invention it is provided that the locking device has an expandable locking ring which is arranged concentrically around the central axis of the switching pin; that a locking pin is arranged on the switching pin part assigned to the drive lever parallel to the axis of the switching pin, which engages in the locking position in a gap of the locking ring in order to hold it in the spread position; that a spring is provided which presses the locking pin in the direction of its locking position; and that the unlocking device has a stop which, when the locking pin strikes, brings it into the unlocking position, so that compression of the locking ring and thus unlocking is made possible. The concentric arrangement of the locking device results in a very uniform load, which enables the individual parts of the locking device to be made particularly light.

A further embodiment of the invention provides that the locking device has at least one radially preloaded cam, which is fixedly connected to the contact piece part facing the counter contact and which interacts with at least one catch. According to a further embodiment, the switching pin part has longitudinal slots in the locking area for radial preloading of the cam, which enable elastic deformation. In these configurations, the switching pin part itself is featured as a radial in a very advantageous manner tensioned element formed, which allows a very simple design of the locking device with few parts.

According to a further embodiment of the invention it is provided that the stop for the switching pin for absorbing the kinetic energy of the switching pin has a buffer. According to advantageous embodiments, it is further provided that the buffer consists of an elastic plastic, in particular polyurethane. According to further refinements, the buffering can also take place pneumatically or by means of a mating contact, which is designed as a resilient pressure contact for buffering.

Another embodiment of the invention provides that the counter-contact piece is disc-shaped and has a guide cylinder, on the outer wall of which a sliding contact transmits the current and moves a spring when switched on, buffering taking place between the disc-shaped part and the adjacent fixed surface. According to a further embodiment of the invention it is provided that the end face of the switching pin is convex and the opposite part of the mating contact is concave. In particular, according to a further embodiment, the radius of the end face of the switching pin is somewhat smaller than that of the opposite part of the mating contact. By varying the radii of the end face of the switching pin or the mating contact, the contact conditions of these contacts and thus the buffering can be expediently set.

Another embodiment of the invention provides that the contact surfaces are copper-plated.

According to a further embodiment of the invention, it is provided that the locking device has at least one locking element which is arranged on a part assigned to the drive lever in an axially positive and radially pivotable manner; that the switching pin facing the counter-contact has a locking element, behind which the locking element is locked Condition takes hold; and that the locking element has a first nose, which cooperates with the latching element in the unlocked position as a stop limiting the movement of the switching pin part, and a second nose, which cooperates with the latching element in the locked position as a driver. According to the invention, this configuration of the locking device can also be used independently of the switches described above. With this configuration, a locking device is created which is very simple and light in construction and nevertheless in any case meets the operating requirements, the switching reliability being improved and the wear reduced, ie the possible number of switching operations being increased. In particular, the simple switching pin has small moving masses.

According to an embodiment of this invention, it is provided that the switching pin part facing the counter contact is arranged telescopically on a tube. With this arrangement, a simple possibility of guiding the switching pin part is created, in which a spring that moves the switching pin part can be arranged in the interior of the tube.

Another embodiment of the invention provides that a plurality of locking elements are provided, which are segments of a longitudinally slotted, essentially tubular structure. With this configuration, a symmetrical arrangement is possible, which results in very advantageous load conditions.

A further embodiment of the invention provides that a ramp arranged in the path of movement of the locking element is provided between the lugs of the locking element, so that the locking element can be moved radially outward from the locking element.

According to a further embodiment of the invention, it is provided that the tube has an annular bead on which the locking elements with a correspondingly shaped recess are arranged to be radially movable but axially form-fitting. This Ausge staltung contains a simple in construction and manufacture and very reliable connection between the tube and the locking elements.

Another embodiment provides that the recess is arranged adjacent to the second nose.

According to another embodiment of the invention it is provided that the locking elements are resiliently biased in the radial direction. According to a further embodiment, this pretension is expediently applied by a toroidal spring which is arranged in recesses in the locking elements.

According to another embodiment of the invention, it is provided that the locking elements have an additional ramp, the movement path of which runs over a stop from which the locking elements are moved radially out of their locking position.

In order to hold the locking elements together at their end facing the mating contact, a groove is provided at this end in which a steel ring holding the locking elements is arranged.

According to another embodiment of the invention, a control element is arranged along the movement path of the locking elements, which control element has a control curve which e.g. is designed by means of ramps so that a radial movement of the locking elements is only possible in certain desired positions. The control element is expediently ring-shaped, which results in a uniform load.

According to a further embodiment of the invention, the stop surrounds the part in a ring.

Another embodiment of the invention provides that the switching pin consists of titanium or an aluminum alloy.

The part assigned to the drive lever is expediently tubular, since the locking elements can advantageously be arranged in such a tube.

Embodiments of the invention are shown in the drawing and described below.

• Figur 1 einen Hochspannungs-Leistungsschalter mit Hilfsschaltstrecke, wobei nur eine Hälfte dargestellt ist;
• Figur 2 eine Hilfsschaltstrecke;
• Figur 2a eine Ver- und Entriegelungseinrichtung;
• Figur 2b eine andere Ausgestaltung einer Ver- und Entriegelungseinrichtung;
• Figur 2c eine weitere Ausgestaltung einer Ver- und Entriegelungseinrichtung;
• Figur 3 eine Teilansicht des Schaltstiftes und des Gegenschaltstückes mit pneumatischer Pufferung;
• Figur 3a eine andere Ausgestaltung des Schaltstiftes und des Gegenschaltstückes mit pneumatischer Pufferung;
• Figur 3b eine weitere Ausgestaltung des Schaltstiftes und des Gegenschaltstückes mit mechanischer Pufferung;
• Figur 4 eine Teilansicht einer anderen Ver- und Entriegelungseinrichtung im Schnitt in der Vorlaufstellung;
• Figur 5 die Ver- und Entriegelungseinrichtung der Figur 4 in der Verriegelungsstellung;
• Figur 6 die Ver- und Entriegelungseinrichtung der Figur 4 in der Entriegelungsstellung.

Show it:

• 1 shows a high-voltage circuit breaker with an auxiliary switching path, only one half being shown;
• Figure 2 shows an auxiliary switching path;
• 2a shows a locking and unlocking device;
• Figure 2b shows another embodiment of a locking and unlocking device;
• Figure 2c shows a further embodiment of a locking and unlocking device;
• Figure 3 is a partial view of the switching pin and the counterpart with pneumatic buffering;
• Figure 3a shows another embodiment of the switching pin and the counter switching piece with pneumatic buffering;
• Figure 3b shows a further embodiment of the switching pin and the counter switching piece with mechanical buffering;
• Figure 4 is a partial view of another locking and unlocking device in section in the forward position;
• Figure 5 shows the locking and unlocking device of Figure 4 in the locking position;
• Figure 6 shows the locking and unlocking device of Figure 4 in the unlocked position.

In the following, reference is first made to the embodiments of the invention illustrated in FIGS. 1 to 3.

A switching pin 24 of the auxiliary switching path 20 has at least two parts 24a, 24b which can be telescoped against one another against the force of a spring 25; these switching pin parts 24a, 24b are advantageously tubular. A stop 26 is provided on the mating contact 32 in order to limit the stroke of the switching pin part 24b immediately after the auxiliary switching path 20 contacts. This stop 26 for the switching pin part 24b has a buffer 28 for absorbing the kinetic energy of the switching pin part 24b. The buffer 28 suitably consists of an elastic plastic, in particular polyurethane (Figures 1, 2). In one configuration, the buffer is formed by the mating contact 32, which is designed as a resilient pressure contact for buffering. For this purpose, the mating contact 32 has a guide cylinder with a disk-shaped part 33 (FIG. 2), on the outer wall 34 of which a sliding contact transmits the current and which, when switched on, shifts a spring 35, between the disk-shaped part 33 and the adjacent fixed surface buffering takes place.

The switching pin can advantageously also be buffered pneumatically (FIGS. 3, 3a, 3b). For this purpose, the end face of the switching pin part 27b is convex and the corresponding opposite part of the mating contact 32 is concave. In Figure 3, the radius of curvature of the switching pin part 27b 'is larger than that of the counter contact 32', whereby an optimal buffering is achieved by the air cushion being formed. In order to enable an even better contacting, the radius of curvature of the end face of the switching pin part 27b ″ is, conversely, somewhat smaller than that of the opposite part of the counter-contact 32 ″ in the embodiment shown in FIG. ₀ In the area, good buffering is possible with good contacting at the same time.

A locking device 60 is provided between the switching pin parts 24a, 24b, which locks the pushed-together switching pin parts with one another in the switched-on position.

In the locking device 60 shown in FIG. 2, it has at least one radially preloaded cam 62 which is fixedly connected to the contact piece part 24b facing the counter contact 32 and which interacts with at least one catch 64 provided on the contact piece part 24a. For the radial prestressing of the cam 62, the switching pin part 24b has longitudinal slots 66 in the locking area (only shown in FIGS. 2b and 2c), which allow an elastic deformation of the switching pin part 24b in the locking area.

In another locking device 60a (FIG. 2a), this has a plurality of levers 52 which are connected to the switching pin part 24a assigned to the drive lever and which, in the locking position, engage in at least one catch 55 provided on the switching element part 24b.

In the locking device 60b shown in FIG. 2b, a radially preloaded cam 62 is again provided on the switching piece part 24b, which interacts with the catch 64.

In the locking device shown in FIG. 2b, a radially preloaded cam 62 on the contact piece part 24b interacts with a catch 64b provided at one end of a double-armed lever.

An unlocking device 80 is provided in order to release the locking again at the end of the opening movement. The unlocking device 80 shown in FIGS. 1 and 2 has a conical stop 82 which moves the cams 62 lying behind the catch 6.4 in the locked state in the radial direction and thereby releases the lock.

In the unlocking device 80a shown in FIG. 2a, a conical stop 82a is again provided, which pivots the locking lever 52 outwards via a corresponding counter surface formed on the lever 52, so that it releases the catch 55.

In the embodiment of the unlocking device 80b shown in FIG. 2b, a conical stop 82b is again provided which interacts with a one-armed lever 65b which has a conical counter surface. When the conical surfaces meet, the one-armed lever 65b is pressed inward and thereby moves the cam 62 inward in the radial direction, as a result of which the unlocking is canceled.

In the unlocking device 80c shown in FIG. 2c, the double-armed lever 65c has a conical counter surface which interacts with the conical surface of the stop 82c, so that the lever 65c is pivoted counterclockwise when it hits the surface 82c, so that the catch 64c den Releases cam 62 and thereby releases the unlocking.

In a further embodiment, a locking device is provided, as is known per se from DE-PS 15 40 062 and DE-PS 27 08 546. This locking device works with an expandable locking ring (piston ring locking). In the present embodiment, the locking ring is arranged concentrically around the central axis of the switching pin 24. A locking pin is arranged on the switching pin part 24b assigned to the drive lever parallel to the axis of the switching pin and engages in the locking position in a gap of the locking ring in order to hold it in the spread position. A spring is provided to push the locking pin towards its locking position. An unlocking device has a stop which, when the locking pin occurs, brings it into the unlocking position, so that a compression of the locking ring and thus unlocking is made possible.

The basic mode of operation of the high-voltage circuit breaker is described below. In the switch-off position, the main switching section 10 and the auxiliary switching section 20 are open. To switch uipd actuated via the isolating rod 6 and the lever system 40, the switching pin 12 of the main switching section and the switching pin 24 of the auxiliary switching section. Immediately after contact of the auxiliary switching path 20, its switching pin 24 strikes the stop 26 which limits the switching pin, as a result of which the two switching pin parts 24a, 24b are pushed together by the further moving drive part and the spring 25 is simultaneously tensioned.

When the main switching path has also switched on and the entire drive system has come to rest, the locking device 60 is actuated, as a result of which the two switching pin parts 24a, 24b are locked together in the pushed-together position. The auxiliary switching path 20 remains in this state as long as the switch remains switched on.

When the switch is switched off, the lever system 40 moves the switching pin 24 of the auxiliary switching path 20 - shortened in its effective length - simultaneously with the movement of the contacts 12 of the main switching path into the switch-off position. In this case, the contact separation of the auxiliary switching path 24 occurs earlier than in the main switching path, as a result of which the current path of the resistor is cut in time.

At the end of the switch-off movement, the locked switching pin parts 24a, 24b are unlocked with the aid of the unlocking device 80 and the spring 25 relaxes, as a result of which the switching pin parts 24a, 24b are moved apart again. The switch is then ready for activation.

The contact surfaces of the switching pin and mating contact made of steel are expediently copper-clad.

The locking device shown in FIGS. 4 to 6 has at least one locking element 92 which is connected to the part 116 associated with the drive lever of the switch (not shown) in a radially movable manner. The connection is made in a manner shown below. The switching pin part 96 facing the mating contact 98 has a latching element 100, behind which the locking element 92 engages in the locked state. The locking element 92 has a first nose 112, which interacts with the locking element 100 of the switching pin part 96 in the unlocked position as a stop, and a second nose 114 which interacts with the locking element 100 in the locked position as a driver. A plurality of locking elements 92 are expediently provided, which are parts of a longitudinally slotted structure with an essentially tubular shape.

The locking element 92 is connected to a tubular part 116 which is moved axially by the drive lever (not shown) of the switch.

The tube 116 has an outwardly directed annular bead 120 on which the locking elements 92 are arranged with a correspondingly shaped recess 122 so as to be radially movable but axially form-fitting. The recess 122 is arranged adjacent to the nose 114 of the locking element 92 and has an essentially U-shaped shape. Adjacent to the recess 122 there is a further recess 126 pointing outwards. A toroidal spring 124 is arranged in this recess in order to generate a radial preload. An additional ramp 128 adjoins the recess 126, the movement path of which runs over a fixed stop 130, by which the locking elements 92 are moved radially out of their locking position. The ramp 128 is inclined outwards, so that a wedge pointing in the switch-on direction is formed between the tube 116 and the ramp 128, into which a fixed tubular stopper 130 penetrates during the return in order to move the locking element out of its locking position. The locking elements 92 have a groove 132 at their end facing the mating contact 98, in which a steel ring 134 holding them together is arranged.

In addition to the path of movement of the locking element 92, a control element 136 is arranged which has a control cam 138 which is designed in such a way that such a movement is only possible in the region of the positions in which a radial movement of the locking element 92 is desired. The For this purpose, control element 136 has ramps 138a, 138b which, when the locking device moves, press the locking elements 92 into their locking position. In the case of several locking elements 92, the control element 136 expediently has the shape of a circumferential ring.

According to an embodiment of the invention, the switching pin part can be arranged to slide telescopically on a tube 94. This tube 94 expediently simultaneously forms a sleeve for a spring 140 arranged in its interior, which protrudes into the appropriately tubular switching pin part 96 and which serves to move this switching pin part 96 and is also expediently used for carrying the current.

The operation of the locking device is described below. Starting from the advance position shown in FIG. 4, in which the switching pin part 96 just touches the counter contact 98, the tube 116 and thus the locking elements 92 are moved in the direction of the counter contact 98 in the course of the further switch-on movement. If, as a result, the switching pin part 96 is immersed sufficiently far, the latching element 110 presses against the ramp 118 and thus the locking element 92 against the spring force of the toroidal spring 124 and then snaps in behind the 92 nose 114. This locking position is shown in Figure 5.

When switched off, the tube 116 with the locking elements 92 are moved in the opposite direction. After a certain distance has been covered, the ramp 128 runs against the stop 130 and is pressed radially outward by the latter. This position is shown in Figure 6. The nose 114 of the locking element 92 is moved out of the movement path of the locking element 100 on the switching pin part 96. As a result, the switching pin part 96 is pressed by the spring 140 in the "ON" direction until the latching element 100 abuts the nose 112 of the locking element 92. This position is shown in Figure 6 in dashed lines. It forms the starting position for a new switch-on process.

Claims (30)

1. High voltage circuit breaker with at least one main switching path; with at least one on-resistance, which is arranged parallel to the current paths of the main switching path; with at least one auxiliary switching path, which is in series with the on-resistance for switching it; with a common drive for the main and auxiliary switching path, whereby a drive part of the auxiliary switching path is connected to the drive of the main switching path via a lever system, such that when switching on the auxiliary switching path closes before the main switching path and that the auxiliary switching path is opened before the main switching path is opened ;
characterized, that the lever system (40) rigidly connects the drive part (22) of the auxiliary switching section with the drive of the main switching section; that a switching pin (24) of the auxiliary switching path has at least two parts (24a, 24b) which can be telescoped against one another against the force of a spring (25); that a locking device (60) is provided between the switching pin parts (24a, 24b), which in the switched-on position locks the pushed-together switching pin parts (24a, 24b) together, and that an unlocking device (80) is provided which, at the end of a subsequent switch-off movement, the locking picks up again. 2. High-voltage circuit breaker according to claim 1,

characterized,
that the switching pin parts (24a, 24b) of the auxiliary switching path are two cylindrical tubes. 3. High-voltage circuit breaker according to one of the preceding claims,
characterized, that the locking device (60a) has at least one lever (52) which is attached to the switching pin part (24a) assigned to the drive lever and connected to it by means of pivot pins and which engages in at least one catch (55) in the locking position. 4. High-voltage circuit breaker according to claim 3,
characterized,
that the unlocking device (80a) has at least one conical stop or a conical ramp surface which (or which) pivots the locking lever (52) in the unlocking position. 5. High-voltage circuit breaker according to one of claims 1 or 2,
characterized, that the locking device has an expandable locking ring which is arranged concentrically around the central axis of the switching pin; that a locking pin on the switching pin part (24a) assigned to the drive lever is arranged parallel to the axis of the switching pin (24), which engages in the locking position in a gap of the locking ring in order to hold it in the spread position; that a spring is provided which presses the locking pin in the direction of its locking position; and that the unlocking device has a stop which, when the locking pin strikes, brings it into the unlocking position, so that a compression of the locking ring and thus unlocking is made possible. 6. High-voltage circuit breaker according to one of claims 1 or 2,
characterized,
that the locking device (60) has at least one radially preloaded cam (62) which is fixedly connected to the contact piece part (24b) facing the counter-contact (32) and which interacts with at least one catch (64). 7. High-voltage circuit breaker according to claim 6,
characterized by h
that for the radial pretensioning of the cam (62), the switching pin part (24b) has longitudinal slots (66) in the locking area, which allow an elastic deformation. 8. High-voltage circuit breaker according to one of the preceding claims,
characterized,
that the stop (26) for the switching pin (24) for absorbing the kinetic energy of the switching pin has a buffer (28). 9. High-voltage circuit breaker according to claim 8,
characterized by h,
that the buffer consists of an elastic plastic, in particular polyurethane. 10. High-voltage circuit breaker according to claim 8,
characterized by h,
that the buffering is pneumatic. 11. High-voltage circuit breaker according to claim 8 or 9,
characterized by h,
that the stop is formed by the counter contact, which is designed as a resilient pressure contact for buffering. 12. High-voltage circuit breaker according to claim 11,
characterized,
that the counter-contact piece (32) is disc-shaped and has a guide cylinder (33), on the outer wall of which a sliding contact transmits the current and moves a spring (35) when switched on, buffering taking place between the disc-shaped part and the adjacent fixed surface. 13. High-voltage circuit breaker according to claim 10,

characterized,
that the end face of the switching pin (24) is convex and the opposite part of the mating contact (32) is concave. 14. High-voltage circuit breaker according to claim 13,
characterized,
that the radius of the end face of the switching pin (24) is slightly smaller than that of the opposite part of the mating contact (32). 15. High-voltage circuit breaker according to one of the preceding claims,
characterized,
that the contact surfaces are copper-plated. 16. High-voltage circuit breaker, in particular according to one of the preceding claims,
characterized, that the locking device has at least one locking element (92) which is arranged on a part (116) associated with the drive lever in an axially positive and radially pivotable manner; that the switching pin part (96) facing the mating contact (98) has a latching element (100), behind which the locking element (92) engages in the locked state; and that the locking element (92) has a first lug (12) which interacts with the latching element (100) in the unlocked position as a stop limiting the movement of the switching pin part (96) and a second lug (114) which connects with the latching element ( 100) cooperates in the locked position as a driver. 17. High-voltage circuit breaker according to claim 16,
characterized,
that the switching pin part (96) facing the counter contact is arranged telescopically on a tube (94). 18. High-voltage circuit breaker according to one of claims 16 or 17,
characterized by h,
that a plurality of locking elements (92) are provided, which are segments of a longitudinally slotted, essentially tubular structure. 19. High-voltage circuit breaker according to one of claims 16 to 18,
characterized,
that between the lugs (112, 114) of the locking element (92) there is a ramp (118) arranged in the path of movement of the locking element (100), so that the locking element can be moved radially outward from the locking element. 20. High-voltage circuit breaker according to one of claims 17 to 19,
characterized by h,
that the part (116) has an annular bead (120) on which the locking elements (92) with a correspondingly shaped recess (122) are arranged to be radially movable but axially form-fitting. 21. High-voltage circuit breaker according to claim 20,
characterized,
that the recess (122) is arranged adjacent to the second nose (114). 22. High-voltage circuit breaker according to one of claims 16 to 21,
characterized by h,
that the locking elements (92) are resiliently biased in the radial direction. 23. High-voltage circuit breaker according to claim 22,
characterized,
that a toroidal spring (124) is used to generate the preload is provided, which is arranged in recesses (126) of the locking elements (92). 24. High-voltage circuit breaker according to one of claims 16 to 23,
characterized,
that the locking elements (92) have an additional ramp (128), the path of which extends over a stop (130), from which the locking elements are moved radially out of their locking position. 25. High-voltage circuit breaker according to one of claims 16 to 24,
characterized,
that the locking elements (92) have at their end facing the counter-contact a groove (132) in which a steel ring (134) holding them together is arranged. 26. High-voltage circuit breaker according to one of claims 16 to 25,
characterized,
that a control element (136) is arranged along the movement path of the locking elements (92), which has a control cam (138) which is designed, for example, by means of ramps (138a, 138b) in such a way that radial movement of the locking elements is only possible in certain desired positions is. 27. High-voltage circuit breaker according to claim 26,
characterized,
that the control element (136) is annular. 28. High-voltage circuit breaker according to one of claims 24 to 27,
characterized,
that the stop (130) surrounds the part (116) in a ring. 29 high-voltage circuit breaker according to one of claims 16 to 28,
characterized,
that the switch pin is made of titanium or an aluminum alloy. 30. High-voltage circuit breaker according to one of claims 16 to 29,
characterized by h,
that the part (116) is a pipe.

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