DE3020800C2 - Vacuum circuit breaker - Google Patents

Description

The invention relates to a vacuum circuit breaker according to the preamble of claim 1.

Such a switch is known from the German utility model 79 36 232.

The object of the invention is to reduce the tripping time of the switch, i. H. the time from The arrival of the off signal until the switching contacts are disconnected passes, as does the switchover time the time that the switch needs to switch off again after it has just been switched on (e.g. when switching to a short circuit).

One difficulty arises from the fact that the mass of the mechanical unlocking or locking elements cannot be reduced to any size for rapid movements; because high breaking capacities are strong Condition energy storage with appropriately sized locking members.

When the switch of the German utility model 79 36 232 it is z. B. not possible a desired to achieve a short switchover time, since the one there, to the Switch-off force accumulator acting shift lever from the drive initially completely ir. Its starting position must be swiveled back before the switch-off movement of the contact can be carried out

The solution to the problem set out at the beginning is provided by a high-voltage potential

ι ο Coupling between drive and switch-off force store achieved, which the operative connection of these parts at the end of the switch-on movement of a shift lever - after the switch-on has been completed and the switch-off force store is locked - inevitably immediately cancels and that the release linkage is also arranged on the switch pole at high voltage potential Includes lift mechanism.

The coupling is expediently implemented by a ratchet system. This can be implemented with a low mass because after locking the switch-off force accumulator only the low force of its release spring is to be released

The trigger linkage can also be due to the inventive arrangement of its energy storage be designed to be low-mass, because it then only needs to transmit tensile forces for triggering.

The design of the coupling can be such that the one which can be pivoted by the drive and is mounted on the switch pole Shift lever at its free end rotatably carries a locking lever for power transmission, the Switching on runs up against a stop, whereby it - releasing the clutch - swings out. The latch lever can act on the switch-off force store via a further pivot lever, in which case the actual, releasable coupling is formed between these levers. Further explanations of the invention may be taken from the description of an exemplary embodiment.

Fi g. 1 shows the side view of a switch pole with a vacuum interrupter (1) when switched off. The stationary one is shown in dashed lines Contact (2) and the movable contact (3). The interrupter 1 is held by the lower connection piece (4), which is attached to the right side of the rib support (5). The one led out of the interrupter 1 above Conductor element (6) protrudes into the upper connection piece (7), which in turn is on the right side of the rib support (8) is attached. Both rib supports are mounted together on the base frame (9).

The connector 7 goes up into the switch housing (10), in which the switch-off force store and the locking and unlocking mechanism is housed.

In Figure 2, the switch housing 10 is in axial section shown. You can see the upper part of the vacuum interrupter 1 with the conductor element 6, which is in the Threaded connector (11) passes over and onto which the contact tube (12) is screwed. The latter contains in the lamellar contacts (13) corresponding grooves. These are on the inner wall during the switching operations of the cylindrical part of the switch housing 10 shifted axially.

The threaded piece (14) is fastened to the threaded connector 11; this is surrounded by the screw sleeve (15) into which the bolt (16) is firmly screwed at the top. The bolt 16 is thus connected to the movable contact 3 in a force-locking manner.
The bolt head (17) is in the guide piece (18)

The latter serves as an upper abutment for the opening spring (19) and the contact pressure spring (20). At the bottom, the opening spring 19 is based on the stationary extension (21) in the switch housing 10 and the Contact compression spring 20 on the screw sleeve 15.

Above the guide piece 18, the ball guide piece (22) is arranged, which is thus below the Biasing pressure of said springs against the limiting face of the switch housing 10 is pressed

In the bores of this ball guide piece, the balls (23) are embedded in the radial direction held on the outside by the stationary support tube (24) and partially engage inwards in that of the plunger (25).

The plunger 25 contains the release spring (26), which is supported below on the bolt of the ball guide piece 22 The plunger 25 protrudes with a square shoulder from the switch housing 10.

The latter has a bearing for the bolt (27) on which the pivot lever (28) is rotatably arranged. The switching lever (31) is also rotatably mounted on the bolt 27. At its free end it has a bearing point for the bolt (29) which the locking lever (30) is rotatably arranged

The switch is switched off. If the shift lever 31 is switched on pivoted by the drive in the direction of the arrow to the left, then the free end of the locking lever 30 pushes the free one End of the pivot lever 28 frictionally downwards. The latter presses the plunger 25 over its end face downward.

Since the balls 23 can not move laterally, they form a frictional connection from the plunger 25 to Ball guide piece 22, which is thus also pushed downwards. This movement inevitably follows the guide piece 18, which via the pretensioned contact pressure spring 20, the screw sleeve 15, the Threaded piece 14 and the conductor element 6 attached to it with the movable contact 3 facing downwards presses until the latter comes to a standstill after contact has been made with the stationary contact 2.

By further downward movement of the plunger 25, the pretensioned contact pressure spring 20 is now still tensioned to full contact pressure.

During this movement process is also of the guide piece 18, the pretensioned Switch-off spring 19 tensioned

After the contact pressure has been achieved by moving the said parts downwards, are Meanwhile, the balls 23 reached a recess in the stationary support tube 24, so that the radial external support canceled.

The bearing surface of the balls 23 in the groove of the plunger 25 has a slope so that now the Balls are pressed into said recess by a radial force component. Here is the frictional connection of the plunger 25 to the ball guide piece 22 is canceled, the plunger can now move freely downwards move and tension the already pre-tensioned release spring 26. Locks with its outer jacket surface he the balls 23.

During this downward movement of the plunger 25, a recess provided on its square is advanced the lower edge of the half-wave (3Ia ^, so that the latter by means of a spring is able to rotate through a small angle and thus the plunger against a Locks upward movement.

After another downward Übereihub of the plunger, the nose (32) of the locking lever 30 hits the Stop (33), which is formed by the head of a stationary adjusting screw Latching lever 30, the notch between it and the pivot lever 28 is released, the latter is on the one hand by the return of the upper stroke of the plunger 25, caused by the release spring 26, and on the other hand, possibly by its own return spring it snaps freely into its starting position until it reaches its rear The end of the lever (34) strikes the stationary switch housing 10. The switch-on operation is now complete completed and the system is in the, in F i g. 3 position shown arrives

Although the shift lever 3i is still in the on position, its Kxaftschluss to that The plunger 25 is lifted so that it is ready to be switched off directly in view of the requirement for a very short one Switching time, this fact is essential, because the backward movement of the shift lever 31 on the The insulating rod, switching shaft, etc. (not shown) is strong because of the mass of these components delayed

The following switch-off process is initiated by rotating the half-shaft 31a in the direction of the arrow (Fig. 3). The release spring 26 can relax and pushes the plunger 25 upwards until its groove comes before the balls 23.

The bearing surface of the balls 23 in the recess of the stationary support tube 24 also has a Incline, so that under the upward force of the tensioned contact compression spring 20 and Switch-off spring 19 an inwardly directed radial force component these balls 23 in the groove of the Plunger 25 pushes. This ensures the frictional connection of the moving parts to the stationary support tube 24 canceled.

As can be seen, the head 17 of the bolt 16 when the contact compression spring 20 is tensioned solved a certain amount of its support in the guide piece 18. This amount can apply the contact compression spring 20 and the switch-off spring 19, released from the movable contact 3, relax freely. As a result of the impact of the guide piece 18 on the head 17, an impulse is generated which may occurring welds of the contacts tear open. Now the releasing switch-off spring presses 19 moves the movable system upwards and thus executes the switch-off movement.

Subsequently, the switching lever 31 and thus the locking lever 30 of the drive is again in the position shown in FIG shown initial position brought.

With the invention it is possible to measure the time from the release of the half-wave 31a to the contact separation to decrease significantly. In order to keep the health release time small, it makes sense to use the Components that cause the rotation of the half-shaft 31a are kept small in terms of mass, d. H. consequently that they are largely also arranged on the switch pole. For the sake of clarity, are this semi-schematically in FIG. 4 shown. In the head 17 of the bolt 16 is sideways from the Switch housing 10 protruding bolts (36) mounted; it is thus frictionally connected to the movement of the movable contact 3 bound. It engages positively in the fork of the lever (37), which is on the Bolt (38) is mounted. The latter is guided in a corresponding hole in the switch housing 10. So that the lever 37 leads exactly with the Schaltheweminu

connected pivoting, which via the Isolating rods (39) are forwarded to the switch position indicator on the earth side.

At the free end of the lever 37 is via the rotatable guide piece (40) the movable therein, the release linkage forming rod (41) stored. This guide piece 40 is located in a radius-compensating fork. The adjusting rings (42), (43) and (44) are attached to this rod 41. Furthermore is the rod 41 slidably and rotatably mounted in the guide piece (45), which is at the free end of the Lever (46) is arranged on the laterally led out of the switch housing 10 end of the Half shaft 31a is attached. The switch-off position can be seen from the constellation shown.

The rod 41 is on the earth side via a thin insulating rod with locking member (47) z. Z. in locked position tied together.

Between the adjusting ring 44 and the guide piece 45 is the currently tensioned compression spring on the rod 41 (48) arranged. If the switch is turned on, then this compression spring 48 presses the lever 46 Half wave in locked position. The guide piece 45 thus comes directly next to the adjusting ring 43.

When switching on, the bolt 36 is moved downwards and thus the guide piece 40 is moved to the left. Here the latter tensions the compression spring (49) mounted between it and the adjusting ring 43 on the rod 41. On the a tensile force is exerted on the earth-side locking member.

If the locking member 47 is now released for disconnection, the tensioned compression spring 49 pushes over the adjusting ring 43, the rod 41 to the left, while the adjusting ring 43 presses the one located next to it Guide piece 45 and thus the lever 46 to the left, so that the half-shaft 31a releases the latch and the Deactivation takes place. The moving parts of this

ίο Systems are low in mass.

When the rod 41 moves to the left, the adjusting ring 44 also moves to the left, so it sits down the relaxed compression spring 48 of the pivoting movement of the lever 46 does not oppose any resistance. the Switching off movement of the bolt now pivots the guide piece 40 to the right; this pushes over the adjusting ring 42 the rod 41 back to the right. So that the spring 48 is again for a switch-on process tensioned, and the locking member 47 is in reverse voltage.

In this unusually simple way, the following switching action takes place after every switching action prepared, d. H. the usual quick reactions in switching operations, with during a switching operation Individual components perform differently directed movements are not required; a circumstance of contributes significantly to increasing operational safety.

For this purpose 4 sheets of drawings

Claims (5)

Patent claims: 1. vacuum circuit breaker for high voltage, with contacts movable relative to one another along an axis and high voltage at the switch pole arranged, when switched on by a drive chargeable switch-off force storage and Devices for its locking and unlocking, the unlocking via a separate Trigger linkage takes place, characterized by a arranged on high voltage potential Coupling between drive and switch-off force accumulator, which is the operative connection between these Parts during the switch-on movement of a switching lever (31) - after the switch-on has been completed and the switch-off force accumulator is loaded and locked - inevitably and immediately for one Deactivation action cancels and that the separate release linkage (rod 41) has an energy store contains, which is also arranged at the switch pole on high voltage potential. 2. Switch according to claim 1, characterized in that the free end of the drive pivotable switching lever (31) mounted on the switch pole a rotatable locking lever (30) contributes to the power transmission, which runs up against a stop (33) when switched on, whereby he - the Releasing the clutch - is swiveled out. 3. Switch according to claim 2, characterized in that the locking lever (30) has a Swivel lever (28) acts on the switch-off force accumulator and these parts act on the detachable clutch form. 4. Switch according to claim 3, characterized in that the pivot lever (28) and locking lever (30) each have a corresponding concave or convex sliding surface and the pivot lever can be brought into its starting position by a return spring. 5. Switch according to claim 1, characterized in that the energy store of the release linkage is formed by two springs (48, 49) acting in the axial direction of this linkage, with in direct dependence on the position of the movable contact (3) in each case a spring for Actuation of the unlocking or locking of the switch-off force accumulator is tensioned.