JPH07211199A - Breaking device - Google Patents

Abstract

PURPOSE:To obtain a breaking device capable of increasing the distance in opened poles between the contacts after the poles are opened, having the good contact status during pole closing, superior breaking performance and conductivity, being preferable as the resistor breaking part of a gas breaker with resistor. CONSTITUTION:A movable contact 13 of a movable contact part A is constituted to be slidable in response to a control rod 9 and a puffer cylinder 10 and energized to an opposite contact part B side by means of a spring 12. The opposite contact part B is provided with an opposite contact 5, first and second springs 6a and 6b, a cylinder 7, and a floating medium 8. The floating medium 8 is energized to the movable contact part A side in relation to a support plate 16 of a cylinder 7 by means of the spring 6a and the opposite contact 5 is energized to the movable contact part A side in relation to the floating medium 8 by means of the spring 6b. The energizing power of the three springs 6a, 6b, and 12 has the relationship of energizing power of the spring 6a > energizing power of the spring 12 > energizing power of the spring 6b.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas circuit breaker, and more particularly to a main circuit breaker and a resistance circuit breaker having a series resistance connected in parallel to the circuit breaker to prevent surge voltage generated during opening and closing. The present invention relates to a circuit breaker suitable as a resistance circuit breaker for a gas circuit breaker with resistance configured to suppress the circuit breaker.

[0002]

2. Description of the Related Art Conventionally, as a circuit breaker for a power system, there is a system in which a resistance breaker having a series resistance is connected in parallel with a main breaker. The operation of such a circuit breaker with a resistor is as follows. That is, at the time of breaking, the resistance breaking unit opens the gate after the main breaking unit to allow a current to flow through the resistor, and suppresses the surge voltage generated at the opening. In addition, at the time of closing, the resistance breaking unit closes the main breaking unit prior to closing the current to flow a current through the resistor and suppress the surge voltage generated due to the closing.

FIG. 8 shows the concept of the operation when the circuit breaker with resistance as described above interrupts a fault current. As an example, this figure shows a case where a failure has occurred at the right terminal of the circuit breaker in the figure. Further, in the figure, 1 is a main cutoff portion, 2
Is a resistance cutoff portion, 3 is a resistance, and I and Ir are currents.

First, in the closed state shown in FIG. 8 (a), the current I flows through the main breaker 1 having a small resistance value of the path. Next, as shown in FIG. 8B, when the main breaking unit 1 is opened while the resistance breaking unit 2 is closed, the current Ir starts to flow through the resistance breaking unit 2 and the resistor 3. The value of this current Ir is determined by the system voltage and the value of the resistor 3. Then, as shown in FIG. 8C, when the resistance breaker 2 is opened, the current Ir is cut off and the breaker is opened.

Further, as shown in FIG. 8 (b), when a failure occurs at the right terminal of the circuit breaker in the figure and the fault current I is interrupted by the main circuit breaker 1, the circuit breaker has a left terminal in the figure. Is
High transient recovery voltage (surge voltage) will be generated due to interruption. However, in this state, since the resistance cutoff portion 2 is closed, the surge voltage is absorbed by the resistance 3. The resistance breaking unit 2 opens the gate after a necessary time from the main breaking unit 1 so that the surge voltage is suppressed to a sufficiently low value.

On the other hand, when closing the right terminal of FIG. 8 after eliminating the accident, the resistance breaking portion 2 is closed prior to the main breaking portion 1 from the state of FIG. 8 (c). The closing surge voltage at this time is absorbed by the resistor 3. Then, the main cutoff unit 1 includes the resistance cutoff unit 2 so that the surge voltage is suppressed to a sufficiently low value.
Close the pole after a more necessary time.

Conventionally, as a concrete structure of such a resistance breaking unit 2, a structure as shown in FIG. 9 is often adopted. The resistance cutoff portion shown in FIG. 9 is composed of a movable contactor portion A and an opposed contactor portion B which are arranged to face each other. Of these, the movable contactor portion A is composed of the movable contactor 4 that moves in the left-right direction in the drawing. On the other hand, the opposing contactor portion B includes the floating contactor 5 and the opposing contactor 5
It is composed of a spring 6 for urging the movable contact 4 toward the movable contact 4 and a case 7 for supporting them. In this case, the opposing contactor 5 is configured to be engaged with the case 7 at a position protruding from the case 7 by a certain protruding dimension and to be held at that position. Further, such a resistance breaker composed of the movable contactor portion A and the opposed contactor portion B is arranged in a grounding container (not shown) filled with arc-extinguishing gas and is directly connected to the movable contactor 4. It is configured to be driven by a driving device (not shown).

Further, the operation of the resistance interrupting portion of FIG. 9 having such a structure is as follows. That is, during the opening operation, the movable contact 4 is driven in the right direction (arrow direction) in the figure. In this case, the opposing contactor 5 moves to the right in the figure with the movement of the movable contactor 4 while maintaining the contact state with the movable contactor 4 by the biasing force of the spring 6. Therefore, at the initial stage of the opening operation, the resistance breaking portion is started at the same speed as the main breaking portion at the same speed, so that the resistance breaking portion is opened later than the main breaking portion by the contact time between the contacts 4 and 5. be able to. At the end of this contact opening operation, the facing contact 5 engages with the case 7 at a position projecting from the case 7 by the above-mentioned projecting dimension, and stops at that position. Therefore, at the time of the closing operation, the distance between the contacts 4 and 5 is shortened by the protrusion size. It can be closed in advance.

[0009]

However, in the conventional resistance breaking portion as shown in FIG. 9, the spring force is limited by design, so that the acceleration of the opposing contactor 5 during the opening operation is movable. It is much smaller than the acceleration of the contactor 4. Therefore, the movable contactor 4 and the opposing contactor 5 are separated immediately after the opening operation is started. On the other hand, the speed of the movable contactor 4 (contact opening speed) gradually increases after the start of the contact opening operation, but has a small value immediately after the start of the contact opening operation. Therefore, in the resistance interruption part as shown in FIG. 9, the contact is opened at a low speed immediately after the start of the opening operation,
It is difficult to rapidly increase the separation distance between the contacts 4 and 5 after the contact opening. As a result, the dielectric breakdown voltage between the contacts 4 and 5 cannot be increased rapidly, so that sufficient insulation performance cannot be obtained against the high voltage applied immediately after interruption,
It becomes difficult to improve the blocking performance.

Further, in FIG. 9, it is necessary to increase the force of the spring 6 to some extent in order to improve the contact state between the movable contact 4 and the opposed contact 5 in the closed state. However, when the force of the spring 6 is increased, the opposing contactor 5 moves toward the movable contactor 4 side at a relatively high speed during the opening operation, and as described above, the movable contactor 4 at the time of opening the contact. Combined with the low contact opening speed, the dielectric breakdown voltage rises more slowly, the insulation performance becomes lower, and the breaking performance becomes more difficult to improve. On the other hand, the breaking device is required to have a good contact state between the two contacts in the closed state, and therefore a large spring force needs to be applied between the two contacts.

The present invention has been proposed to solve the above-mentioned problems of the prior art, and its purpose is to:
It is possible to quickly increase the contact opening distance between contacts after contact opening, has a good contact state when closing contacts, and has excellent breaking and energizing performance, making it suitable as a resistance breaker for a gas circuit breaker with resistance. To provide a simple shutoff device.

[0012]

A breaking device according to the present invention adopts a wiping method in which a movable contact is not directly connected to a drive device, and has a large and small biasing force on the opposing contact side. A second spring and a floating intermediate body for transmitting the biasing force of the first spring to the opposing contact are provided.

First, the interruption device of the present invention is basically housed in a grounding container filled with an arc-extinguishing gas, and has a movable part including a movable contact and a movable contact part composed of a supporting part thereof. An opposing contactor portion including an opposing contactor is provided, and the movable contactor and the opposing contactor are arranged to face each other so that they can come into contact with and separate from each other. It has a shutoff unit that operates and a drive device that drives the movable portion of the shutoff unit.

In addition to the basic structure described above, the breaking device according to the first aspect has the following features. That is, a part of the movable portion of the movable contact portion is configured as a driving device direct coupling portion that is directly coupled to the driving device, and the movable contactor is not directly coupled to the driving device and is movably supported by the driving device direct coupling portion. . The movable contactor portion has a first spring that biases the movable contactor toward the facing contactor side with respect to the drive device direct coupling portion, and the drive device direct coupling portion is set in advance during the opening operation. After moving by the first set distance, the movable contactor is configured to start the contact opening operation by engaging with the drive device direct connection portion and moving. On the other hand, the opposing contactor portion includes a support portion that movably supports the opposing contactor, a floating intermediate body provided between the support portion and the opposing contactor, and a floating intermediate body with respect to the support portion on the movable contactor side. And a third spring for urging the opposing contactor toward the movable contactor side with respect to the floating intermediate body.
During the contact opening operation, the facing contact portion is moved by the urging force of the second spring between the floating intermediate member and the facing contact member by a preset second set distance, and then the floating intermediate member engages with the support portion. It is configured such that the opposing contactor moves toward the movable contactor side by the urging force of the third spring while stopping together. On the other hand, the urging forces of the first, second, and third springs are the urging force of the second spring> the urging force of the first spring>
The third spring has an urging force.

In addition to the construction of claim 1 as described above, the shutoff device according to claim 2 further has the following features. That is, the movable contactor has a flange on the drive device direct connection part side, and the drive device direct connection part has a cylinder that engages with the flange. And the movable contact part is
During the opening operation, the drive unit direct connection part is set to the first
After moving by the set distance, the flange of the movable contact is engaged with the cylinder of the drive unit direct connection portion to move to start the opening operation.

Furthermore, the interruption device according to claim 3 has the following features in addition to the configuration of claim 2 as described above. That is, the drive device direct connection part is
The movable contactor has a puffer cylinder having a gas outlet, a puffer piston for compressing the gas in the puffer cylinder, and a nozzle for guiding the gas blown out from the gas outlet between the movable contactor and the opposing contactor. With a gas blowing device, the flange and the cylinder are located just before the gas outlet of the puffer cylinder.

[0017]

According to the interrupting device of the present invention having the above-described structure, first, since the movable contactor employs the wiping method, the drive device direct connection portion of the movable contactor portion is opened during the opening operation. Even if the opening operation is started, the floating contact is left in the initial position.Therefore, open the moving contact and the opposing contact after the opening speed becomes sufficiently high. You can In addition, a large biasing force of the second spring acts on the opposing contactor via the floating intermediate body immediately after the start of the opening operation to maintain contact with the movable contactor,
After that, a small biasing force of the third spring acts, and the advancing speed of the opposing contactor becomes sufficiently slow. Therefore, the contact opening distance between the contacts after contact opening can be rapidly increased.

[0018]

【Example】

[1] First Embodiment [1-1] Configuration of First Embodiment FIG. 1 is a diagram showing a configuration of a first embodiment of a circuit breaker according to the present invention, and particularly shows a closed state. The interruption unit of this interruption device is composed of a movable contactor portion A and an opposed contactor portion B, and the interruption portion is housed in a grounding container (not shown) filled with arc extinguishing gas.

First, the structure of the movable contact portion A will be described.
That is, first, the movable contactor portion A is an operation rod 9 that is directly connected to a driving device (not shown) via an insulating rod or the like.
And a puffer cylinder 10 integrally attached to the operating rod 9 and a puffer piston 11 inserted into the puffer cylinder 10. The operating rod 9 and the puffer cylinder 10 are connected directly to the drive unit of the present invention. Equivalent to. Of these, puffer piston 11
Is fixedly supported with respect to a grounding container (not shown), and the gas is compressed by relative movement with the puffer cylinder 10. Further, a gas outlet 10a for blowing out the compressed gas is provided at the end of the puffer cylinder 10 on the side of the facing contact portion B.

The movable contact portion A also has a spring 12 mounted on the end surface of the puffer cylinder 10 on the side of the opposing contact portion B.
And a movable contactor 13 arranged so as to come into contact with the opposite end of the spring 12. This movable contact 1
3 is configured to be slidable with respect to the operating rod 9 and the puffer cylinder 10, and is provided with a spring 12 so that the opposing contact portion B
It is biased toward the side. The spring 12 corresponds to the first spring in the present invention. In addition, the movable contact 13
An insulating nozzle 14 is arranged around and is integrally attached. The insulating nozzle 14 is a means for guiding the gas blown out from the gas outlet 10a of the puffer cylinder 10 between the movable contact 13 and a counter contact 5 described later, and the puffer cylinder 10 and the puffer piston 11 are provided.
Together with this, it constitutes a gas spraying device. Further, a piston 13b having a diameter larger than that of the shaft 13a is formed at the end of the shaft 13a of the movable contactor 13 (on the side opposite to the contactor) so that the inner diameter of the operating rod 9 can be slid. The urging force of the spring 12 is sufficiently larger than the frictional force between the movable contactor 13 side and the drive device direct connection portion (operation rod 9 and puffer cylinder 10) side.

On the other hand, a partition portion 9a having a penetrating portion is provided on the inner diameter portion of the operating rod 9 so as to face the piston 13b of the shaft 13a of the movable contactor 13. An energizing portion 15 is provided in the inner diameter portion of the end portion of the puffer cylinder 10 on the side of the facing contact portion B. Among the movable contactor portions A configured as described above, the puffer piston 1
1 corresponds to the support portion of the movable contact portion in the present invention,
The other portions correspond to the movable portion of the movable contactor portion in the present invention.

Next, the structure of the facing contact portion B will be described.
That is, the opposing contactor portion B has the movable contactor 1 in the closed state.
3, a counter contact 5 that contacts the counter contact 3, a cylinder 7 that movably supports the counter contact 5, a floating intermediate body 8 provided between the cylinder 7 and the counter contact 5, and a support plate 1 for the cylinder 7.
6, a spring 6a for urging the floating intermediate member 8 toward the movable contactor portion A side, and an opposing contactor 13 for urging the floating intermediate member 8 toward the movable contactor portion A side. The spring 6b is provided. Of these, the opposing contactor 5 has a shaft 5a and a piston 5b, like the movable contactor 13 described above. The end of the shaft 5a on the side of the movable contactor A is attached to the end of the floating intermediate body 8. A step portion 5c that engages is provided. Also,
An energizing portion 16a is provided on the inner diameter portion of the support plate 16 of the cylinder 7. On the other hand, the floating intermediate body 8 has the ring shape, and the outer diameter portion thereof slides in the cylinder 7, and the shaft 5a of the opposed contactor 5 is slidable on the inner diameter portion thereof. Penetrates. Further, the spring 6a corresponds to the second spring in the present invention and is a spring having a relatively large urging force and a relatively short stroke, and the spring 6b is
The spring corresponds to the third spring in the present invention and has a relatively long stroke and a relatively small biasing force. Further, B ₁ in the drawing is a braking device portion for the opposing contactor,
It is composed of a cylinder 17, a lid 18 thereof, and a piston 5b of the movable contactor 13.

In the structure shown in FIG. 1, the urging force of the three springs 6a, 6b, 12 is "the urging force of the spring 6a>
The biasing force of the spring 12> the biasing force of the spring 6b ”. By setting the biasing force of the spring in such a relationship, in the closed state shown in FIG.
The piston 13b of the movable contactor 13 and the partition 9a of the operation rod 9 are in close contact with each other, and the piston 13b of the movable contactor 13 is
The distance a between the a and the end of the puffer cylinder 10 is kept at L ₂ . This distance L ₂ is the stop length (wiping length) of the movable contactor 13 during the opening operation of the movable contactor portion A, and corresponds to the first set distance in the present invention. Similarly, in the closed state shown in FIG. 1, the opposing contactor portion B has one end portion of the floating intermediate body 8 and the opposing contactor 5.
And the other end of the floating intermediate body 8 and the end of the cylinder 7 maintain a slight distance L ₁ . This distance L ₁ is equal to the spring 6 at the start of the opening operation.
It is a driving distance of the opposing contactor 5 by a and corresponds to the second set distance in the present invention.

[1-2] Operation of the first embodiment The operation of the interruption device of the present embodiment having the above-mentioned structure is as follows. First, in the closed state shown in FIG.
Since the contact force between the movable contact 13 and the opposed contact 5 is obtained by the large biasing force of the spring 6a, both contactors 5, 13
The contact state of is kept good.

Next, when the opening operation is started from the closed state shown in FIG. 1, the operating rod 9 and the puffer cylinder 10 which are the direct connecting portions of the driving device are driven by the opening driving force from the driving device (not shown). , Start moving to the right in the figure. In such a start state of the contact opening operation, the movable contact 13 is biased toward the opposing contact 5 by the spring 12. Since the urging force of the spring 12 is sufficiently larger than the frictional force between the movable contactor 13 and the drive device direct connection portion side, the movable contactor 13 continues to perform the opening operation from the closed state. The good contact state with the opposing contactor 5 is maintained until immediately after the start.

Subsequently, as shown in FIG. 2 (a), the operating rod 9 and the puffer cylinder 10 which are directly connected to the drive unit are moved from the closed position to the right (arrow 21a) in FIG.
When moved by a distance L _2, the distance between the end of the piston 13b and the puffer cylinder 10 of the movable contact 13 becomes 0, the movable contact 13 and puffer cylinder 10 is engaged in this portion. Therefore, after that, the movable contact 13 is
The contact opening operation is started by engaging the operating rod 9 and the puffer cylinder 10 and moving integrally with them, as shown in FIG.
As shown in, the distance L _o between the movable contact 13 and the opposed contact 5 increases. In this case, in the present embodiment, unlike the conventional example shown in FIG. 9, the contacts are not opened in the low speed state immediately after the start of the opening operation, but are opened in a speeded up state to some extent, It is possible to rapidly increase the opening distance between the rear contacts 5 and 13.

Further, in this embodiment, immediately after the opening operation is started, the floating intermediate body 8 and the opposing contactor 5a which is in close contact with the floating intermediate body 8 are formed.
However, due to the relatively large urging force of the spring 6a, they integrally move forward to the movable contact 13 side, and move forward from the opening position by the distance L _{1 in} FIG. At this time, as shown in FIG. 2A, the distance between the end of the floating intermediate body 8 and the end of the cylinder 7 becomes 0, and the floating intermediate body 8 stops. After that, as shown in FIG. 2B, the opposed contact 5 is driven toward the movable contact 13 by the relatively small biasing force of the spring 6b, and is sufficiently slower than the speed of the movable contact 13. Move forward at speed. Therefore, the increase in the distance L _o between the movable contact 13 and the opposed contact 5 is significantly faster than that in the conventional example shown in FIG. As shown in FIG. 2B, the spring 6b
As a result, when the opposing contactor 5 starts to move forward, the opposing contactor 5
A distance L ₃ is formed between the stepped portion 5c and the end of the floating intermediate body 8 and its size increases.

After the contact is opened, the arc generated between the contacts 5 and 13 is compressed by the reduction of the space C in the puffer cylinder 10 as shown in FIG. , 22b are formed to extinguish the arc. That is, the gas compressed by the reduction of the space C in the puffer cylinder 10 is blown out from the gas outlet port 10 a of the puffer cylinder 10 to form a gas flow 22 a, and further, between the contacts 5 and 13 via the insulating nozzle 14. As a result of the formation of the gas stream 22b directed to the arc, this gas stream 22b is blown into the arc and a break is achieved. At the end of the contact opening operation, as shown in FIG. 2C, the distance between the contacts 5 and 13 is sufficiently large.
_It becomes _{o (e)} , and sufficiently high insulation performance is maintained.

FIG. 3 is a characteristic diagram showing the operation of the movable contactor A and the opposing contactor B over time during the contact opening operation as described above, immediately after the opposing contactor 5 starts the contact opening operation. By moving at a relatively large speed only in the initial stage and at a relatively low speed after opening, it is shown that the distance between contacts after opening is rapidly increased.

On the other hand, when the closing operation is started from the completion state of the opening operation as shown in FIG. 2 (c), the closing rod driving force from the driving device causes the operating rod 9 which is a direct connecting portion of the driving device. And the puffer cylinder 10 moves leftward in the drawing. In this case, the movable contactor 13 moves leftward in the figure together with the operation rod 9 and the puffer cylinder 10 while maintaining the protruding state by the urging force of the spring 12. On the other hand, the opposing contactor 5 is kept in a protruding state by the biasing force of the spring 6a.

Subsequently, as shown in FIG. 4 (a), the operating rod 9, the puffer cylinder 10, and the movable contactor 13 of the movable contactor portion A move to the left (indicated by the arrow) from the state in which the contact opening operation is completed. 21b), the movable contact 13 comes into contact with the opposing contact 5 when moved by the distance L _{o (e) in} FIG. When the operation rod 9 and the puffer cylinder 10 of the movable contactor portion A further move to the left in the figure from this state, the spring that biases the opposed contactor 5 more than the biasing force of the spring 12 that biases the movable contactor 13. Because the biasing force of 6b is smaller,
As the movable contact 13 moves, the spring 6b is pressed and compressed via the opposing contact 5, and the step 5c of the opposing contact 5 is formed.
The distance L ₃ between the end of the floating intermediate body 8 and the floating intermediate body 8 becomes smaller.
In FIG. 4B, the distance L ₃ becomes 0 due to the progress of the closing operation, so that the step 5c of the opposing contactor 5 and the end of the floating intermediate body 8 come into contact with each other, and It shows the engaged state.

In this way, from the time when the opposing contactor 5 and the floating intermediate body 8 are engaged, the movable contactor portion A is further added.
When the operating rod 9 and the puffer cylinder 10 of FIG. 6 further move to the left in the figure, the spring 6 that urges the floating intermediate body 8
Since the biasing force of the spring 12 that biases the movable contact 13 is smaller than the biasing force of a, the spring 12 presses the floating intermediate body 8, the opposing contactor 5, and the movable contactor 13. When compressed, the movable contactor 13 starts moving rightward in the figure in a pushed back form. FIG. 4C shows a state in which the spring 12 is compressed and the movable contact 13 is pushed back in this way. As shown in FIG. 4 (c), the distance L _2a between the end of the puffer cylinder 10 and the piston 13b of the movable contact 13 is increased with the progress of the closing operation.
Is increased, the partition portion 9 of the piston 13b and the operating rod 9 is increased.
The distance L _2b from a decreases. And this distance L _2b is 0
After the distance L ₂ shown in FIG. 1 is established between the piston 13a of the movable contact 13 and the end of the puffer cylinder 10, the spring 6a for urging the floating intermediate body 8 is finally compressed. 1, the closed state shown in FIG. 1 is established, and the distance L between the end of the floating intermediate body 8 and the end of the cylinder 7 shown in FIG.
_I can do one. In this case, the contact force between the contacts 5 and 13 is sufficiently increased by the spring 6a having a large biasing force, so that the contact state between the contacts 5 and 13 in the closed state can be improved. .

[1-3] Effects of the First Embodiment As described above, according to the present embodiment, since the movable contact 13 employs the wipe method, the contact opening between the contacts after the opening is completed. The distance can be increased quickly. Further, in this embodiment, the opposing contactor portion B is provided with springs 6a and 6b having different biasing forces and a floating intermediate body that transmits the biasing force of the spring 6a having a relatively large biasing force to the opposing contactor 5. Since the counter contact 5 is provided, the large biasing force of the spring 6a acts on the opposing contact 5 via the floating intermediate body 8 only immediately after the opening operation is started, and the contact with the movable contact 13 is maintained. Since only a small biasing force of the spring 6b acts, the advancing speed of the opposing contactor 5 becomes sufficiently slow.

Therefore, according to this embodiment, it is possible to rapidly increase the contact opening distance between the contacts 5 and 13 after opening, and as a result, the breakdown voltage between the contacts 5 and 13 can be quickly increased. Therefore, sufficient insulation performance can be obtained with respect to the high voltage applied immediately after the interruption, and the interruption performance can be improved. In addition, since the contact state is good when the electrodes are closed, it is possible to improve the energization performance.

[2] Second Embodiment [2-1] Configuration of Second Embodiment FIG. 5 is a diagram showing the configuration of a second embodiment of the circuit breaker according to the present invention, particularly showing the closed state. ing. In the opposing contactor B of this embodiment, a shield 5d is provided around the opposing contactor 5, and the main body side of the opposing contactor 5 and the shaft 5a and the step 5c side are separate members, and these are integrated. The other structure of the facing contact portion B is the same as that of the first embodiment.

On the other hand, in the movable contactor A of this embodiment, a large-diameter flange 13c is provided at the rear of the movable contactor 13, and the nozzle 14 is fixed to this flange 13c. A cylinder 19 that engages with the flange 13c is provided around the flange 13c, and the flange 13c slides on the inner diameter portion of the cylinder 19. Note that the piston 13b of the movable contact 13 and the partition 9a of the operating rod 9 are omitted in accordance with such a change in configuration. Further, the distance L ₂ is maintained between the flange 13c of the movable contactor 13 and the end of the cylinder 19 in the closed state. Further, similarly to the opposing contactor 5, the shield 20 is provided around the movable contactor 13. The other structure of the movable contact portion A is exactly the same as that of the first embodiment, and the relationship of the biasing forces of the three springs is also the same as that of the first embodiment.

[2-2] Operation of the Second Embodiment The operation of the present embodiment having the above-mentioned structure is as follows. First, in the closed state shown in FIG.
Similar to the embodiment, by the opening driving force from the driving device,
The operation rod 9 and the puffer cylinder 10, which are the drive unit direct connection portions, start moving rightward in the drawing. In this case, the movable contact 13 is kept in contact with the opposing contact 5 by the urging force of the spring 12. Then, after the flange 13c of the movable contact 13 is engaged with the end of the cylinder 19, the movable contact 13 is opened in a manner of moving integrally with the operation rod 9 and the puffer cylinder 10 which are the drive device direct connection parts. Then, similarly to the first embodiment, the contact is released from the opposing contactor 5 with a certain speedup.

Immediately after the opening operation is started, the floating intermediate 8
The opposing contactor 5a that is in close contact with it moves forward integrally by the relatively large biasing force of the spring 6a, and moves forward from the opening position by a distance L ₁ . As a result, (a) of FIG.
When the floating intermediate body 8 and the cylinder 7 are engaged with each other and the floating intermediate body 8 stops as shown in FIG.
Due to the relatively small biasing force of the spring 6b, the movable contact 13
Move forward at a slower speed than (B) of the contact opening diagram
Shows the state in the middle of such opening operation.

Therefore, also in the present embodiment, the opening distance between the movable contact 13 and the opposed contact 5 can be rapidly increased, as in the first embodiment. The fact that the gas is compressed by the reduction of the space C in the puffer cylinder 10 and the gas flows 22a and 22b are generated to achieve the interruption is the same as in the first embodiment.

[2-3] Effects of the Second Embodiment As described above, according to the present embodiment, the opening distance between the contacts 5 and 13 after opening is the same as in the first embodiment. Can be rapidly increased, and as a result, the breakdown voltage between the contacts 5 and 13 can be quickly increased, so that sufficient insulation performance can be obtained against the high voltage applied immediately after the interruption. The blocking performance can be improved. In addition, since the contact state is good when the electrodes are closed, it is possible to improve the energization performance.

[3] Third Embodiment [3-1] Configuration of the Third Embodiment FIG. 7 is a diagram showing the configuration of the third embodiment of the circuit breaker according to the present invention, particularly showing the closed state. ing. The structure of the facing contact portion B of this interruption device is exactly the same as that of the first embodiment. On the other hand, in the movable contactor portion A of this embodiment, the puffer cylinder 10 has the same structure as that of the first embodiment.
The gas blowing device including the puffer piston 11 and the insulating nozzle 14 is omitted. The present embodiment is suitable for a case where the breaking current is small and breaking is easy. The other structure of the movable contactor portion A in this embodiment is exactly the same as that of the first embodiment.

[3-2] Operation of the third embodiment Also in the present embodiment having the above-mentioned structure, as in the first embodiment, the contact opening between the movable contact 13 and the opposed contact 5 is opened. The distance can be increased quickly. In this embodiment, since there is no gas blowing device, a gas flow is not formed as in the first embodiment, but when the breaking current is small and breaking is easy, the opening distance is long. Good shutoff can be achieved by a rapid increase of

[3-3] Effects of Third Embodiment As described above, according to this embodiment, the breaking current is small,
If it is limited to the case where the breaking is easy, the opening distance between the contacts 5 and 13 after opening can be rapidly increased, as a result of the first embodiment, and as a result, the contacts 5 and 13 can be increased. Since the dielectric breakdown voltage between 13 can be rapidly increased, sufficient insulation performance can be obtained with respect to the high voltage applied immediately after the interruption, and the interruption performance can be improved. In addition, since the contact state is good when the electrodes are closed, it is possible to improve the energization performance. Furthermore, in the present embodiment, the configuration can be greatly simplified by omitting the gas spraying device, and the economy is excellent.

[4] Other Embodiments The present invention is not limited to the above embodiments, and the specific configurations of the movable contact portion and the opposing contact portion can be freely selected. . For example, the movable contactor in the movable contactor and the drive device direct coupling portion are engaged with each other, the opposed contactor in the opposed contactor portion is engaged with the floating intermediate body, and the floating intermediate body and the support portion are engaged with each other. The configuration can be freely designed.

[0045]

As described above, according to the present invention,
It is possible to quickly increase the contact opening distance between contacts after contact opening, has a good contact state when closing contacts, and has excellent breaking and energizing performance, making it suitable as a resistance breaker for a gas circuit breaker with resistance. Can be provided.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a configuration of a first embodiment of a blocking device according to the present invention.

2A and 2B are explanatory diagrams showing an opening operation of the circuit breaker of FIG. 1, where FIG. 2A is an initial state immediately after the opening operation is started, FIG. 2B is an intermediate state of the opening operation, and FIG. The end state of the pole action.

FIG. 3 is a characteristic diagram showing the operation of the movable contactor portion A and the opposing contactor portion B over time during the opening operation of the circuit breaker of FIG.

4A and 4B are explanatory views showing a closing operation of the breaking device of FIG. 1, where FIG. 4A is a contact state of both contacts, FIG. 4B is an engagement state of an opposing contact and a floating intermediate body, and FIG. ) Indicates a state in which the movable contactor has started to move backward with respect to the directly connected portion of the drive device.

FIG. 5 is a configuration diagram showing a configuration of a second embodiment of a blocking device according to the present invention.

6A and 6B are explanatory views showing an opening operation of the circuit breaker of FIG. 5, where FIG. 6A is an initial state immediately after the start of the opening operation, and FIG. 6B is an intermediate state of the opening operation.

FIG. 7 is a configuration diagram showing a configuration of a third embodiment of a blocking device according to the present invention.

8A and 8B are principle diagrams showing the operation of a general circuit breaker with a resistance, where FIG. 8A is a closed state, FIG. 8B is an open state of a main circuit breaker, and FIG. 8C is an open circuit state.

FIG. 9 is a configuration diagram showing an example of a configuration of a conventional resistance breaker for a gas circuit breaker with resistance.

[Explanation of symbols]

 A ... Movable contact part B ... Opposing contact part 5 ... Opposing contact part 5a ... Shaft 5b ... Piston 5c ... Step part 5d ... Shield 6a, 6b, 12 ... Spring 7 ... Cylinder 8 ... Floating intermediate body 9 ... Operation rod 9a ... Partition part 10 ... Puffer cylinder 11 ... Puffer piston 13 ... Movable contactor 13a ... Shaft 13b ... Piston 13c ... Flange 14 ... Insulation nozzle 15, 16a ... Energizing part 16 ... Support plate 17 ... Cylinder 18 ... Lid 19 ... Cylinder 20 ... shield

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Susumu Nishiwaki No. 2 Ukishimacho, Kawasaki-ku, Kawasaki-shi, Kanagawa Stock company Toshiba Hamakawasaki Factory

Claims (3)

[Claims] 1. A movable contact part, which is housed in a grounding container filled with an arc-extinguishing gas and is composed of a movable part including a movable contact and a supporting part thereof, and an opposed contact part including an opposed contact. The movable contactor and the facing contactor are arranged so as to be able to come into contact with and separate from each other, and a blocking section that performs a contact opening operation and a contact closing operation by movement of the movable section of the movable contactor section; In a shutoff device having a drive device that drives the movable part, a part of the movable part of the movable contactor part is configured as a drive device direct connection part that is directly connected to the drive device, and the movable contactor is the The drive device is not directly connected to the drive device and is movably supported by the drive device direct connection part, and the movable contactor part urges the movable contactor toward the opposite contactor side with respect to the drive device direct connection part. First
In the opening operation, the movable contact directly engages with the drive device direct connection part and then moves after the movable device direct connection part moves by a preset first set distance. The counter contact part is configured to start an opening operation, the counter contact part movably supports the counter contact, a floating intermediate body provided between the support part and the counter contact, and the support part. A second spring that urges the floating intermediate member toward the movable contactor side, and a third spring that urges the opposing contactor toward the movable intermediate member side with respect to the floating intermediate member. In the opening operation, the floating intermediate body and the facing contact move by the preset second set distance by the biasing force of the second spring, and then the floating intermediate body engages with the support portion. At the same time, the opposing contactor is moved to the movable contactor side by the urging force of the third spring. The urging force of the first, second and third springs is configured to move, and the urging force of the second spring> the urging force of the first spring> the urging force of the third spring. An interrupting device, comprising: 2. The movable contact has a flange on the drive device direct connection part side, the drive device direct connection part has a cylinder that engages with the flange, and the movable contact part has an opening contact. In operation, after the drive device direct connection portion moves by a preset first set distance, the flange of the movable contactor engages with the cylinder of the drive device direct connection part to move the electrode. The interrupting device of claim 1, wherein the interrupting device is configured to initiate operation. 3. The drive device direct connection portion includes a puffer cylinder having a gas outlet on the side of the movable contact, a puffer piston for compressing gas in the puffer cylinder, and a gas blown out from the gas outlet. It has a gas blowing device provided with a nozzle which guides between a contact child and a counter contact child, and said flange and said cylinder are arranged just before a gas outlet of said puffer cylinder, It is characterized by things. 2. The shutoff device according to 2.