KR20090113070A - Switching drive device for extra high voltage circuit breaker - Google Patents

Abstract

PURPOSE: A switching drive device for extra high voltage circuit breaker is provided to mechanically and reliably maintain the force reduction state by fixing the input lever. CONSTITUTION: The first variable pulley(1) has the sheave. An input spring(7) provides the acoustic energy for the input drive of the hyper voltage cut-off device. A trip spring(10) provides the acoustic energy for the trip drive of the hyper voltage cut-off device. The second power transmission structures(4,8,9) are installed to drive and connect the trip spring and the second variable pulley(2). The first power transmission structures(5,6) are installed to drive and connect the input spring and the second variable pulley.

Description

Switching and driving device of high voltage breaker {SWITCHING DRIVE DEVICE FOR EXTRA HIGH VOLTAGE CIRCUIT BREAKER}

The present invention relates to an ultra high voltage breaker (EXTRA HIGH VOLTAGE CIRCUIT BREAKER), in particular, the spring (CHARGING in English) of the spring (CHARGING) is fast and efficient, and after the completion of the storage, the stored elastic energy prevails ( The present invention relates to an opening and closing device of an ultra-high voltage circuit breaker that can be mechanically restrained so as not to be discharging.

Ultra-high voltage generally means a high voltage corresponding to 200 to 800 kilo volts, and a typical example is a voltage transmitted by a transmission tower, and an ultra-high voltage circuit breaker is installed in a substation or the like to supply or cut off such ultra high voltage power. Circuit breaker). In such an ultra-high voltage breaker, the opening and closing drive device is a device that provides a driving force for opening and closing the circuit.

The ultra high voltage breaker basically has the function to automatically detect when a system accident such as a short circuit accident occurs and to shut off the system, and to extinguish the arc generated at the time of interruption to protect the system and the power equipment.

In order to provide a large driving force to temporarily shut off the system in the event of an accident, the opening / closing drive device of the ultra-high voltage circuit breaker utilizes a large capacity spring and elastic energy stored in the spring. These springs include closing springs that can provide or compress elastic energy to drive the ultra-high voltage breaker to the energized position for energizing the system, and drive the ultra-high voltage breaker to the disconnected position to shut off the system. There is a blocking spring (also known as a trip spring) that provides or compresses the elastic energy for preventing, and the blocking spring is connected to the closing spring.

The input spring is a reduction gear composed of a plurality of gears on the output shaft of the motor in order to convert the small torque output of the motor into a large torque and to accumulate a large spring by converting the small torque output of the motor into a large torque. Is connected to the installation.

An object of the present invention is to provide an opening and closing drive device of the ultra-high pressure breaker in the opening and closing drive device of the ultra-high pressure breaker, which can be made quickly and efficiently the elastic energy storage for the closing spring.

Another object of the present invention is to provide an opening / closing drive device for an ultra-high voltage circuit breaker, which can be restrained to mechanically and reliably maintain a state of washing after the elastic energy storage of the closing spring is completed.

Still another object of the present invention is to provide an opening / closing drive device for an ultra-high voltage circuit breaker, which can completely block the driving force for the storage after the completion of elastic energy storage of the closing spring.

The object of the present invention, in the opening and closing drive device of the ultra-high voltage circuit breaker,

A first variable pulley (PULLEY) having a pair of sheaves connected to an electric motor, rotatably driven and rotatably installed, and provided with a pair of facing distances and having a variable separation distance therebetween;

A second variable pulley having a pair of sheaves which are rotatable by power from the first variable pulley and are installed to face each other and have a variable distance from each other;

A pair of the first variable pulley and the second variable pulley rotatably installed between the first variable pulley and the second variable pulley so as to transfer power from the first variable pulley to the second variable pulley. A belt (BELT) whose radius of rotation on each of the first variable pulley and the second variable pulley changes as the wheel spacing distance of the variable varies;

An input spring for providing elastic energy for driving the input of the ultra-high voltage circuit breaker;

A first power transmission mechanism installed to drive connection between the input spring and the second variable pulley;

A trip spring providing elastic energy for trip driving of the ultra-high voltage breaker; And

It can be achieved by providing an opening and closing drive device of the ultra-high voltage circuit breaker according to the invention, characterized in that it comprises a second power transmission mechanism is installed to drive connection between the trip spring and the second variable pulley.

According to the present invention, by using a variable pulley and a belt whose contact radius is changed by the variable pulley, it is possible to obtain an opening / closing drive device of an ultra-high voltage circuit breaker, which can efficiently and quickly perform elastic energy storage for an input spring.

According to the present invention, by closing the throw lever by the closing ratchet after the completion of the elastic energy storing of the closing spring, the opening and closing device of the ultra-high voltage circuit breaker which can be restrained to be mechanically and reliably maintained is kept. .

According to the present invention, after completion of the elastic energy storage of the closing spring, the belt is brought into contact with the bearing of the first variable pulley connected through the driving circle and the rotating shaft to separate the belt from the driving circle, thereby driving the driving force for the closing after the closing of the closing spring. It is possible to obtain an opening and closing device of an ultra-high voltage circuit breaker that can be completely blocked to prevent damage or damage caused by the load of the closing ratchet due to the continuous load of the driving force after the completion of the washing.

The object of the present invention and the constitution and effects of the present invention to achieve the same will be more clearly understood by the following description of the preferred embodiment of the present invention with reference to the accompanying drawings.

First, showing the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention and the operating state diagram showing the overall configuration showing the operating state when the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention Referring to Figure 1 will be described the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention.

As shown in FIG. 1, the opening and closing device of the ultrahigh voltage circuit breaker according to the embodiment of the present invention is largely divided into a first variable pulley (PULLEY) 1, a second variable pulley 2, and a belt 3. And the input spring 7, the first power transmission mechanisms 4, 5, 6, the trip spring 10, and the second power transmission mechanisms 4, 8, 9.

The first variable pulley 1 is connected to an electric motor (not shown) and is electrically driven and rotatable, and a pair of conical sheaves that are installed to face each other and have a variable distance from each other, that is, refer to FIG. 7. As can be seen, each has a conical fixed sheave 1a and a movable sheave 1b. More specifically, in FIG. 1, the fixed sheave 1a and the movable sheave 1b of the first variable pulley 1 are installed to rotate together with the first variable pulley rotation axis 1d on the rotation drive shaft 1d. The rotary drive shaft 1d is connected to the electric motor of the figure, and rotationally drives a pair of sheaves of the first variable pulley 1, that is, the fixed sheave 1a and the movable sheave 1b. Here, the axial movement of the movable sheave 1b can be made by a continuously known transmission (CONTINUOUS VARIABLE TRANSMISSION, also known as CVT), wherein the axial power of the movable sheave 1b is the hydraulic sheave 1b is hydraulic It can be obtained in connection with the piston of the cylinder and the operation of the hydraulic cylinder can be made by an electrical control device for controlling the hydraulic action direction. As is well known, the axial movement of the movable sheave 1b is also possible in other embodiments in which the movable sheave 1b is connected to a ball screw BALL SCREW connected to an electric motor, a reduction gear and a reduction gear.

The second variable pulley 2 is rotatable by the power from the first variable pulley 1 and is installed to face each other, and a pair of sheaves (SHEAVE) having a variable distance from each other, that is, refer to FIG. 7. As can be seen, the first variable pulley and the second variable pulley each have a pair of conical sheaves having a variable distance from each other, that is, a fixed sheave 2a and a movable sheave 2b which are conical. The fixed sheave 2a and the movable sheave 2b of the second variable pulley 2 are in contact with the belt 3 and rotate together with the second variable pulley rotation shaft 4 in accordance with the rotation of the belt 3. The axial movement of the movable sheave 2b on the second variable pulley rotational shaft 4 is similar to the first variable pulley 1 and is connected to the axial power or the motor provided by the hydraulic cylinder of the continuously variable transmission. By axial power provided by the screw.

The belt 3 is rotatably between the first variable pulley 1 and the second variable pulley 2 to transfer power from the first variable pulley 1 to the second variable pulley 2. Is installed. Further, the belt 3 has a contact radius contacting each of the first variable pulley and the second variable pulley as the separation distance between the pair of sheaves of the first variable pulley 1 and the second variable pulley 2 varies. Is changed. More specifically, when the separation distance between a pair of sheaves of the first variable pulley 1 and the second variable pulley 2 increases, between the belt 3 and the first variable pulley 1 and the second variable pulley 2 ) Decreases the contact radius between the pair of sheaves of the first variable pulley (1) and the second variable pulley (2), between the belt (3) and the first variable pulley (1); The contact radius between the second variable pulleys 2 increases. This increase in contact radius will increase the driving force transmitted through the belt 3 in contact with that contact radius. It is preferable that the belt 3 is a V-shaped belt, that is, a V belt.

The opening and closing device of the ultrahigh voltage circuit breaker according to the preferred embodiment of the present invention further includes a bearing 1c, and the bearing 1c is installed on the rotation drive shaft 1d as shown in FIG. The bearing 1c is provided on a pair of sheaves of the first variable pulley 1, that is, on the rotary drive shaft 1d between the fixed sheave 1a and the movable sheave 1b. When the pair of sheaves of the first variable pulley 1, i.e., the distance between the fixed sheave 1a and the movable sheave 1b, is the longest, the bearing 1c supports the belt 3 to rotate from the electric motor. It serves to block the transmission of the old power to the belt (3).

The closing spring 7 provides elastic energy for the closing drive of the ultra-high pressure breaker. The dosing spring 7 consists of a tension spring that stores the elastic energy when it is tensioned in practice. In other words, by using the elastic energy provided by the input spring 7 (prediction), the unshown movable contact of the power transmission mechanism of the figure shown in the figure connected to the input spring 7 and the said ultra-high voltage | voltage breaker connected to this power transfer mechanism. In contact with the stationary contact, a closed circuit is formed, and thus, a closed state is established so that the current of the power system can be energized.

The first power transmission mechanisms 4, 5, 6 are provided to drive connection between the input spring 7 and the second variable pulley 2. The first power transmission mechanism 4, 5, 6 includes a second variable pulley rotary shaft 4, an input lever LEVER 5, and an input wire WIRE 6.

The input lever 5 is coaxially connected to the second variable pulley rotary shaft 4 and rotatable together in accordance with the rotation of the second variable pulley 2 and the second variable pulley rotary shaft 4. The closing lever 5 is a closing lever 5 by the closing latch 11 at a position in contact with the wire supporting part 5b to which the following closing wire 6 is connected, and the closing latch 11 described later. It has a latching action portion 5a for receiving a restriction to stop the rotation. The ratchet action portion 5a and the wire support portion 5b may be constituted by an extension portion which is integrally formed with the injection lever 5 and connected to the injection lever 5 by welding or may be connected to the injection lever 5 such as bolts and nuts. It can be fixedly connected to the input lever 5 by the fixing means. In particular, the wire support portion 5b may be provided with a through hole for fixing the input wire 6, where the input wire 6 is extended through the through hole and then fixed, for example, an anchor bolt. It can be fixed to the wire support 5b by means.

The input wire 6 is a wire which can be manufactured by twisting a plurality of wires made of a metal material such as steel in multiple layers so as not to be disconnected from the input spring 7 even when a large elastic energy is imposed upon the blocking / injection operation for several thousand times. , Between the input lever 5 and the input spring 7.

In order to maintain the tension of the feeding wire 6, a wire tension holding sheave 6a installed at a predetermined position between the feeding lever 5 and the feeding spring 7 to guide the feeding wire 6 is provided in the present invention. It can be configured to be included in addition to the opening and closing device of the ultra-high voltage circuit breaker according to.

The trip spring 10 provides elastic energy for tripping the ultra-high voltage breaker. The trip spring 10 consists of a compression spring that stores elastic energy when the compression is anticipated to occur. Accordingly, by using the elastic energy provided by the trip spring 10 (preventing), the power transmission mechanism of the figure not shown connected to the trip spring 10 and the above-mentioned high voltage circuit breaker connected to the power transmission mechanism are not shown. The movable contact is separated from the fixed contact, so that a circuit between the power supply side and the load side of the power system is opened, and thus the circuit is cut off so that current cannot be supplied to the circuit of the power system.

The second power transmission mechanisms 4, 8, and 9 are provided to drive connection between the trip spring 10 and the second variable pulley 2. The second power transmission mechanism 4, 8, 9 comprises a second variable pulley rotation shaft 4, a cam CAM 8 and a shutoff lever 9.

The second variable pulley rotation shaft 4 is a rotation shaft of the second variable pulley 2 connected to rotate together with the second variable pulley 2, and an input lever of the first power transmission mechanisms 4, 5, 6. It is also a rotation drive shaft for rotating (5).

The cam 8 is coaxially connected to the second variable pulley rotary shaft 4 and is rotatable together in accordance with the rotation of the second variable pulley 2 and the second variable pulley rotary shaft 4.

The blocking lever 9 is pressurized and rotatable by the cam 8 which is located within the rotation radius of the cam 8 and rotates. The blocking lever 9 is connected at one end to the trip spring 10, and the other end is a free end.

In addition, according to a preferred embodiment of the present invention, the opening and closing device of the ultra-high voltage circuit breaker of the present invention is installed at a predetermined position on the rotation path of the input lever 5 so that the input spring 7 is maintained in an expanded state. An additional latch (RATCHET) 11 for restraining (5) is configured.

In addition, according to a preferred embodiment of the present invention, the opening and closing device of the ultra-high voltage circuit breaker of the present invention is installed at a predetermined position on the rotation path of the blocking lever 9 so that the tripping spring 10 is kept in an extended state. And a blocking latch 12 for restraining 9).

The closing ratchet 11 and the blocking ratchet 12 may be manually operated or electrically operated to release the restraint. That is, when configured to be operated manually, the closing ratchet 11 or the blocking by the ON button or OFF button (OFF BUTTON) and the power transmission mechanism connected to these buttons by the user to press and operate The ratchet 12 may be driven to rotate to release the restraint of the input lever 5 or the blocking lever 9. In addition, when it is configured to be operated by electric power, the ON button or OFF button (OFF button) of the city which the user presses and operates is connected to the electric / stop control unit of the electric motor, and the rotational power of the electric motor is controlled by the power transmission mechanism. It may be configured to release the restraint of the input lever 5 or the blocking lever 9 by rotationally driving the closing ratchet 11 or the blocking ratchet 12.

On the other hand, the operation of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention configured as described above with reference to Figures 1 to 7 as follows.

First, the closing spring reduction operation as shown in FIGS. 3 and 4 in the blocked state as shown in FIGS. 1 and 2 will be described.

Figure 1 is as described above, Figure 2 is an operating state road showing the contact radius state of the first and second variable pulley and the belt of the opening and closing drive device of the high voltage circuit breaker according to an embodiment of the present invention in the blocking state of FIG. 3 is a top view showing a side operation state and a bottom view showing a planar operation state, and FIG. 3 shows an overall configuration of an opening and closing device of an ultrahigh voltage circuit breaker according to an embodiment of the present invention. Figure 4 is an operation state diagram showing the overall configuration showing the state of the closing spring of the opening and closing drive device, Figure 4 is a first and second of the opening and closing driving device of the ultra-high voltage circuit breaker according to an embodiment of the present invention in the closing spring of the closing state of Figure 3 2 is an operational state diagram showing the contact radius of the variable pulley and the belt. The top view is a side view and the bottom view is a plan view. .

In the shut-off state, the opening and closing device of the ultrahigh voltage circuit breaker according to the embodiment of the present invention has a maximum contact radius between the first variable pulley 1 and the belt 3 and the second variable pulley 2 as shown in FIG. 2. The contact radius of the belt 2 is in a minimum state. In this state, the movable sheave 1b of the first variable pulley 1 is driven by the power from the axial drive circle (hydraulic cylinder or electric motor of the continuously variable transmission) as shown in the right figure of FIG. This can be done by moving on the rotary drive shaft 1d to approach a predetermined position toward the side. At the same time, the movable sheave 2b of the second variable pulley 2 is driven by the power from the axial drive circle (hydraulic cylinder or electric motor of the continuously variable transmission) as shown in the left figure of FIG. It can be made by moving on the rotation drive shaft 1d to move to a predetermined position away from. In this state, when the rotation drive shaft 1d is driven to rotate clockwise in the state shown in FIG. 1 by the rotational power from the electric motor (not shown), the belt 3 that contacts the first variable pulley 1 also rotates clockwise. Thus, the second variable pulley 2 and the second variable pulley rotation shaft 4 which contact the belt 3 rotate clockwise. At this time, since the contact radius of the belt 3 in contact with the first variable pulley 1 is the maximum, the torque is maximized, and the contact radius of the belt 3 in contact with the second variable pulley 2 has a minimum value. In this state, the rotational speeds of the second variable pulley 2 and the second variable pulley rotation shaft 4 are raised to the maximum in a state where the reduction ratio is minimum. Therefore, the input lever 5, which is installed on the second variable pulley rotation shaft 4, rotates clockwise quickly and rotates about 180 degrees from the 6 o'clock direction of FIG. 1 to the 12 o'clock direction of FIG. 2. As the input wire 6 connected to one end of the input lever 5 is pulled, the input spring 7 connected to the other end of the input wire 6 is tensioned to elasticize the elastic energy. At this time, as the elastic energy stored in the closing spring 7 increases, the torque required for storing such elastic energy also increases, so that the interval between the fixed sheave 2a and the movable sheave 2b of the second variable pulley 2 increases as the accumulation thereof proceeds. As shown in the right figure of FIG. 7, the contact radius of the belt 3 is increased so that the distance (width) between the fixed sheave 1a and the movable sheave 1b of the first variable pulley 1 is increased. As shown in the left figure of Fig. 7, the contact radius decreases automatically so that the belt 3 as shown in Figs. 3 and 4 is brought into contact with the bearing 1c, and thus the power from the electric motor is not shown. Transfer to the belt 3 is stopped. The state where the closing spring 7 accumulates elastic energy in this way can be maintained by the ratchet action portion 5a of the throttling lever 5 being braked (restrained) by the closing ratt 11. As described above, the opening and closing drive device of the ultra-high pressure circuit breaker according to the embodiment of the present invention is in a state in which the belt 3 is in contact with the bearing 1c when the injection spring 7 has undergone elastic energy accumulation. Since the transmission is stopped, a phenomenon in which the closing ratchet 11 is damaged or broken under excessive load due to the continuous power transmission can be prevented.

On the other hand, the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention performs the charging operation by precipitating the elastic energy from the urgent state of the closing spring as described above and with reference to FIG. The process of making an enlarged time is demonstrated with reference to FIGS.

Figure 5 shows the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention and the overall configuration showing the state of the closing operation of the closing spring of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention. 6 is an operation state diagram showing a contact radius state of the first and second variable pulleys and the belt of the opening and closing driving device of the high voltage circuit breaker according to the embodiment of the present invention in the closing operation state of FIG. The top view is a side operation state diagram and the bottom view is a planar operation state diagram, Figure 7 is a belt contacting the variable pulley in accordance with the position change of the first or second variable pulley of the opening and closing device of the high voltage circuit breaker according to the present invention. The operation explanatory diagram showing the change in the contact radius of the left side shows the state in which the contact radius is minimized and the right side the contact radius A view showing the increased state as it becomes available.

In the elastic energy storage state of the input spring 7 as shown in FIG. 3, as described above, the input latch 11 is driven by electric or manual operation to rotate the input lever 5 so that the ratchet action portion ( When releasing 5a), the input spring 7 disposes the stored elastic energy so that the input wire 6 connected at one end to the input spring 7 is pulled and accordingly the input wire 6 The input lever 5 having the wire supporting portion 5b connected to the other end of the rotating lever rotates about 180 degrees clockwise from the state indicating the 12 o'clock direction shown in FIG. The cam 8, which is coaxially connected to the second variable pulley rotary shaft 4 and the second variable pulley rotary shaft 4, is also clockwise in accordance with the clockwise rotation of the input lever 5. Rotate 180 degrees

 The rotation of the clockwise about 180 degrees of the second variable pulley rotational shaft 4 acts to rotationally drive the movable contact of the figure not to contact the stationary contact via a power transmission mechanism not shown.

In addition, as the cam 8 rotates about 180 degrees in the clockwise direction, as shown in FIG. 3, the blocking lever 9 whose one end is in contact with the cam surface of the cam 8 is moved by the cam 8. The trip spring 10 connected to the other end of the blocking lever 9 by counterclockwise rotation of the blocking lever 9 is compressed as shown in FIG. For the elastic energy. The elastic energy storage state for the tripping operation of the trip spring 10 can be maintained by braking (restraining) by the blocking latch 12 provided with the blocking lever 9 at a preset position. At this time, the distance between the fixed sheave 2a and the movable sheave 2b of the second variable pulley 2 is widened so that the contact radius of the belt 3 is minimized as shown in the left side of FIGS. 6 and 7, and the first variable pulley The fixed sheave 1a and the movable sheave 1b of (1) become narrow like the right figure of FIG. 6 and FIG. 7, and the contact radius of the belt 3 becomes maximum, and a reduction ratio is minimum.

On the other hand, the operation of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention in the closing state as shown in Figure 5 will be described with reference to FIGS.

In the closing state as shown in Fig. 5, as described above, when the shutoff latch 12 is driven or rotated to be released to release the shutoff lever 9, the tripping spring was compressed to accumulate elastic energy ( As 10) stretches, the elastic energy is allowed to rest and the blocking lever 9 is rotated clockwise. When one end of the blocking lever 9, which rotates in a clockwise direction, comes into contact with the cam 8 to stop, the blocking operation is completed, and the state shown in FIG. At this time, the movable contact, which is connected to the shutoff lever 9 via a power transmission mechanism not shown, operates to be separated from the fixed contact according to the clockwise rotation of the shutoff lever 9.

Figure 1 shows the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention and the operating state showing the overall configuration showing the operating state when the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention Degree,

2 is an operating state diagram showing a contact radius state of the first and second variable pulleys and the belt of the opening and closing drive device of the high voltage circuit breaker according to the embodiment of the present invention in the blocking state of FIG. Bottom view is a plan view of the state of operation,

Figure 3 shows the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention and the operating state showing the overall configuration showing the state of the closing spring of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention Degrees,

4 is an operating state diagram showing a contact radius state of the first and second variable pulleys and the belt of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention in the closing spring state of FIG. And the lower figure is a planar operation state diagram,

Figure 5 shows the overall configuration of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention and the overall configuration showing the state of the closing operation of the closing spring of the opening and closing drive device of the ultra-high voltage circuit breaker according to the embodiment of the present invention The operation state diagram shown,

6 is an operating state diagram showing a contact radius state of the first and second variable pulleys and the belt of the opening and closing drive device of the ultra-high voltage circuit breaker according to an embodiment of the present invention in the closing operation state of FIG. And the lower figure is a planar operation state diagram,

7 is an operation explanatory diagram showing a change in the contact radius of the belt according to the position change of the variable pulley in the opening and closing drive device of the ultra-high voltage circuit breaker according to the present invention, the left side shows a state in which the contact radius is reduced to a minimum and the right side the contact radius It is a figure which shows this state to the maximum increase.

* Explanation of symbols on the main parts of the drawings

1: first variable pulley 1a: fixed sheave

1b: movable sheave 1c: bearing

1d: rotary drive shaft

2: second variable pulley 2a: fixed sheave

2b: movable sheave 3: belt

4: second variable pulley rotary shaft 5: injection lever

5a: ratchet action portion 5b: wire support portion

6: input wire 6a: wire tension sheave

7: closing spring 8: cam

9: blocking lever 10: trip spring

11: closing ratchet 12: shutoff ratchet

Claims (10)

In the opening and closing drive device of the high voltage circuit breaker, A first variable pulley (PULLEY) having a pair of sheaves connected to an electric motor, rotatably driven and rotatably installed, and provided with a pair of facing distances and having a variable separation distance therebetween; A second variable pulley rotatably driven by the power from the first variable pulley and having a pair of sheaves that are installed to face each other and have a variable distance from each other; A pair of the first variable pulley and the second variable pulley rotatably installed between the first variable pulley and the second variable pulley so as to transfer power from the first variable pulley to the second variable pulley. A belt BELT having a change in contact radius in contact with each of the first variable pulley and the second variable pulley as the spacing distance between the sheaves is varied; An input spring for providing elastic energy for driving the input of the ultra-high voltage circuit breaker; A first power transmission mechanism installed to drive connection between the input spring and the second variable pulley; A trip spring providing elastic energy for trip driving of the ultra-high voltage breaker; And And a second power transmission mechanism installed to drive connection between the trip spring and the second variable pulley. The method of claim 1, The first power transmission mechanism, A rotating shaft of the second variable pulley; An input lever LEVER coaxially connected to the rotary shaft and rotatable together with the rotation of the second variable pulley and the rotary shaft; And a closing wire (WIRE) connected between the closing lever and the closing spring. The method of claim 1, The second power transmission mechanism, A rotating shaft of the second variable pulley; A cam CAM coaxially connected to the rotary shaft and rotatable together in accordance with the rotation of the second variable pulley and the rotary shaft; And a shutoff lever positioned within a rotation radius of the cam and pressurized according to the rotation of the cam and connected at one end to the trip spring. The method of claim 1, The first variable pulley and the second variable pulley each have a pair of conical sheaves having a variable distance from each other, The belt is a V-shaped belt, characterized in that the opening and closing drive device of the high voltage circuit breaker. The method of claim 1, A rotation drive shaft connected to the electric motor to rotationally drive a pair of sheaves of the first variable pulley; A bearing installed on the rotation drive shaft and supporting the belt when the distance between the pair of sheaves of the first variable pulley is farthest to block the transmission of the rotation driving force from the electric motor to the belt; Opening and closing drive device of the ultra-high voltage circuit breaker, characterized in that comprising a. The method of claim 2, In order to maintain the tension of the input wire (WIRE) of the ultra-high voltage circuit breaker, characterized in that it further comprises a wire tension holding sheave installed in a predetermined position between the input lever and the input spring to guide the input wire Actuator. The method of claim 2, It is installed at a predetermined position on the rotational path of the closing lever is configured to further include an opening latch (RATCHET) for restraining the closing lever to keep the closing spring is in an extended state, characterized in that the opening and closing drive of the ultra-high voltage circuit breaker Device. The method of claim 3, And a blocking latch installed at a predetermined position on a rotation path of the blocking lever and restraining the blocking lever so as to maintain the trip spring in an extended state. In the opening and closing drive device of the ultra-high voltage circuit breaker to open and close the contact by using the elastic energy stored in the spring, An electric motor providing a rotational driving force; A belt for transmitting a rotational driving force of the electric motor; And Opening and closing of the ultra-high voltage circuit breaker, characterized in that it comprises a pair of variable pulleys having a pair of conical sheaves that can adjust the deceleration ratio of the belt rotation speed by widening or narrowing the distance between each other so that the contact radius with the belt changes. drive. The method of claim 9, wherein the variable pulley, In the initial stage of elastic energy storage, the gap between the sheaves of the variable pulley is widened to obtain a small deceleration ratio, and large force is required to accumulate elastic energy in the spring. In the late period of the elastic energy to be stored is a variable pulley of the variable pulley is narrowed the gap between the sheave of the variable pulley so as to obtain a large deceleration ratio.

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