KR20230127012A - Spring Mechanism of High Voltage Circuit Breaker - Google Patents

Abstract

The present invention relates to a spring operating mechanism of an ultra-high-voltage circuit breaker, and more particularly, to a spring operating mechanism of an ultra-high-voltage circuit breaker capable of adjusting a damping speed by adjusting the volume of a hydraulic oil space of a damping device.
The present invention has been made to solve the above problems, and its object is to provide a spring operating mechanism of an ultra-high voltage circuit breaker that adjusts the amount of damping in a method other than the method of adjusting the amount of hydraulic oil. In particular, it is to provide a spring operating mechanism of an ultra-high pressure circuit breaker capable of adjusting a damping speed by adjusting a volume control of a hydraulic oil space in a cylinder of a damping device.

Description

Spring Mechanism of High Voltage Circuit Breaker}

The present invention relates to a spring operating mechanism of an ultra-high voltage circuit breaker, and more particularly, to a spring operating mechanism of an ultra high voltage circuit breaker capable of adjusting a damping speed by adjusting the volume of a hydraulic oil space of a damping device.

In general, a high voltage gas circuit breaker or gas insulated switchgear is installed between the power side and the load side circuit of the power system to manually open or close the circuit for maintenance, etc. It is an electric device that protects the power system and load equipment by automatically cutting off the circuit when an abnormal current such as overload or short circuit occurs. The ultra-high voltage circuit breaker separates the electrodes by receiving the power transmitted from the actuator connected to the outside, and at this time, the arc generated between the contacts sprays gas such as SF6 to block and extinguish the arc. Gas insulated switchgear has the advantage of saving space compared to air circuit breakers.

The contacts (main contacts and arc contacts) of the extra-high voltage circuit breaker are operated by a hydraulic operating mechanism or a spring operating mechanism of a traditional mechanical operating method.

Among them, in the spring operating mechanism, two large-capacity operating mechanisms of a closing spring and an opening spring are provided. Normally, the closing spring is mechanically energized by an electric motor and supported in an energy-accumulated state by a latch. When the closing signal is input, the latch is released, and the closing spring drives the circuit breaker in the closing state, while accumulating energy in the opening spring. At this time, another latch secures the circuit breaker in the closed position. The closing spring is normally re-energized immediately after the closing operation.

In summary, the function of the closing spring is to provide mechanical energy to close the extra-high voltage circuit breaker (to close the contact) and to accumulate energy in the opening spring.

And, the function of the opening spring is to provide mechanical energy to open the contacts of the extra-high voltage circuit breaker.

On the other hand, in the open spring mechanism, a damping device (damper) is provided to prevent sudden collision between the open spring and other parts and excessive bounce of the circuit breaker moving part do. The speed of the opening spring or closing spring can be adjusted according to the set value (set amount) of the damping device, and as a result, the speed of the moving part of the extra-high voltage circuit breaker can be adjusted. This may also affect the performance of the extra-high voltage circuit breaker. When the set value of the damping device is decreased, the speed of the movable part is increased, and when the set value of the damping device is increased, the speed of the movable part is decreased. Here, in order to improve the performance of the extra-high voltage circuit breaker, it is not necessarily necessary to operate it at high speed. Engineers determine the best stroke curve (movement curve) of the contact part in order to optimize the performance of the extra-high voltage circuit breaker through experimental methods or simulations.

As such a damping device, ODP (Oil Dash Pot) is commonly used. In particular, since the opening speed is faster than the closing speed, the role of damping in the opening operation is important. In the case of a circuit breaker, it generally operates in the order of closing spring compression, closing operation, and opening operation after motor operation.

1 to 4 show a spring operating mechanism of an ultra-high voltage circuit breaker according to the prior art. 1 is an overall structural diagram of a high-capacity spring operating mechanism of an ultra-high voltage circuit breaker according to the prior art. The closing spring part is deleted, and only the opening spring operating mechanism and the operating part are shown. Figure 2 is a cutaway view of the opening spring operating mechanism in Figure 1; 3A to 3C are operational views of the opening spring operating mechanism. 4a and 4b show the movement of operating oil in FIGS. 3b and 3c, respectively.

An opening spring mechanism 10 and a closing spring (not shown) are installed on one side of the manipulator 1. The manipulator (1) includes a trip mechanism (2) and a main lever (3). The main lever 3 is connected to the damper movable rod 4, and the damper movable rod 4 is connected to the support plate 5 and the piston 6 that receive the force of the opening spring 7.

The opening spring 7 is inserted into the housing 14 fixed to the manipulator 1. One end of the opening spring 7 is supported on the end plate 15 of the housing 14, and the other end is supported on the support plate 5 receiving the force of the damper movable rod 4. A piston 6 is coupled to one side of the support plate 5, and a damper movable rod 4 is coupled to the other side. Thus, the piston 6 and the damper movable rod 4 move together with the support plate 5. When the main lever 3 rotates by the operation of the closing spring, the damper movable rod 4 moves in the direction of the end plate 15, so that the support plate 5 is pushed and the opening spring 7 is compressed and the elastic force is charged. .

In the spring operating mechanism of the ultra-high voltage circuit breaker according to the prior art, the power transmission process of the opening operation is as follows. Trip mechanism (2) -> Opening spring (7) -> Damper movable rod (4) (translational and rotational motion) -> Main lever (3) (rotational motion) -> Link (not shown) (rotational motion) - > Insulation rod (not shown) (translational motion and rotational motion) -> breaker contact part mover (not shown) (translational motion) in order.

That is, when the latch 2a of the trip mechanism 2 is released from the restraint by receiving the trip signal, the open spring 7 in the energy accumulation state pushes the support plate 5 by the restoring force and moves the damper movable rod 4 and the motion of the damper movable rod 4 rotates the main lever 3. At this time, a damping device is provided to adjust the operating speed of the opening spring 7 or the damper movable rod 4.

An oil tank 13 is inserted into the opening spring 7 in the housing 14, and hydraulic oil 9 is filled in the oil tank 13. Inside the oil tank 13, a cylinder 8 having an operating oil cavity 11 (piston hole) is inserted and installed, and in the cylinder 8, a piston 6 connected to the damper movable rod 4 ) is slidably installed. A plurality of orifices 12 are formed in a part of the cylinder 8. The hydraulic oil 9 may flow between the hydraulic oil hole 11 and the oil tank 13 through the orifice 12 .

As shown in FIGS. 3A to 4B , when the opening spring 7 operates, the piston 6 compresses the hydraulic oil 9 while moving in the cylinder 8 . Accordingly, a counterforce is generated in the hydraulic oil 9 . Initially, as the compression force increases, the repulsive force also increases. This is the principle of the damping device.

During the opening operation, the hydraulic oil hole 11 is a space compressed by the piston head 6a (the space on the right side of the piston head on the drawing) (B) and a space not being compressed (the space on the left side of the piston head on the drawing) (A) divided into During the opening action, as the piston 6 moves, space A expands and space B contracts. By the movement of the piston 6, the working oil moves from space B to space A via the orifice 12 and the space of the oil tank 13. At the beginning of compression, the repulsive force is large according to the resistance of the hydraulic oil 9, and at the end of the compression, the repulsive force decreases according to the discharge of the hydraulic oil 9. However, the operation properties of the hydraulic fluid and the speed of the piston accordingly may be set differently depending on other variables such as the arrangement of the orifice hole.

In the opening spring mechanism 10, in particular, the cylinder 8 and the oil tank 13, various seals 16 that prevent hydraulic oil from leaking, and an end cap that fixes the position of the cylinder 8 17) is called ODP.

In FIG. 1, hydraulic oil is filled inside the oil tank 13, and the amount of hydraulic oil is less than the internal volume of the ODP. Hydraulic oil can be filled in the initial assembly state or can be put in or taken out through the inlet connected to the oil tank.

3A to 3C show cross-sectional views of the opening spring operating mechanism during which the manipulator operates from a closed state to an open state. In the open state (FIG. 3c), the open spring 7 compresses and enters the input state. At this time, the piston 6 moves a predetermined distance toward the end plate 15 inside the ODP. As the piston 6 moves, it pushes the hydraulic oil, and the hydraulic oil escapes to the oil tank 13 through the orifice 12 of the cylinder 8, damping through the position and size of the orifice 12 of the cylinder 8 (Damping) determines the length or speed of action.

However, due to the manufacturing characteristics of the opening spring 7, a load deviation occurs for each spring, and the circuit breaker operated by the manipulator also has a different load for each circuit breaker. Therefore, even if the same cylinder 8 orifice 12 and the amount of hydraulic oil are provided, the load and damping amount are different for each opening spring operating mechanism.

For this reason, the damping amount of the manipulator is adjusted in a manner in which the operator adjusts the amount of oil in the characteristic measurement task after the assembly of the manipulator is completed. At this time, as shown in FIG. 1, it is possible to work when the manipulator is placed horizontally, but when the manipulator is erected vertically and assembled with a circuit breaker, access to the inlet is difficult and the work is impossible.

Therefore, a structure for adjusting the amount of damping of the manipulator through an additional method in addition to the method of adjusting the amount of working oil is required.

The present invention has been made to solve the above problems, and its object is to provide a spring operating mechanism of an ultra-high pressure circuit breaker that adjusts the amount of damping in a method other than the method of adjusting the amount of hydraulic oil. In particular, it is to provide a spring operating mechanism of an ultra-high pressure circuit breaker capable of adjusting a damping speed by adjusting a volume control of a hydraulic oil space in a cylinder of a damping device.

A spring operating mechanism of an ultra-high voltage circuit breaker according to an embodiment of the present invention includes an opening spring inserted into a housing; an oil tank inserted into the opening spring; a cylinder inserted into the oil tank and fixed to an end plate provided at a front end of the housing; A piston that is inserted into the cylinder and moves linearly; and an adjustment cap inserted into the front end of the cylinder and installed through the through hole of the end plate to adjust the internal volume of the cylinder.

Here, an adjustment cap coupling portion is formed on an inner circumferential surface of the front end of the cylinder, and a cylinder coupling portion coupled to the adjustment cap coupling portion is formed at the rear end of the adjustment cap.

In addition, the end plate is characterized in that a front protrusion protrudes from the front and a rear protrusion having a larger diameter than the front protrusion protrudes from the rear.

In addition, a hole is formed along the central axis of the end plate, and the hole is composed of a first hole formed in the front protrusion and a second hole formed in the rear protrusion with a larger diameter than the first hole. .

In addition, it is characterized in that a stepped portion is formed between the first hole and the second hole.

In addition, side holes are formed on both sides of the front protrusion, and a fixture for fixing the adjusting cap is inserted into the side holes.

In addition, the control cap is characterized in that it comprises a first part inserted into the second hole, and a second part inserted into the first hole.

In addition, the inner diameter of the cylinder and the inner diameter of the second hole of the rear protruding part are characterized in that they match each other.

In addition, the first portion of the adjusting cap may be disposed over the second hole of the end plate and the front portion of the cylinder.

In addition, the second part of the adjusting cap is characterized in that it is disposed across the first hole and the second hole of the end plate.

And, it is characterized in that the tool action portion is formed at the front end of the adjusting cap.

Here, a plurality of annular seals may be disposed between the second hole of the end plate and the adjusting cap to prevent leakage of hydraulic fluid and to reinforce the fixing force of the adjusting cap.

According to the spring operating mechanism of the ultra-high voltage circuit breaker according to an embodiment of the present invention, the damping speed may be adjusted by adjusting the volume of the hydraulic fluid space in the cylinder of the damping device using the adjusting cap.

Therefore, the damping amount of the damping device can be adjusted without adjusting the amount of oil injected into the oil tank.

Accordingly, it is possible to easily adjust the damping amount of the damping device even when it is difficult to access the oil injection port due to the installation of the unit of the ultra-high voltage circuit breaker.

In addition, since the characteristics of the damping device can be changed only by rotating the adjusting cap using a working tool, the amount of damping can be more easily adjusted than adjusting the amount of damping by adjusting the amount of oil.

1 is an overall structural diagram of a high-capacity spring operating mechanism of an ultra-high voltage circuit breaker according to the prior art. The closing spring part is deleted, and only the opening spring operating mechanism and the operating part are shown.
Figure 2 is a cutaway view of the opening spring operating mechanism in Figure 1;
3A to 3C are operational views of the opening spring operating mechanism. FIG. 3A is the input state, FIG. 3B is the opening progress state, and FIG. 3C is the opening completion state.
4a and 4b show the movement of operating oil in FIGS. 3b and 3c, respectively.
5 is a perspective view of a spring operating mechanism of an ultra-high voltage circuit breaker according to an embodiment of the present invention.
FIG. 6 is a perspective view in which a part of the control cap portion of FIG. 5 is separated.
7 is a cross-sectional view of a spring operating mechanism of an ultra-high voltage circuit breaker according to an embodiment of the present invention, showing an input state.
FIG. 8 shows a detailed view of part E in FIG. 7 .
9 is a cross-sectional view of a spring operating mechanism of an ultra-high voltage circuit breaker according to an embodiment of the present invention, showing an open state.
10 shows a state in which the internal volume of the cylinder is increased by moving the adjusting cap.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, this is to explain in detail enough for those skilled in the art to easily practice the invention, which means that the technical spirit and scope of the present invention are limited by these drawings. It is not.

The term "member" or "part" used to refer to a component in the present invention is not used for any limiting purpose, and may be omitted.

5 is a perspective view of a spring operating mechanism of an ultra-high voltage circuit breaker according to an embodiment of the present invention. FIG. 6 is a perspective view in which a part of the control cap portion of FIG. 5 is separated. 7 and 9 are cross-sectional views of the spring operating mechanism of the ultra-high voltage circuit breaker according to an embodiment of the present invention, respectively showing a closed state and an open state. A spring operating mechanism of an ultra-high voltage circuit breaker according to each embodiment of the present invention will be described in detail with reference to the drawings.

The spring operating mechanism 100 of the ultra-high voltage circuit breaker according to an embodiment of the present invention includes an opening spring 105 inserted into a housing 101; an oil tank 110 inserted into the opening spring 105; a cylinder 120 inserted into the oil tank 110 and fixed to an end plate 115 provided at a front end of the housing 101; A piston 130 that is inserted into the cylinder 120 and moves linearly; and an adjustment cap 140 inserted into the front end of the cylinder 120 and installed through the through hole 116 of the end plate 115 to adjust the internal volume of the cylinder 120.

5 and 6 are perspective views of the spring operating mechanism 100 of the ultra-high voltage circuit breaker. An end plate 115 is provided at the front end of the spring operating mechanism 100 of the ultra-high voltage circuit breaker to fix the housing 101, the oil tank 110, and the cylinder 120, and the spring operating mechanism 100 of the ultra-high voltage circuit breaker The rear end of ) is fixed to the support plate (flange) of the manipulator (not shown, see FIG. 1). To this end, a plurality of coupling parts 102 are protruded from the front and rear ends of the housing 101, respectively, and fastening screws 103 are provided at the coupling parts 102, respectively. Here, the part where the end plate 115 of the housing 101 is located is called the front end, and the part where the housing 101 is coupled to the manipulator is called the rear end. Further, the direction in which the end plate 115 of the housing 101 is located is referred to as the front end, and the direction in which the manipulator is located is referred to as the rear end.

The housing 101 may be formed in a cylindrical shape. The housing 101 is preferably made of a material with high rigidity. The housing 101 is fixed to the manipulator, supports each component inside the housing 101 and protects movement between the components.

Further reference is made to the cross-sectional view of FIG. 7 . An opening spring 105 is inserted into the housing 101. The opening spring 105 is disposed between a fixed support plate 150 fixedly installed at the front end of the housing 101 and a movable support plate 155 movably inserted and installed at the rear end of the housing 101.

Since the fixed support plate 150 at the front end of the housing 101 is fixed to the end plate 115, it does not move. Therefore, the front end of the opening spring 105 is supported by the fixed support plate 150 and fixed.

The movable support plate 155 at the rear end of the housing 101 is supported by the piston connecting member 165 fixing the piston 130 to the clevis 160. Meanwhile, the movable support plate 155 comes into contact with the rear end of the open spring 105 to receive elastic force. That is, the rear end of the open spring 105 in contact with the movable support plate 155 is compressed by the force of the movable support plate 155, or when the force is not applied, the charged elastic force acts to push and extend the movable support plate 155.

Since the piston 130 is connected to the damper movable rod 163 via the clevis 160, and the damper movable rod 163 is connected to the main lever (not shown, see FIG. 1) of the manipulator, In this case, the elastic force is stored by pushing the opening spring 105 toward the front end, and when the restraint of the manipulator is released, the elastic force of the opening spring 105 is restored while moving backward to open the circuit breaker.

The piston 130 is formed with a piston head 132 in close contact with the inner wall of the cylinder 120. By the movement of the piston head 132, the working oil 121 is pushed into space A or space B in the cylinder 120.

Inside the open spring 105 in the housing 101, an oil tank 110 is provided. The oil tank 110 is fixedly installed between the end plate 115 and the fixing part 180 . The oil tank 110 may be formed in a cylindrical shape. Hydraulic oil 121 is injected into the oil tank 110 . At this time, the hydraulic oil 121 should be injected smaller than the internal volume of the oil tank 110 . This is to enable the movement of the hydraulic oil 121 through the upper air layer.

An inlet hole 117 and an outlet hole 118 formed through the end plate 115 are connected to the rear end of the oil tank 110 . (See FIG. 7 or 8) Hydraulic oil 121 may be injected through the inlet hole 117, and a ventilation space is provided. Hydraulic oil 121 may be discharged through the outlet hole 118 . Stoppers 114 are inserted into the inlet hole 117 and the outlet hole 118, respectively.

A cylinder 120 is installed inside the oil tank 110. The front end of the cylinder 120 is fixed to the end plate 115, and the mounting part 122 provided at the rear end of the cylinder 120 is coupled to the fixing part 180. The rear end of the cylinder 120 is closed by the cylinder wall 123, but the front end of the cylinder 120 is open. However, a piston moving hole 124 is formed in the cylinder wall 123 so that the piston 130 is installed therethrough.

Inside the cylinder 120, a hydraulic oil space 125 (A+B) corresponding to a volume excluding the space into which the piston 130 is inserted is provided. The hydraulic oil space 125 is a value obtained by subtracting the volume of the piston 130 inserted into the cylinder 120 from the internal volume of the cylinder 120 . Here, the hydraulic oil space 125 is divided into a front space A formed in front of the piston head 132 and a rear space B formed in the rear of the piston head 132. In the open state as shown in FIG. 7, the front space (A) and the rear space (B) are each formed with a predetermined volume, and in the closed state as in FIG. 9, the front space (A) becomes the maximum value, and the rear space (B) is the minimum value. Here, the maximum value is equal to or less than the value obtained by subtracting the volume of the piston head 132 from the internal volume of the cylinder 120, and the minimum value is equal to or greater than zero.

A plurality of orifice holes 126 having various sizes are formed on the upper surface of the cylinder 120 . The hydraulic oil 121 may circulate between the hydraulic oil space 125 and the oil tank 110 through the orifice hole 126 .

In a normal state, the lower part of the oil tank 110 is filled with oil (hydraulic oil), the upper part of the oil tank 110 has a layer of oil to some extent, and the upper part forms an air layer without oil. (See FIGS. 7 to 9)

An adjusting cap coupling part 128 is formed on the inner circumferential surface of the front end of the cylinder 120 . The adjusting cap coupling part 128 may be formed as a screw thread.

A front protrusion 113 protrudes forward from the end plate 115 and a rear protrusion 112 protrudes rearward. The rear protrusion 112 has a larger diameter than the front protrusion 113. This is to correspond to the shape of the adjusting cap 140 formed with a step, and also to set a movement limit of the adjusting cap 140.

Both the front protrusion 113 and the rear protrusion 112 are formed in a tubular shape. That is, holes are formed along the central axis. Here, the second hole 112a of the rear protrusion 112 is formed larger than the first hole 113a in the front protrusion 113, so that the stepped portion 111 is provided. The stepped portion 111 serves as a surface limiting the movement of the adjusting cap 140 .

Side holes 113b are formed on both sides of the front protrusion 113, respectively. A fixture 145 for fixing the adjusting cap 140 to the end plate 115 is coupled to the side hole 113b. The fixture 145 may be composed of a nutless bolt or the like.

An adjusting cap 140 is provided. The adjustment cap 140 is formed in two stages so that it can be inserted into the first hole 113a of the front protrusion 113 and the second hole 112a of the rear protrusion 112 . This will be divided into a first part 141 and a second part 142 of the adjusting cap 140 . Here, the first part 141 is a part inserted into the second hole 112a of the rear protrusion 112, and the second part 142 is a part inserted into the first hole 113a in the front protrusion 113. am.

The first portion 141 of the adjusting cap 140 is disposed over the second hole 112a of the end plate 115 and the front portion of the cylinder 120 . At this time, the inner diameter of the cylinder 120 and the inner diameter of the second hole 112a of the rear protrusion 112 coincide with each other.

The second part 142 of the adjusting cap 140 is disposed over the first hole 113a and the second hole 112a of the end plate 115 . In some cases, the second part 142 of the adjusting cap 140 may extend to the outside of the end plate 115 .

A cylinder coupling part 144 is formed on the first part 141 of the adjusting cap 140 . Cylinder coupling part 144 may be formed as a screw thread. In this case, the adjusting cap 140 is movable along the longitudinal axis of the cylinder 120 in a screwed manner to the cylinder 120 .

A tool action portion 143 is formed at the front end of the adjusting cap 140 . A worker may move the adjusting cap 140 along the longitudinal axis direction of the cylinder 120 by rotating the tool action part 143 using a working tool such as a wrench. Accordingly, the inner volume of the cylinder 120 or the hydraulic fluid space 125 is expanded or reduced.

Between the second hole 112a of the end plate 115 and the adjusting cap 140, a plurality of annular seals 119 are disposed to prevent oil leakage of the hydraulic oil 121 and to enhance the fixing force of the adjusting cap 140. .

An operation of the adjusting cap 140 in the spring operating mechanism 100 of the ultra-high voltage circuit breaker according to an embodiment of the present invention will be described with additional reference to FIG. 10 .

An operator may rotate the tool action portion 143 of the adjusting cap 140 to move the adjusting cap 140 along the longitudinal axis of the cylinder 120 . FIG. 10 shows a state in which the adjusting cap 140 is moved in the shear direction to a position where it touches the stepped portion 111 . As a result, the internal volume of the cylinder 120, that is, the hydraulic oil space 125 is increased to the maximum. In this case, the resistance of the hydraulic oil 121 decreases during the opening action, so the moving speed of the opening spring 105 increases and the time to reach the open state decreases.

Conversely, if the operator moves the adjusting cap 140 backward along the longitudinal axis of the cylinder 120 by rotating the tool action part 143 in the opposite direction, the internal volume of the cylinder 120, that is, the hydraulic oil space 125 is reduced. will be. In this case, the resistance of the hydraulic fluid 121 increases during the opening action, so the moving speed of the opening spring 105 decreases and the time to reach the open state increases.

As described above, in the present invention, the damping amount (damping length, damping speed, etc.) can be adjusted by adjusting the internal volume of the cylinder 120 by moving the adjusting cap 140 .

According to the spring operating mechanism of the ultra-high voltage circuit breaker according to an embodiment of the present invention, the damping speed may be adjusted by adjusting the volume of the hydraulic fluid space in the cylinder of the damping device using the adjusting cap.

Therefore, the damping amount of the damping device can be adjusted without adjusting the amount of oil injected into the oil tank.

Accordingly, even when it is difficult to access the oil injection port due to the installation of the unit of the ultra-high voltage circuit breaker, it is possible to easily adjust the damping amount of the damping device.

In addition, since the characteristics of the damping device can be changed only by rotating the adjusting cap using a working tool, the amount of damping can be more easily adjusted than adjusting the amount of damping by adjusting the amount of oil.

The embodiments described above are examples of the best practice for implementing the present invention, and those skilled in the art can make various modifications and modifications without departing from the essential characteristics of the present invention. transformation will be possible. Therefore, these embodiments are only intended to explain and not to limit the technical idea of the present invention. Therefore, it should be understood that the scope of the technical idea of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100 Spring operating mechanism of extra-high voltage circuit breaker
101 housing
102 joint
103 fastening screw
105 open spring
110 oil tank
111 stepped part
112 rear projection
112a second hall
113 front overhang
113a 1st Hall
114 Stopper
115 end plate
116 through hole
117 inlet hole
118 outlet hole
120 cylinder
121 hydraulic oil
122 Mounting part
123 cylinder wall
124 Piston moving hole
125 oil space
126 orifice hole
128 adjustable cap joint
130 piston
132 piston head
140 adjustable cap
141 first part
142 second part
143 tool action
144 cylinder joint
150 fixed support plate
155 moving support plate
160 Clevis
163 damper moving rod
165 Piston connecting member
180 fixed part

Claims (12)

Opening spring inserted into the housing
an oil tank inserted into the opening spring;
a cylinder inserted into the oil tank and fixed to an end plate provided at a front end of the housing;
A piston that is inserted into the cylinder and moves linearly; and
An adjustment cap inserted into the front end of the cylinder and installed through the through hole of the end plate to adjust the internal volume of the cylinder; The spring operation of the ultra-high voltage circuit breaker according to claim 1, wherein an adjustment cap coupling part is formed on an inner circumferential surface of the front end of the cylinder, and a cylinder coupling part coupled to the adjustment cap coupling part is formed at the rear end of the adjustment cap. machine. [3] The spring operating mechanism of an ultra-high voltage circuit breaker according to claim 2, wherein the end plate has a front protruding portion protruding forward and a rear protruding portion having a larger diameter than the front protruding portion protruding rearward. 4. The method of claim 3 , wherein a hole is formed along a central axis of the end plate, and the hole is composed of a first hole formed in the front protrusion and a second hole formed in the rear protrusion with a larger diameter than the first hole. A spring operating mechanism of an extra-high voltage circuit breaker, characterized in that. [5] The spring operating mechanism of an ultra-high voltage circuit breaker according to claim 4, wherein a stepped portion is formed between the first hole and the second hole. The spring operating mechanism of an ultra-high voltage circuit breaker according to claim 3, wherein side holes are formed on both sides of the front protrusion, and a fixture for fixing the adjusting cap is inserted into the side holes. The spring operating mechanism of an extra-high voltage circuit breaker according to claim 4, wherein the adjustment cap includes a first part inserted into the second hole and a second part inserted into the first hole. [8] The spring operating mechanism of an extra-high voltage circuit breaker according to claim 7, wherein an inner diameter of the cylinder and an inner diameter of the second hole of the rear protrusion coincide with each other. The spring operating mechanism of claim 8, wherein the first portion of the adjustment cap is disposed over the second hole of the end plate and the front portion of the cylinder. 10. The spring operating mechanism of an ultra-high voltage circuit breaker according to claim 9, wherein the second part of the adjusting cap is disposed across the first hole and the second hole of the end plate. The spring operating mechanism of an ultra-high voltage circuit breaker according to claim 1, wherein a tool action portion is formed at a front end of the adjustment cap. The spring operation of the ultra-high voltage circuit breaker according to claim 4, characterized in that a plurality of annular seals are disposed between the second hole of the end plate and the adjusting cap to prevent oil leakage and to reinforce the fixing force of the adjusting cap. machine.

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