KR20220037695A - Gas insulated circuit breaker and centering method thereof - Google Patents

Abstract

The present invention relates to a gas insulated circuit breaker configured to be centered and easily perform assembly and installation work, and a method for centering the same. The gas insulated circuit breaker comprises: a fixed part constituting an electric current path and having an arc contact at the fixed part; a movable part disposed to face the fixed part, having an arc contact at the movable part, and movable so that the arc contact at the movable part is connected to or separated from the arc contact at the fixed part; a first shape part formed at one end of the fixing part; and a second shape part disposed opposite to the first shape part at one end of the movable part. The first shape part and the second shape part may have a shape that the first and second shape parts correspond to each other to be molded.

Description

Gas insulated circuit breaker and centering method thereof

The present invention relates to a gas insulated circuit breaker that is configured to be able to center and can easily perform assembly and installation work, and a method for centering the same.

A gas insulated circuit breaker is a device that cuts off current in the event of an accident such as opening/closing a load or grounding or short circuit in a power transmission or substation system or an electric circuit. Such a gas insulated circuit breaker includes an insulating support installed in the tank, and a movable part and a fixed part supported by the insulating support, respectively, and having a main contact and an arc contact. The tank is filled with insulating gas and sealed.

Here, when an abnormal current is applied, the movable part moves and the arc contacts of the movable part and the fixed part are separated from each other and an arc is generated at the contact location. is extinguished and the abnormal current is cut off.

The gas insulated circuit breaker is important in breaking performance, so there are several conditions and variables to improve the breaking performance. For example, the center of the movable part and the fixed part, that is, the center between the arc contacts should be aligned. If the arc contacts of the movable part and the fixed part are not aligned with each other, the blocking operation may not be performed and the contacts may be easily damaged.

However, since the movable part and the fixed part are not substantially connected to each other, it is quite difficult to center the movable part and the fixed part. For this centering, it is necessary to use a separate tool such as a jig while assembling the movable part and the fixed part. The use of these tools is time consuming and the process is complex. Moreover, it is difficult or impossible to verify alignment between arc contacts during and/or after assembly, even with tools.

(Patent Document 1) JP 6045339 B2

Accordingly, an object of the present invention is to provide a gas insulated circuit breaker that is configured to be able to center and can easily perform assembly and installation work, and a method of centering the same.

A gas insulated circuit breaker according to the present invention comprises: a fixed part constituting an energization path and having a fixed-side arc contact; a movable part disposed to face the fixed part, having a movable arc contact, and movable so that the movable arc contact is connected to or separated from the fixed arc contact; a first shape formed at one end of the fixing part; and a second shape part disposed to face the first shape part at one end of the movable part, and the first shape part and the second shape part may have a shape corresponding to each other and mating.

The centering method of the gas insulated circuit breaker according to the present invention comprises the steps of installing a movable part on one side of a tank; at the other side of the tank, temporarily mounting an insulating support part of the fixing part to the flange of the tank; moving the movable part toward the fixing part as much as possible, and shape-fitting the first shape part of the fixing part to the second shape part of the movable part; and finally fixing the insulating support part of the fixing part to the flange in a state in which the first shape part of the fixing part and the second shape part of the movable part are shape-fitted.

As described above, according to the present invention, the centering between the fixed part and the movable part is automatically achieved by matching the first shape part and the second shape part to each other, so that assembly and installation work can be easily performed, and thus the circuit breaker is blocked As well as performance, durability may be improved.

1 to 3 are views sequentially illustrating a centering method of a gas insulated circuit breaker according to the present invention.
4 to 6 are enlarged views of part A of FIG. 2 , illustrating embodiments of the first shape part and the second shape part.
7 is a view showing the flange of the tank.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to components in each drawing, it should be noted that the same components are given the same reference numerals as possible even though they are indicated in different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 to 3 are views sequentially illustrating a centering method of a gas insulated circuit breaker according to the present invention.

1 to 3, the gas insulated circuit breaker according to the present invention is a fixed part (10). It may include a movable part 20 , a movable arc contact 21 , a fixed arc contact 11 , a first shape 30 , and a second shape 40 .

The fixing part 10 is a cylinder-shaped conductor having an internal space and through which a main current is passed, and may include a fixing part body 12 constituting the fixing part.

The fixing part main body 12 forms the outer shape of the fixing part 10, and the stationary-side arc contact 11 may be installed therein. The fixing unit body may be fixedly installed to the flange 50 of the tank (not shown) through the support by the insulating support 13 and at the same time as a medium.

The fixed-side arc contact 11 may have one end connected or disconnected from the movable arc contact 21 provided in the movable part 20, and constitutes a conduction path of the arc generated between the poles when the circuit breaker is closed and opened. can do.

The movable part 20 is a cylinder-shaped conductor having an internal space and through which a main current is passed, and the movable part body 22, a cylinder 23 moving inside the movable part body, and a cylinder rod connected to the cylinder and moving together with the cylinder (24), and may include a nozzle 25 installed at one end of the cylinder.

The movable part main body 22 forms the outer shape of the movable part 20 , and the cylinder 23 and the cylinder rod 24 may reciprocate therein. The movable part body may be fixedly installed on one side of the tank (not shown) through the insulating support part 26 .

When an abnormal current is applied and the circuit breaker is in an open state, the cylinder 23 moves backward in a direction away from the fixed part 10 inside the movable part main body 22 .

In the cylinder 23, a thermal expansion chamber 27 in which the high-temperature insulating gas generated between the poles is accommodated when the circuit breaker cuts off a large current, and when the circuit breaker cuts off a small current, the volume decreases in connection with the reverse operation of the cylinder and is stored inside. A puffer chamber 28 for supplying an insulating gas to the thermal expansion chamber may be provided.

The cylinder rod 24 is connected to the cylinder 23 and moves together with the cylinder. A movable arc contact 21 is provided at one end of the cylinder rod, and a driving unit 29 is connected to the other end.

The movable arc contact 21 may operate in accordance with the movement of the cylinder 23 and the cylinder rod 24 of the movable part 20 . The movable arc contact may be connected to or separated from one end of the fixed arc contact 11, and may constitute a path through which an arc generated between the poles flows when the circuit breaker is closed and opened.

The nozzle 25 may be installed at one end of the cylinder 23 . The nozzle is formed of an insulator and is fixed to surround the movable arc contact 21, so that it can operate in accordance with the movement of the movable part.

The nozzle 25 may constitute a path through which the gas flows between the thermal expansion chamber 27 and the poles (between the movable side and the stationary side arc contact). That is, the nozzle constitutes a path through which the insulating gas generated between the poles flows into the thermal expansion chamber, and constitutes a path through which the insulating gas of the thermal expansion chamber is injected into the poles.

The movable part 20 is disposed to face the fixed part 10 , and may be moved forward by the driving force of the driving unit 29 to contact the fixed part, or may be separated from the fixed part by moving backward. Thereby, the circuit breaker can perform a closing and opening operation.

When the movable part 20 is in contact with the fixed part 10 , the movable part together with the fixed part constitutes a conduction path of the main current.

In addition, the cylinder 23 of the movable part 20 may have a movable main contact point (not shown) at one end thereof, and similarly, it is fixed to one end of the fixing part body 12 constituting the fixing part 10 . A side main contact (not shown) may be provided. The main contact on the movable side and the main contact on the fixed side are connected or separated from each other so that the main current can be energized or cut off.

In this specification and drawings, the fixed-side arc contact 11 is described and illustrated as having a fixed position, but is not necessarily limited thereto. It can also operate in the direction opposite to the direction of movement.

The gas insulation circuit breaker according to the present invention includes a first shape part 30 formed at one end of the fixed part 10 and a second shape part (30) disposed to face the first shape part at one end of the movable part 20 ( 40), and the first shape portion and the second shape portion may have a shape corresponding to each other and mating.

4 to 6 are enlarged views of part A of FIG. 2 , illustrating embodiments of the first shape part 30 and the second shape part 40 .

For example, as shown in detail in FIG. 4 , the first shape part 30 has a stepped groove 31 formed to be stepped on the inner circumferential surface of the end of the fixing part 10 (specifically, the end of the fixing part body 12 ). ) may be included. The second shape portion 40 protrudes from the end of the movable part 20 (specifically, the end of the cylinder 23) and may include a protrusion 41 formed to have a shape to fit into the stepped groove of the first shape. there is.

For example, if the wall surface perpendicular to the axial direction of the fixing part 10 in the stepped groove 31 is a flat surface, the end surface of the protrusion 41 is formed as a flat surface, and if the wall surface in the stepped groove is a concave curved surface, the end surface of the projection may be formed as a convex curved surface. In addition, when the concave and convex portions are provided on the wall in the step groove, the opposite shape, that is, the embossed concavities and convexities, may be provided on the end surface of the protrusion.

Accordingly, the first shape 30 and the second shape 40 can be perfectly shaped to each other.

In addition, the profiles of the first shape part 30 and the second shape part 40 are not necessarily limited to the above-described examples and may be implemented with various modifications.

For example, as shown in FIG. 5 , the first shape 30 includes a protrusion 32 protruding from the end of the fixed part 10 , and the second shape 40 includes the movable part 20 . It may include a step portion 42 formed to be stepped on the outer peripheral surface of the end of the.

Alternatively, as shown in FIG. 6 , the first shape part 30 includes the insertion part 33 protruding from the end of the fixed part 10 , and the second shape part 40 is the movable part 20 . It may include a slit groove 43 formed to have a predetermined depth in the axial direction of the movable part at the end.

When the first shape part 30 and the second shape part 40 are shape-fitted and coupled to each other, the fixed part 10 and the movable part 20 are automatically centered, and the fixed side of the fixed part The arc contact 11 and the movable arc contact 21 of the movable part can be coaxially aligned with each other.

The profile of the first shape 30 and the second shape 40 for shape fitting ensures proper rigidity, and the fixed-side arc contact 11 and movable arc area that the operator cannot access or see. Makes the alignment between the side arc contacts 21 completely reliable.

In fact, according to the result of the tolerance calculation, the fixed-side arc contact 11 and the movable-side arc contact 21 are precisely coaxially aligned by the shape fitting of the first shape 30 and the second shape 40 . turned out to be possible.

Hereinafter, the centering method of the gas insulated circuit breaker according to the present invention will be described with reference to FIGS. 1 to 3 again.

As shown in FIG. 1 , first, the movable part 20 may be assembled and installed on one side of the tank. Specifically, the movable part body 22 , the cylinder 23 , the cylinder rod 24 , and the nozzle 25 may be combined to form a movable part.

The movable part main body 22 is fixed to one side of the tank via the insulating support part 26 . This fixing may be implemented by any mechanical fixing method such as welding or bolting.

A movable arc contact 21 is provided at one end of the cylinder rod 24 , and a driving unit 29 is connected to the other end thereof.

A fixed-side arc contact 11 is installed in the fixed part main body 12 , and the insulating support part 13 may be connected to the fixed part main body. Thereby, the fixing part 10 can be assembled and prepared.

As shown in FIG. 2 , on the other side of the tank, the insulating support 13 of the fixing part 10 may be temporarily mounted to the flange 50 of the tank.

Here, the flange 50 is a part of the tank and is an annular member extending radially inward from the inner circumferential surface of the tank. A plurality of screw holes 51 may be formed in the flange at equal intervals along the circumferential direction. Such a flange is shown in FIG. 7 .

In addition, the insulating support part 13 of the fixing part 10 is disposed at equal intervals along the circumferential direction at the end thereof, and a plurality of screw holes 14 having a predetermined depth in the axial direction of the insulating support part may be formed. .

Accordingly, when the insulating support part 13 of the fixing part 10 is mounted on the flange 50 of the tank, the insulating support part of the fixing part and the flange of the tank are connected by fastening using a fixing screw 52 on the opposite side of the insulating support part. can be combined

When the set screw 52 is fastened, the set screw is inserted only to a certain depth into each screw hole 14 in the insulating support 13 of the fixing part 10 without applying the full torque that causes the set screw to be fully fastened. Tighten by applying only a part of the total torque as much as possible.

As a result, the insulating support 13 of the fixed part 10 and the flange 50 of the tank are somewhat spaced apart from each other, so that the insulating support of the fixed part is able to move relatively relative to the flange of the tank.

In this case, it is preferable that the separation distance between the insulating support part of the fixing part and the flange of the tank is less than about 10 mm.

In this state, the movable part 20 may be moved toward the fixed part 10 as far as possible, and the first shape part 30 of the stationary part may be shape-fitted to the second shape part 40 of the movable part. At this time, the position of the movable part 20 is the same as the maximum forward position of the movable part movable toward the fixed part 10 by the driving force of the driving unit 29 .

Since the fixed part 10 can move slightly with respect to the flange 50 of the tank, the fixed part body 12 and the fixed-side arc contact 11 of the fixed part are movable with the cylinder 23 of the movable part 20 . Its position can be adjusted to be concentric with respect to the side arc contact 21 .

Accordingly, the fixed part 10 and the movable part 20 are centered and can be aligned concentrically with each other.

In this shaped and centered state, the insulating support 13 of the fixing portion 10 can be finally fixed to the flange 50 of the tank as shown in FIG. 3 .

By tightening by applying the full torque to be fully fastened to the set screw, the insulating support 13 of the fixing unit 10 can move by several mm toward the flange 50 of the tank.

In this case, the insulating support 13 of the fixing part 10 and the flange 50 of the tank may contact each other. In addition, the additional torque applied to each set screw and the depth at which each set screw is finally inserted into the screw hole 14 of the insulating support 13 may be different.

Accordingly, the position in the tank of the fixed part 10 may be fixed in a state in which it is centered with the movable part 20 .

Finally, the movable part 20 moves backward in a direction away from the fixed part 10 .

During normal operation of the circuit breaker, the first shape 30 of the fixed part 10 and the second shape 40 of the movable part 20 cannot be shaped again.

As described above, according to the present invention, the centering between the fixed part and the movable part is automatically achieved by matching the first shape part and the second shape part to each other, so that assembly and installation work can be easily performed, and thus the circuit breaker is blocked As well as performance, durability may be improved.

In addition, according to the present invention, there is no need for a separate tool such as a jig for centering, time and process can be shortened, and there is an effect that the alignment between arc contacts is reliable.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: fixed part 11: fixed side arc contact
12: fixing part main body 13: insulating support part
20: movable part 21: movable arc contact
22: movable part body 23: cylinder;
24: cylinder rod 25: nozzle
26: insulation support 27: thermal expansion chamber
28: fur persil 29: drive unit
30: first shape part 31: stepped groove
32: protrusion 33: insertion part
40: second shape 41: protrusion
42: step 43: slit groove
50: flange 51: screw hole
52: set screw

Claims (12)

a fixed part constituting an energization path and having a fixed-side arc contact;
a movable part disposed to face the fixed part, having a movable arc contact, and movable so that the movable arc contact is connected to or separated from the fixed arc contact;
a first shape formed at one end of the fixing part; and
a second shape disposed opposite to the first shape at one end of the movable part
including,
The first shape portion and the second shape portion are gas insulated circuit breaker having a shape to match each other.
According to claim 1,
The first shape includes a stepped groove formed to be stepped on the inner peripheral surface of the end of the fixing part,
The second shape portion protrudes from the end of the movable portion and includes a protrusion formed to have a shape to fit into the stepped groove of the first shape portion.
According to claim 1,
The first shape includes a protrusion protruding from the end of the fixing portion,
The second shape portion gas insulated circuit breaker including a stepped portion formed to be stepped on the outer peripheral surface of the end of the movable portion.
According to claim 1,
The first shape includes an insertion portion protruding from the end of the fixing portion,
The second shape portion includes a slit groove formed at an end of the movable portion to have a predetermined depth in the axial direction of the movable portion.
According to claim 1,
During normal operation of the gas insulated circuit breaker, the first shape of the fixed part and the second shape of the movable part do not conform to the shape of the gas insulated circuit breaker.
A method of centering the gas insulated circuit breaker according to any one of claims 1 to 5,
Installing the movable part on one side of the tank;
at the other side of the tank, temporarily mounting an insulating support connected to a fixing part to the flange of the tank;
moving the movable part toward the fixing part as much as possible, and shape-fitting the first shape of the fixing part to the second shape of the movable part; and
Finally fixing the insulating support portion of the fixing portion to the flange in a state in which the first shape portion of the fixing portion and the second shape portion of the movable portion are shape-fitted;
A method of centering a gas insulated circuit breaker comprising a.
7. The method of claim 6,
The flange is an annular member extending radially inward from the inner circumferential surface of the tank, and includes a plurality of screw holes formed at equal intervals along the circumferential direction,
The insulating support part of the fixing part includes a plurality of screw holes disposed at equal intervals along the circumferential direction and formed to have a predetermined depth in the axial direction of the insulating support part at the end,
The centering method of the gas insulated circuit breaker in which the insulating support part of the fixing part and the flange of the tank are coupled by a fixing screw.
8. The method of claim 7,
In the temporarily mounting step, the centering method of a gas insulated circuit breaker for fastening the set screw by applying only a portion of the torque to make the set screw fully fastened, rather than applying the entire torque.
9. The method of claim 8,
In the step of temporarily mounting, the separation distance between the insulating support part of the fixing part and the flange of the tank is less than 10 mm.
9. The method of claim 8,
In the shape fitting step, the position of the fixed portion is adjusted to be concentric with the movable portion.
11. The method of claim 10,
The final fixing step includes applying a full torque to the fixing screw and tightening it,
The centering method of the gas insulated circuit breaker in which the insulating support part of the fixing part moves toward the flange of the tank.
7. The method of claim 6,
After the final fixing step, the centering method of the gas insulated circuit breaker further comprising the step of moving the movable part in a direction away from the fixing part.

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