KR900002891B1 - Gas insulated switchgear - Google Patents

Abstract

A gas-insulated switch unit is enclosed in holders. Each face of the holder is provided with a flange for connection to the holders before and after it in the series, equipped with bolts round the circumference. The holder is a hollow casting for containing the insulating gas, with a bore so that the gas can pass along the series from holder to holder or through the branch outlets to other switches. Between the holders in the series, there are distance pieces, but also siphons or flexible connections. The distance pieces are of insulating material. Through the main bore of each holder, from switch to switch, also pass the bus-bars, carrying the current to the terminals of the switching device.

Description

Gas Insulated Switchgear

1 is a side view showing an embodiment of a gas insulated switchgear according to the present invention.

2 is a perspective view of the cylindrical body of FIG.

3 is an enlarged front view of the flange of the cylindrical body shown in FIG. 1 and FIG.

4 is an enlarged front view of the insulating spacer shown in FIG.

5 is an enlarged front view of the flange of the bellows shown in FIG.

6 is a partial detail view of the cylindrical body shown in FIG. 1 and FIG.

7 to 9 are assembly explanatory diagrams of the present invention.

10 is a partial cross-sectional view of the main busbar portion showing an embodiment of the gas insulated switchgear according to the present invention in a state of thermal inversion.

FIG. 11 is a partial cross-sectional view showing the portion shown in FIG. 10 in a state of heat release.

12 is an enlarged partial cross-sectional view showing an embodiment of the insertion main bus.

13 is an overall assembled front view showing an example of a set of gas insulated switchgear.

14 is a side view showing a conventional gas insulated switchgear.

15 is an enlarged front view of the flange of the cylindrical body shown in FIG.

16 is an enlarged front view of the insulating spacer shown in FIG.

17 is an enlarged front view of the flange of the bellows shown in FIG.

18 through 20 are conventional assembly explanatory views.

21 is a partial cross-sectional view of a gas insulated shielding device showing a conventional main bus connection state.

* Explanation of symbols for the main parts of the drawings

1, 1a-1d: cylindrical body, yawing body or mother tank

2: flange 201: screw hole

202: through hole 3: branch pipe

4, 4a-4d: Bellow 5, 5a-5d: Insulated spacer

501: through screw hole 502: through hole

6: flange 601: through hole

7: Temporary fixing bolt 8: Bolt

9: Inserting bolt 13: Main bus bar

14 spacer 15 insertion main bus

17: connection request

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas insulated switchgear, and more particularly, to a connection between a coupling portion of a gas insulated switch and a main bus in a gas insulated switchgear.

Conventional gas insulated switchgear of this kind has been shown in Figs. 14 to 17, the cylindrical bodies 1a to 1d are formed at both ends thereof with large diameter through holes 202 and small diameter through holes 201 formed in the axial direction, as shown in FIG. And a branch pipe (3) branched at right angles to the axial direction and disposed at each intermediate portion of the cylindrical bodies (1a) to (1d). The bellows 4a-4d are connected to each other of the cylindrical bodies 1a-1d through the insulating spacers 5a-5d, respectively, and the bellows 4a-4d respectively. At both ends, a flange 6 having a small diameter through hole 601 formed in the axial direction is provided as shown in FIG. Insulation spacers 5a to 5d are formed with large diameter through screw holes 501 and small diameter through holes 502 in the axial direction, respectively, as shown in FIG.

Next, a case where the cylindrical body 1a and the bellows 4a are assembled through the insulating spacer 5a in the conventional gas insulated switchgear will be described based on FIGS. 18 to 20. FIG. First, as shown in FIG. 18, the flange 2 of the cylindrical body 1a and the insulating spacer 5a are joined together, and the large diameter of the large diameter through hole 202 and the insulating spacer 5a of the flange 2 is joined. Align the through screw hole 501, insert the large diameter temporary fixing bolt 7 from the flange 2 side to the insulation spacer 5a side, and the through screw hole 501 of the large diameter so as not to protrude from the insulation spacer 5a. ), The insulating spacer 5a is temporarily fixed to the flange 2. This temporary fixation allows the correct positioning of the through-holes.

In this state, as shown in FIG. 19, the flange 6 of the bellows 4a is joined to the insulating spacer 5a by the insertion bolt 8A and the nut 8B, and the small diameter of the cylindrical body 1a is bonded. Align the through hole 502 of the small diameter of the through hole 201 and the insulation spacer 5a with the through hole 601 of the small diameter of the bellows 4a, and insert the insertion bolt 8A into the nut 8B. By tightening, the insulating spacer 5a of the flange 2 of the cylindrical body 1a and the flange 6 of the bellows 4a are fixed.

Next, the temporary fixing bolt 7 is pulled out, and the through hole 202 of the large diameter of the cylindrical body 1a and the through screw hole 501 of the large diameter of the insulating spacer 5a and the bellows 4a are inserted into the hole of the large diameter thereafter. The insertion bolt 9 is inserted into the through hole 601 of the small diameter through the washer and tightened with the nut 10 through the washer 101. The diameter of the through screw hole 501 of the large diameter of the insulating spacer 5a is such that the thread of the insertion bolt 9 can penetrate therethrough.

In this type of gas insulated switchgear, the size of the tubular body is increased because the bolt 7 or 9 needs to be inserted between the branch pipe 3 and the flange 2.

When a plurality of gas insulated switchgear are opened to form an inverted station or the like, the main bus line of the gas insulated switchgear is connected, but the configuration of the main bus connecting portion of the conventional gas insulated switchgear is 21st. As shown in the figure, in this figure, reference numeral 1 denotes a busbar tank, 4 denotes a bellow for connecting the busbar tank 1, 8 denotes a bellows 4 and an insulation spacer 5 for the busbar tank. Bolts (1), (11) is the upper cover covering the busbar tank (1), (12) is a straight line disconnector installed in the busbar tank (1), (13) is the main bus bar, (14) is the main bus bar Is a spacer embedded in the insulating spacer 5, 22 is a main bus for connecting, and 23 is a main bus connecting bolt.

Conventionally, in the case of connecting the main bus, the main bus 22 for the connection is peeled off at the heat inversion, and the entire gas insulated switchgear is opened at a predetermined position (see FIG. 13), and then fixed and installed. Open the upper cover 11, insert the main bus line 22 for connection into the busbar tank 1, adjust the dimensions, and fasten the main bus line 13 together with the spacer 14 to the main bus line 13 by fixing it. Let's do it. Subsequently, the bellows 4 and busbar tank 1 are adjusted and fastened with bolts 8 to complete the connection work.

In the conventional gas insulated switchgear as described above, a spacer for inserting the fastening bolt 7 and the insertion bolt 9 between the branch pipe 3 and the flange 2 is required. Thus, the cylindrical body 1a- ( There is a problem that the length in the axial direction of 1d) becomes long.

The present invention has been made to solve the above problems, it is possible to obtain a gas insulated switchgear which can narrow the gap between the branch pipe and the flange of the cylindrical body or the container-shaped body.

In addition, in the conventional gas insulated switchgear, the connection part of the main busbar is configured as described above, so that the positions of the gas insulated switchgear of both sides to be connected must be precisely aligned, and precise dimension adjustment is required, and the connection work is narrow. Since work requires poor workability, such as bolting at a place, there are problems such as poor efficiency and time consuming.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems of the prior art, and an object thereof is to obtain a gas insulated switchgear that can slightly alleviate heat half precision and can simplify and facilitate main bus connection work.

The gas insulated switchgear according to the present invention forms a threaded hole or a through-screw hole in the axial direction on the outer end surface side of the flange of the flange of the tubular body or the recessed body, and penetrates in the axial direction to the other part of the flange. A larger-diameter through-hole is formed than the thread, the flange and the to-be-joined are joined, and the screw or bolt is screwed into the screw or through-screw at the side to be connected.

In the flange part on the side without the branch pipe of the cylindrical body or the container body, a temporary fixing bolt or a temporary fixing screw is inserted, and in the flange part on the side with the branch pipe, a screw or bolt is provided on the flange side of the connected body. Screw in, then pull out the temporary fixing bolt or screw, and insert the insertion bolt or insertion screw there.

In addition, since one side of the gas insulated switchgear has a connection recess, and the other side has an insertion main busbar, the connection is made by an insertion connection. Therefore, the main bus connection work time is greatly shortened, and troublesome work in bad posture is eliminated. In addition, the position adjustment of both gas insulation switchgear at the time of hot spot can also be connected, without requiring high precision.

Next, an embodiment of the present invention will be described with reference to the drawings. 1 to 6, the tubular bodies 1a-1d in the busbar tank are upper and lower portions without protrusion of the flange 2 as shown in Figs. 2, 3 and 6 at both ends, respectively. Flange 2 having screw hole 201 of small diameter formed in the axial direction in the axial direction, or through-hole 202 formed in the axial direction in the part with protrusion of flange 2, and an intermediate part A branch pipe 3 branched and disposed in the axial direction, and the screw hole 201 is formed in the flange 2 portion of the side where the branch pipe 3 branches, and the through hole 202 The engine 3 is formed in the flange 2 part of the side which does not branch. The bellows 4a-4d are connected to each other of the cylindrical bodies 1a-1d via insulating spacers 5a-5c, respectively, and at both ends of the bellows 4a-4c. As shown in Fig. 5, a flange 6 having a small diameter through hole 601 formed in the axial direction is provided. Insulation spacers 5a to 5d are formed with large diameter through screw holes 501 and small diameter through holes 502 in the axial direction, respectively, as shown in FIG. The threaded hole has a bottom, the through hole has no bottom, and the flange 2, the insulating spacers 5a-5d and the bellows 4a-4d of the tubular body have a tubular body (the busbar). Means for easily connecting the tank). Next, the case where the cylindrical body 1a and the bellows 4b are assembled through the insulating spacer 5a is demonstrated based on FIG. 7 thru | or FIG. First, as shown in FIG. 7, the large diameter through-hole of the flange 2 of the cylindrical body 1a and the insulating spacer 5a is joined, and the branch pipe 3 of the flange 2 is not provided. 202 and the through-hole threaded hole 501 of the large-diameter of the insulating spacer 5a are aligned, and firmly insert the infomation 7 from the flange 2 side to the insulating spacer 5a and not protrude from the insulating spacer 5a. The insulating spacer 5a is temporarily fixed to the flange 2 by screwing it into the large-diameter through-hole 501 so as not to be.

In this state, the flange 6 of the bellows 4b is joined to the insulating spacer 5a, and the small diameter screw hole 201 and the insulating spacer (1) on the side where the branch pipe 3 of the cylindrical body 1a emerges. Align the small-bore through hole 502 of 5a with the small-bore through hole 601 of the bellows 4b, and insert the bolt 8 into the bellows 4b side as shown in FIG. The flange 2 of the tubular body 1a and the flange 6 of the insulating spacer 5a and the bellows 4b are fixed by screwing in 201).

Next, the planting bolt 7 is pulled out, and the through hole 202 of the large diameter of the cylindrical body 1a and the through screw hole 501 of the large diameter of the insulating spacer 5a, the bellows 501, and the bellow 4b are placed therein. Into the through hole 601 of the small diameter, the insertion bolt 9 having a diameter smaller than the temporary fixing bolt 7 is inserted into the through hole 601 of FIG. 9 and fastened to the nut 10 through the washer 101. The diameter of the large-sized through screw hole 501 of the insulating spacer 5a is such that the thread of the insertion bolt 9 can pass therethrough or larger.

In addition, when connecting the flange 2 of the cylindrical body 1b and the flange 6 of the bellows 4b directly, as shown in FIG. 1 without interposing the insulating spacer 5a, the flange 2 of the cylindrical body 1b. ) And the flange 6 of the bellows 4b, and the bolt 8 is screwed into the through hole 601 of the small diameter of the bellows 4b and the screw hole 201 of the tubular body 1b from the bellows 4b side. And insert the screw (9) into the threaded hole (201) while inserting the insertion bolt (9) into the through hole (601) of the small diameter of the bellows (4b) and through hole (202) of the large diameter of the cylindrical body (1b). Tighten with nut 10 through. In this way, each unit of the tubular members 1a-1d, the insulating spacers 5a-5c, and the bellows 4a-4d is sequentially connected as shown in FIG.

In this embodiment, as shown in FIG. 6, the screw holes 201 are formed in the screw holes 201 of the flanges 2 of the cylindrical bodies 1a to 1d. It may be a through screw hole formed by penetrating the pendulum. Alternatively, the container body may be substituted for the cylindrical bodies 1a to 1d. The bolt 8 may be a screw, the insertion bolt 9 may be an insertion screw, or the temporary fixing bolt 7 may be a temporary fixing screw.

In the above embodiment, the insulating spacers 5a to 5c or the bellows 4a to 4d as the connected bodies 1a to 1d or the container shaped bodies have been described. Or other cylindrical or container-like bodies or bushings.

In addition, this invention is demonstrated in detail by the Example shown about connection of a main bus.

As shown in FIG. 10, in the gas insulated switchgear according to the present invention, the structure of the portion other than the connection portion of the main bus is the same as that of the conventional gas insulated switchgear shown in FIG. The same reference numerals are used to denote equivalent members of the twenty-first degree, and description thereof is omitted.

As shown in Fig. 10, the connecting recesses which are female side (female) are connected to the bus bar connection part in the busbar tank 1 of the gas insulated switchgear on one side (left side in the drawing), that is, the gold spacer 18 embedded in the insulating spacer 5. 17 is provided with the shield 16 and attached to the metal 18 embedded in, for example, 18a (FIG. 12). In the gas insulated switchgear on the other side (right side in the drawing), the main bus line connecting part, i.e., the insertion main bus line 15 which is the male side at the position facing the connecting recess 17 on the spacer 14 of the main bus 13 ) Is excreted. The insertion main bus line 15 can be formed in a detachable structure which is fastened and fixed to the main bus bar 13 through the spacers 14 by the bolt 19 and the washer 20 as shown in detail in FIG. 12. The case where a main bus is connected and a gas insulated switchgear is installed in a substation etc.

The heat inversion is shown in FIG. 10, and each gas insulated switchgear is placed in a separated state. A connecting recess 17 is attached to one gas insulated switchgear on the left side of the drawing, and an insertion main bus line 15 is attached to the other gas insulated switchgear on the other side (on the right side in the drawing). To install, first fix one gas insulated switchgear at a predetermined position, then slowly approach the other gas insulated switchgear and adjust the position of the main busbar forward and backward and up and down while looking at the state of the main bus. When the position is determined within the determined allowable dimension, the contact is made as it is. At that time, the tip of the insertion main bus line 15 is inserted into the connecting recess 17, and connection is performed. When the bellows 4 and the busbar tank 1 are fastened with bolts 8, the installation is completed. At this time, since the insertion main bus line 15 is automatically inserted in the connecting recess 17, the connection is completed. In general, the permissible shim error tolerance for insertion between the connecting recess 17 and the insertion main bus line 15 is several mm, and has a large margin compared to conventional bolting. The shield 16 may not be necessary.

The above has described the case where the new gas insulated switchgear is installed in sequence, but in the case of the expansion in the middle of the nirvana, the case of removing the gas insulated switchgear in the middle, and inserting another one instead, After completion of nirvana as shown in the figure, the main main line 15 to be contracted is inclined as shown by the dotted line and pushed into the connecting recess 17. Then, the core is tightened with the spacer 14 and the main bus fastening bolt 19 and washer. Using 20, the main bus 13 can be fastened and fixed. The bolt fastening work may be performed on only one side, so that the working time can be shortened. When removing, the procedure is the reverse of the above.

In the above embodiment, as shown in FIG. 13, the main bus bar (shown in FIG. 13 as shield 16 for the two main bus bars) is illustrated in a round shape, but the main bus bar is not limited to the round shape. In Fig. 13, reference numeral 21 denotes a hermetically sealed container that forms part of the gas insulated switchgear. The connection recess and the insertion main bus bar have the same effect as described above on either side. Furthermore, the 11 degrees _{(W 1), (W 2} ) is shown the width of one set of gas-insulated switchgear device, _{(W 1), (W 2} ) may be either the same dimensions or different dimensions.

As described above, according to the present invention, a through screw hole or a screw hole is formed at the outer end surface in the axial direction in the branch observation portion of the flange of the tubular body or the container shape having the branch pipe, and penetrates in the axial direction to the other portion of the flange. Since a ball is formed to join the flange and the connected object, and screws or bolts are screwed into the threaded hole or through threaded hole on the side to be connected, a space for screw or bolt insertion is required between the branch pipe and the flange. In addition, since the space between the branch pipe and the flange can be narrowed, the device can be made compact.

In addition, according to the present invention, since the same cylindrical body and bellows can be used for both insulated and non-insulated attachment, the number of types of components can be reduced.

In addition, according to the present invention, by inserting the main connecting line to the main busbar of one gas insulated switchgear, the main main bus of the other gas insulated switchgear adjacent to each other, and open the two gas insulated switchgear automatically Since the main bus is configured to be connected, work in a narrow place is eliminated, dimensional accuracy is not strict, and main bus connection and installation work can be greatly reduced, further reducing the installation cost. There is.

Claims (6)

A busbar tank 1 having a flange 2 having a plurality of threaded holes and a through hole on both sides, a branch pipe 3 branched at right angles to the axial direction in which the flange is disposed, and the motor tank A gas insulated electric apparatus, comprising means for easily connecting (1). The busbar tank according to claim 1, wherein the means for easily connecting the busbar tank (1) includes a flange (2) having a large diameter through hole (202) and a small diameter screw hole (201), and the busbar tank (2). And a thread having a large diameter through screw hole 501 corresponding to a large diameter through hole 202 of the flange 2 of the busbar tank 1, and a small diameter of the flange 2 of the bus mother tank 1 An insulating spacer 5 having a small diameter through hole 502 corresponding to the thread hole 201, which is fixed to one flange 2 of the busbar tank 1, and a small diameter through hole 601 on both sides. A bellows (4) having a flange (6) with a flange (6), one flange (6) of the bellows (4) being fixed to the insulating spacer (5) and the other flange (6) of the bellows (4) ) Is a bellows (4) which is fixed to the flange (2) of the other side of the busbar tank (1). 6. The insulating spacer (5) according to claim 5, wherein the insulating spacer (5) is fixed to the flange (2) of the busbar tank (1) and the flange (6) of the bellows (4) by bolts, It is inserted into a small diameter through hole 601 and a small diameter through hole 502 of the insulating spacer, screwed into a small diameter screw hole 201 of a flange of the busbar tank, and the bellows by another bolt. And a small diameter through hole (601) of the flange of the flange and a large diameter through screw hole (501) of the insulating spacer and a large diameter through hole (202) of the flange of the tank. 6. The flange 6 on the other side of the bellows 4 is fixed to the flange 2 on the other side of the busbar tank 1 by bolts, and the flange of the bellows flange is fixed by a bolt. It is inserted into the through hole 601 of the bore, and is screwed into the screw hole 201 of the small diameter of the flange of the busbar tank, and the through hole 601 of the small diameter of the flange of the bellows by another bolt. Gas insulated electric apparatus, characterized in that inserted into the through hole 202 of the large diameter of the flange of the mother tank. According to claim 1, Means for easily connecting the busbar tanks are disposed in each busbar tank (1) having a main busbar 13 therein, and the connection recess 17 to relax the heat half precision in connection And an insertion main bus line (15) inserted into a connection recess (17) of one end of the adjacent bus bar tank and the other end fixed to the main bus line (13). 9. The gas insulated switchgear according to claim 8, wherein the insertion main bus line (15) is fixed to the main bus line (13) by a bolt through a spacer (14).

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