KR102307655B1 - Bushing cover of metering out fit - Google Patents

Abstract

The present invention relates to a bushing cover for an instrument transformer, where a barrier rib is formed at the boundary between a lower body and a protruding body, so that a conductor of a load side wire cannot be connected to a power supply side bushing, to prevent conduction and to allow an instrument transformer to accurately measure current consumption.

Description

Bushing cover of instrument transformer {BUSHING COVER OF METERING OUT FIT}

The present invention relates to a bushing cover for an instrument transformer, and more particularly, to a bushing cover for an instrument transformer that blocks a bushing exposed at the top of the instrument transformer to the outside to protect the bushing and prevent an electric shock accident. .

Instrument transformer is a combination of instrument transformer (PT) and instrument current transformer (CT). These instrument transformers are used for metering power consumption in high-pressure receivers.

1 and 2, a bushing 20 protrudes from the upper end of the instrument transformer, and the lower portion thereof is protected by an insulator 23. As shown in FIG. The bushing 20 has a structure in which a cylindrical power-side bushing 21 is inserted into the cylindrical load-side bushing 22 in an insulated state, and the power-side wire 31 is connected to the wire connection portion 21a of the power-side bushing 21. The load-side electric wire 32 is connected to the plate-shaped wire connection part 22a that is connected and protrudes from the side of the load-side bushing 22 .

The load-side electric wire 32 is connected to a fixing member 22b fixed to the electric wire connection part 22a with a bolt in a structure in which the portion of the conductor 32a with the bare coating is pressed.

On the other hand, if the bushing 20 is exposed to the outside as it is, there is a risk of contamination and damage to the bushing 20, and in particular, the risk of electric shock is high. is insulated.

The bushing cover 10 has an upper body 11 and a lower body 12 surrounding the bushing 20 and the insulator 23, and a protruding body surrounding the connection between the wire connection part 22a and the load-side wire 32. (13). The upper body 11 and the lower body 12 are cylindrical and have a step difference between them, and the protruding body 13 is formed to protrude from one side of the lower body 12 and has a substantially rectangular parallelepiped shape. In addition, a wire hole 11a into which the power-side wire 31 is inserted is formed in the upper portion of the upper body 11, and a wire hole 13a through which the load-side wire 32 passes is formed on the front surface of the protruding body 13. . The wire hole 13a formed in the double protruding body 13 has a shape that is opened downward so that the bushing cover 10 can be installed by moving downward from the top.

Therefore, the bushing cover 10 is installed in a state that surrounds the bushing 20 as shown in FIG. 2 , thereby shielding the bushing 20 from the outside to protect the bushing 20 and prevent an electric shock accident.

On the other hand, in the instrument transformer, the supply current passes through the electric devices inside the instrument transformer through the power supply side wire 31 and the power supply side bushing 21, and then flows through the load side bushing 22 and the load side electric wire 32. The usage (current supplied from the supplier side to the user side) can be accurately measured.

However, in some sites, as shown in FIG. 3 , the conductor 32a is lengthened by stripping the cover of the load-side electric wire 32 and connected to the power-side bushing 21 to conduct conduction. As such, when the load-side wire 32 is directly connected to the power-side bushing 21, a significant amount of the current supplied through the power-side wire 31 flows directly to the load-side wire 32 without going through the instrument transformer. Since the current consumption cannot be measured, there is a problem that conduction is easily performed.

In addition, after the bushing cover 10 is installed, the bushing cover 10 is fixed at the installation position and a separate sealing operation is performed so that it cannot be removed arbitrarily. Therefore, the installation of the bushing cover is cumbersome and time-consuming, and in particular, in many cases, the sealing operation is performed after starting the current supply in the field, so there is a problem that an electric shock accident occurs during the sealing operation.

Republic of Korea Registered Utility Model Publication No. 20-0315371 (Registered on May 21, 2003)

Accordingly, the present invention has been devised to solve the above problems, and by preventing conduction, the instrument transformer can accurately measure the current consumption, and the sealing is automatically performed upon installation on the upper part of the instrument transformer, so that a separate sealing operation is performed. An object of the present invention is to provide a bushing cover of an instrument transformer that is easy to install, takes less time, and can prevent an electric shock accident during sealing work in advance.

The present invention for achieving the above object is a tubular upper body and lower body communicating with each other in the inner space so as to surround the upper part of the insulator and the bushing, and the electric wire of the load-side bushing protruding from one side of the lower body A protruding body surrounding the connection part of the connecting part and the load-side electric wire, and formed at the boundary between the protruding body and the lower body to block the extension of the conductor of the load-side electric wire from the inner space of the protruding body to the inner space of the upper body and the lower body including bulkheads that

The bulkhead is formed with a length in which the lower end abuts against the upper surface of the wire connection part of the load-side bushing.

The partition wall is formed in a shape extending downward while enclosing both sides of the wire connection part of the load-side bushing.

In addition, the present invention is a tubular upper body and lower body communicating with each other in the inner space so as to surround the upper part of the insulator and the bushing, and is formed protruding from one side of the lower body to connect the wire connection part of the load-side bushing and the load-side wire. a protruding body surrounding the protruding body; a partition wall formed at the boundary between the protruding body and the lower body to block the conductor of the load side from extending into the inner space of the upper body and the lower body in the inner space of the protruding body; and the protruding body; A wire hole formed in a shape that is opened downward on the front wall of It may include a sealing device that suppresses the load-side electric wire from being separated to the outside of the electric wire hole again.

The sealing device is rotatably installed on the outer part of the wire hole in the front wall of the protruding body through a hinge pin, and when rotated toward the wire hole, blocks the lower part of the load-side wire that has entered the wire hole so that the load-side wire is connected to the wire A pair of lock levers to suppress separation from the hole, a torsion spring installed on the hinge pin to apply force so that the lock lever always rotates inside the wire hole, and a bushing cover before installing the wire hole in a state that blocks the wire hole The both ends support the lock levers on both sides to prevent the lock lever from rotating inside the wire hole, and when the bushing cover is installed, it may include a push member that releases the lock lever support state while being pushed and moved by the load-side wire entering the wire hole. .

A pin is formed to protrude upward from an upper portion of the push member, an elastically deformable locking piece is formed on the upper end of the pin, and a through hole through which the locking piece is penetrated and hooked is formed on the upper surface of the protruding body.

In addition, the present invention further comprises a latch gear formed at the end of the hinge pin side of the lock lever, and a stopper that is selectively meshed with the latch gear so that the lock lever is rotatable in the inner direction of the wire hole and cannot be rotated in the reverse direction. include

On the other hand, the sealing device is mounted on the outer surface of the front wall of the protruding body and has a body formed in a shape surrounding the periphery of the wire hole, and is rotatably installed with a hinge pin on one side of the body and a hooking tooth type on one side of the end It may include the formed rotary lever, and a locking tooth-shaped member that is installed on the lower portion of the other side of the body and meshes with the locking tooth-type of the rotary lever.

The body includes a pair of body plates spaced apart from each other, and the rotary lever and the engaging tooth member are installed between the body plates.

The locking tooth shape of the rotary lever and the tooth shape of the locking tooth member are formed in a shape that allows upward rotation (clockwise rotation) of the rotary lever and suppresses downward rotation (counterclockwise rotation) of the rotation lever in a state in which they are engaged with each other.

The engaging tooth-shaped member is elastically supported by a leaf spring.

According to the present invention as described above, a barrier rib is formed in the bushing cover to block a path connecting the conductor of the load-side electric wire to the power-side bushing, thereby preventing conduction, and accurate current consumption can be measured in the instrument transformer.

The bushing cover installation work is quick and easy as it is equipped with a sealing device that automatically seals when it is installed on the bushing cover. It can prevent an electric shock accident.

1 is a perspective view of a bushing cover of an instrument transformer according to the prior art.
Figure 2 is a sectional view of a conventional bushing cover installation state.
3 is a view showing a structure in which conduction is made in the conventional bushing cover installation state.
4 is a perspective view of a bushing cover of a transformer for an instrument according to the present invention.
5 is a cross-sectional view of an installation state of the bushing cover according to the present invention.
6 and 7 are a first embodiment of the sealing device installed on the bushing cover according to the present invention, Figure 6 is a state diagram before operation, Figure 7 is a state diagram after operation.
8 and 9 are a second embodiment of the sealing device, FIG. 8 is a state diagram before operation, and FIG. 9 is a state diagram after operation.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. The thickness of the lines or the size of the components shown in the accompanying drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or precedent of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are assigned to the same parts as in the prior art.

4 is a perspective view of a bushing cover of an instrument transformer according to the present invention, and FIG. 5 is a cross-sectional view of an installation state of the bushing cover according to the present invention. As shown in FIGS. 4 and 5, the bushing cover according to the present invention ( 10) has the same external structure as the conventional bushing cover.

That is, the bushing cover 10 according to the present invention has an upper body 11 and a lower body 12 surrounding the upper portion of the bushing 20 and the insulator 23 , and the connection part of the wire connection part 22a and the load side wire 32 . It includes a protruding body 13 surrounding the.

The upper body 11 and the lower body 12 are cylindrical and have a step difference between them, and the protruding body 13 is formed to protrude from one side of the lower body 12 and has a substantially rectangular parallelepiped shape.

In addition, a wire hole 11a into which the power-side wire 31 is inserted is formed in the upper portion of the upper body 11, and a wire hole 13a through which the load-side wire 32 passes is formed on the front surface of the protruding body 13. . The wire hole 13a formed in the double protruding body 13 has a shape that is opened downward so that the bushing cover 10 can be installed by moving downward from the top.

The bushing 20 of the instrument transformer consists of a substantially cylindrical power-side bushing 21 and a substantially cylindrical load-side bushing 22, which has a structure in which the power-side bushing 21 is inserted into the load-side bushing 22. and is insulated from each other in that state.

On the upper portion of the power-side bushing 21, a wire connection part 21a to which the power-side wire 31 is connected is formed in a circular shape having a concentric circle, and the load-side wire 32 is connected to the load-side bushing 22. A plate-shaped wire connection part (22a) is formed to protrude in the transverse direction.

The conductor 32a of the load side electric wire 32 is pressed and fixed to the fixing member 22b fixed by bolts to the electric wire connection part 22a, and the connection part of this electric wire connection part 22a and the load side electric wire 32 is a bushing cover. It is located on the inside of the protruding body 13 in (10).

On the other hand, the bushing cover 10 according to the present invention is a partition wall 14 that blocks the conductive passage between the lower body 12 and the protruding body 13 on the upper surface of the boundary between the lower body 12 and the protruding body 13. It is characterized in that it is formed.

Since the upper space of the lower body 12 is completely in communication with the upper body 11, when the bulkhead 14 blocking the passage from the protruding body 13 to the lower body 12 is formed, the load side bushing 22 ) from the connection part of the wire connection part 22a and the load-side electric wire 32 to the load-side electric wire 32 conductor ( 32a) cannot be connected to the power-side bushing 21, making it impossible to conduct.

The lower end of the partition wall 14 is formed to have a length in contact with the upper surface of the load-side bushing 22 to completely block the passage of the conductor 32a of the load-side electric wire 32 into the upper space of the electric wire connection part 22a.

In addition, although not shown, the partition wall 14 may extend vertically downwardly in a shape surrounding the side surface of the wire connection part 22a and may be formed to have a length in contact with the upper surface of the insulator 23 . In this way, it is possible to prevent the conductor 32a of the load-side electric wire 32 from being introduced into the inner side of the lower body 12 through the space below the side of the electric wire connection part 22a and then raised again and connected to the power-side bushing 21. have.

As described above, a partition wall 14 is formed between the lower body 12 and the protruding body 13 to block the path connecting the conductor 32a of the load-side electric wire 32 to the power-side bushing 21, so that the power-side bushing ( In 21), the current cannot flow directly to the load-side wire 32 without going through the transformer for the instrument, and thus conduction is prevented and the transformer for the instrument can accurately measure the amount of current used.

On the other hand, the bushing cover 10 according to the present invention is characterized in that the sealing device is installed on the front of the protruding body (13). The sealing device may be implemented with the configuration of the first embodiment shown in FIGS. 6 and 7 and the second embodiment shown in FIGS. 8 and 9 .

First, a first embodiment of the bushing cover sealing device will be described with reference to FIGS. 6 and 7 .

An inverted U-shaped wire hole 13a opened downwardly is formed on the front surface of the protruding body 13, and a sealing device is installed around the wire hole 13a.

Guides 13b are provided on both sides of the wire hole 13a in the vertical direction. The guide 13b may be in the form of a groove formed inside the front wall (in this case, it is necessary to form the front wall of the protruding body 13 thick), or a separate straight member is provided at a predetermined interval on the rear of the front wall. It may be of a type installed with a

A push member 40 that crosses the wire hole 13a in the transverse direction is installed in the wire hole 13a. Both ends of the push member 40 are inserted into the guide 13b to guide the elevating path. A pin 41 is formed to protrude upward from the center of the upper surface of the push member 40 , and an elastically deformable gully piece 42 is formed at an end of the pin 41 .

In addition, a hinge pin 51 is fixed to the outside of the guide 13b inside the front wall of the protruding body 13 , and a rotatably lock lever 50 is installed on the hinge pin 51 .

A torsion spring 52 is installed on the hinge pin 51, one end of the torsion spring 52 is fixed to the front wall and the other end applies a force to always rotate the lock lever 50 toward the wire hole 13a.

Since the lock lever 50 is normally supported by the push member 40, it is hidden behind the front wall without protruding toward the wire hole 13a.

In addition, a latch gear 60 is formed around the hinge pin 51 insertion part of the lock lever 50 . In addition, a stopper 61 that is selectively hung on the teeth of the latch gear 60 according to the rotation direction of the latch gear 60 is installed in a rotatable position at a predetermined distance away from the latch gear 60 . Although not shown, the stopper 61 is also provided with a torsion spring, so that a force may be applied to maintain the stopper 61 in contact with the latch gear 60 .

When the lock lever 50 is rotated, the latch gear 60 is also rotated integrally, and the stopper 61 allows the lock lever 50 to rotate in the inner direction of the wire hole 13a, but the lock lever 50 Reverse rotation is not allowed.

In addition, a through hole 13c through which the pin 41 of the push member 40 passes is formed in the upper wall of the protruding body 13, and the locking piece 42 penetrates the through hole 13c and then unfolds. It is caught in the periphery of the through-hole (13c) as it goes down. In FIG. 6, the front wall of the protruding body 13 is thickly formed so that the through hole 13c penetrates the entire upper portion of the front wall. With this structure, the through hole 13c may be formed.

Before the bushing cover 10 is installed by the above structure, the rotation of the lock lever 50 is suppressed by the push member 40 as shown in FIG. 6 . When the bushing cover 10 is installed while moving from the top of the bushing 20 downward in that state, the load-side electric wire 32 moves to the inside of the electric wire hole 13a. At this time, the load-side electric wire 32 moves while pushing the push member 40 upward.

Therefore, the support state of the lock lever 50 by the push member 40 is released, and the lock lever 50 is rotated toward the wire hole 13a by the force of the torsion spring 52 to close the lower part of the electric wire 32 on the load side. will get in the way

At this time, the stopper 61 is engaged with the latch gear 60 to prevent the lock lever 50 from rotating into the space behind the front wall, so that the load-side electric wire 32 cannot move downward of the electric wire hole 13a. , it becomes impossible to remove the bushing cover 10 from the installation position because it is impossible to raise it. That is, the sealing of the bushing cover 10 is made.

In the above state, the push member 40 is completely raised, and the locking piece 42 of the upper end of the pin 41 passes through the through hole 13c and then spreads apart, and the periphery of the through hole 13c (the upper surface of the protruding body 13). ) to keep the rising position stable.

As described above, at the same time as the bushing cover 10 is installed in place, the sealing device is automatically operated to perform sealing.

Meanwhile, the second embodiment of the bushing cover sealing device is also installed on the front wall of the protruding body 13 as shown in FIGS. 8 and 9 . However, as shown in reference numerals 71a and 71b in FIG. 9 , since a body 71 having a double structure is required, it may be preferable to separately manufacture the sealing device 70 and mount the sealing device 70 on the outside of the front surface of the protruding body 13. . Of course, the front wall of the protruding body 13 may be formed in a double structure or very thick to take a structure in which all of the components to be described later are installed therein.

Hereinafter, the sealing device 70 of a type to be separately manufactured and mounted, which is relatively superior in manufacturing convenience, will be described as an example.

The sealing device 70 includes an inverted U-shaped body 71, an approximately L-shaped rotary lever 72 rotatably fixed to one lower end of the body 71 by a hinge pin 73, and the body (71) It is installed on the other side of the inside and includes a locking tooth-shaped member 74 that is caught on the locking tooth-shaped member 72a of the rotary lever 72, and a leaf spring 75 for elastically supporting the locking-tooth-shaped member 74. .

The body 71 has a double structure and includes a pair of body plates 71a and 71b formed in the same inverted U shape. The rotary lever 72 is installed between the two body plates 71a and 71b. The side portion of the body 71 overlapping the rotation range of the rotary lever 72 is removed so that the rotary lever 72 can rotate 360 degrees around the hinge pin 73 . The other side portions other than the removed portion may be interconnected to form a body 71 by a pair of body plates 71a and 71b.

9 schematically shows a right side view of the sealing device 70 , and an inner body plate 71b is attached to the front surface of the protruding body 13 .

The teeth of the locking tooth shape 72a of the rotary lever 72 and the locking tooth member 74 allow the rotary lever 72 to rotate in the clockwise direction, but the rotation lever 72 can rotate in the opposite direction. It is formed in a shape that does not

That is, each of the teeth of the locking tooth shape member 74 has a flat upper surface, and the inclined surface connected therefrom is inclined in a direction away from the wire hole 13a as it goes downward, and each of the locking tooth shape 72a of the rotary lever 72 has a lower surface. This flat and inclined surface connected therefrom is formed in a shape inclined in a direction closer to the wire hole 13a as it goes upward (described on the basis of a state in which both teeth are engaged).

In addition, the operation of the rotary lever 72 is performed by the leaf spring 75 elastically supporting the engaging tooth-shaped member 74 toward the wire hole 13c, so that the engaging tooth-shaped member 74 compresses the leaf spring 75 while compressing the wire hole. It is possible by being movable in a direction away from (13c).

Before installing the bushing cover 10 on the bushing 20 by the above structure, as shown in FIG. 8, by adjusting the rotation position of the rotary lever 72 (can be freely rotated clockwise), the rotary lever ( 72) can be made in a state in which the engaging tooth type (72a) is engaged with the engaging tooth type member (74). At this time, the wire hole 13a of the protruding body 13 is blocked by the rotary lever 72 .

In this state, when the bushing cover 10 is lowered to cover the bushing 20, the load-side wire 32 pushes the rotary lever 72 while entering the wire hole 13a, and the load-side wire 32 When this maximum rises, the rotary lever 72 is rotated out of the body 71 , and in some cases, the rotary lever 72 is rotated to a state in which it hangs under the body 71 under the influence of an operating force and its own weight. In that state, when the operator directly rotates the rotary lever 72 further in the same direction, the locking tooth shape 72a of the rotary lever 72 enters the interior of the body 71 again and can be meshed with the locking tooth shape member 74. have. At this time, the load-side electric wire 32 is completely entered into the wire hole 13a, and the downward direction is blocked by the rotary lever 72, and the rotary lever 72 has the locking tooth shape 72a and the locking tooth member 74. Since it cannot be rotated downward (counterclockwise around the hinge pin 73 ) due to the shape of the teeth, the load-side electric wire 32 cannot escape to the outside of the electric wire hole 13a. That is, by lifting the bushing cover 10 upward, it is in a sealed state that makes it impossible to separate it from the bushing 20 .

Accordingly, the sealing device 70 can be operated to seal the bushing cover 10 only by a simple operation of slightly rotating the rotary lever 72 while installing the bushing cover 10 in place.

As described above, since the sealing of the bushing cover 10 according to the present invention is completed along with the installation, a state in which the bushing cover 10 is installed but not sealed does not occur.

Therefore, since it is not necessary to check the sealing state and perform the sealing operation later in the state in which the power supply is started, an electric shock accident does not occur. For the same reason, there is no need to separately assign a sealing number and check and manage it, so that an electric shock accident while approaching the bushing 20 to check the sealing number later does not occur.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and those of ordinary skill in the art can make various modifications and equivalent other embodiments therefrom. You will understand that it is possible. Therefore, the true technical protection scope of the present invention should be defined by the following claims.

10: bushing cover 11: upper body
11a: wire hole 12: lower body
13: protruding body 13a: wire hole
14: bulkhead 20: bushing
21: power side bushing 21a: wire connection part
22: load side bushing 22a: wire connection part
22b: fixing member 31: power-side electric wire
32: load side wire 32a: conductor
40: push member 50: lock lever
51: hinge pin 52: torsion spring
60: latch gear 61: stopper
70: sealing device 71: body
72: rotary lever 73: hinge pin
74: engaging tooth-shaped member 75: leaf spring

Claims (11)

A tubular upper body and a lower body in which the inner space communicates with each other so as to surround the upper part of the insulator and the bushing;
a protruding body formed to protrude from one side of the lower body to surround the wire connection portion of the load-side bushing and the connection portion of the load-side wire;
a partition wall formed at the boundary between the protruding body and the lower body to block the conductor of the load-side electric wire from extending from the inner space of the protruding body to the inner space of the upper body and the lower body;
A bushing cover of an instrument transformer comprising a. The method according to claim 1,
The bulkhead is a bushing cover of an instrument transformer, characterized in that the lower end is formed with a length in contact with the upper surface of the wire connection part of the load-side bushing. The method according to claim 1,
The bulkhead is a bushing cover for an instrument transformer, characterized in that it is formed in a shape extending downward while enclosing both sides of the wire connection part of the load-side bushing. A tubular upper body and a lower body in which the inner space communicates with each other so as to surround the upper part of the insulator and the bushing;
a protruding body formed to protrude from one side of the lower body to surround the wire connection portion of the load-side bushing and the connection portion of the load-side wire;
a partition wall formed at the boundary between the protruding body and the lower body to block the conductor of the load-side electric wire from extending from the inner space of the protruding body to the inner space of the upper body and the lower body;
an electric wire hole formed in a downwardly opened shape on the front wall of the protruding body so that the load-side electric wire can ascend and enter from the bottom;
a sealing device installed around the wire hole of the front wall of the protruding body to prevent the load-side wire entering the wire hole from being separated out of the wire hole again when the bushing cover is installed;
A bushing cover of an instrument transformer comprising a. 5. The method according to claim 4,
The sealing device is
It is rotatably installed on the outer part of the wire hole in the front wall of the protruding body through a hinge pin, and when it is rotated toward the wire hole, it blocks the lower part of the load-side wire that has entered the wire hole so that the load-side wire is separated from the wire hole a pair of locking levers for restraining it;
a torsion spring installed on the hinge pin to apply a force so that the lock lever always rotates inside the wire hole;
Before the bushing cover is installed, both ends support the lock levers on both sides while blocking the wire hole to prevent the lock lever from rotating inside the wire hole. a push member for releasing the lever support state;
A bushing cover of an instrument transformer comprising a. 6. The method of claim 5,
A pin is formed to protrude upwardly on the upper portion of the push member, an elastically deformable locking piece is formed on the upper end of the pin, and a through hole through which the locking piece is penetrated and hooked is formed on the upper surface of the protruding body. Transformer bushing cover. 6. The method of claim 5,
a latch gear formed on the hinge pin side end of the lock lever;
a stopper selectively engaged with the latch gear so that the lock lever is rotatable in the inner direction of the wire hole and cannot be rotated in the reverse direction;
The bushing cover of the instrument transformer further comprising a. 5. The method according to claim 4,
The sealing device is
a body mounted on the outer surface of the front wall of the protruding body and formed in a shape surrounding the periphery of the wire hole;
a rotary lever rotatably installed on one side of the lower portion of the body with a hinge pin and having a locking tooth shape on one side of the end;
a locking tooth-shaped member installed in the lower portion of the other side of the body and engaged with the locking tooth-shaped member of the rotary lever;
A bushing cover of an instrument transformer comprising a. 9. The method of claim 8,
The body includes a pair of body plates spaced apart from each other, and the bushing cover of the instrument transformer, characterized in that the rotary lever and the engaging tooth member are installed between the body plates. 9. The method of claim 8,
The locking tooth shape of the rotary lever and the tooth shape of the locking tooth member are formed in a shape that allows upward rotation (clockwise rotation) of the rotary lever and suppresses downward rotation (counterclockwise rotation) in a state in which they are engaged with each other. The bushing cover of the instrument transformer. 11. The method of claim 10,
The bushing cover of the instrument transformer, characterized in that the engaging tooth member is elastically supported by a leaf spring.

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