KR101510982B1 - Vacuum breaker - Google Patents

Abstract

A three-phase vacuum valve 2, three insulating frames 3 for housing and holding the vacuum valve 2 in individual phases, and a bogie frame 7 having a mechanism case 7c on the front side Three insulating frames 3 accommodating the vacuum valve 2 are arranged rearwardly of the instrument case 7c in the left and right direction and the lower side thereof is fixed to the bogie frame 7, 3 and the mechanism case 7c and the latch portion 15 restrains displacement of the insulating frame 3 in the vertical direction.

Description

Vacuum breaker {VACUUM BREAKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum circuit breaker using a vacuum valve used in a power reception / distribution (power distribution) facility, and more particularly to an insulation frame that receives and holds a vacuum valve.

The vacuum valve which is the blocking part of the vacuum circuit breaker is arranged at a predetermined interval in parallel with the axial direction in three phases and is held in the insulating frame in three phases or in each phase, (Mounted) on the frame.

[0003] In a conventional vacuum circuit breaker in which a vacuum valve is held in a three-phase insulated frame, for example, an insulation frame on which a chamber divided into three phases is formed is mounted on a bank base, The fixed side of the upper portion of the vacuum valve is connected to the upper main circuit conductor in the horizontal direction and is fixed to the insulating frame, and the movable side of the lower portion is fixed to the lower main circuit via the flexible conductor And is drawn out in the horizontal direction (see, for example, Patent Document 1).

Further, in the conventional vacuum circuit breaker which is individually held in the insulating frame, for example, a vacuum valve is arranged in a U-shaped insulating frame whose cross section is in the vertical direction so that the three- It is mounted on a moving lorry together. The fixed conductors and the movable conductors connected to the fixed contacts and the movable contacts of the vacuum valve are disposed above and below the vacuum valve and extend outward in the horizontal direction from the opening side of the U- (See, for example, Patent Document 2).

[Patent Document 1] JP-A-7-320610 (page 3, Fig. 1) [Patent Document 2] JP-A-2006-49247 (page 4, Fig. 1)

Since the three-phase vacuum circuit and the upper and lower main circuit conductors arranged in the insulating frame are formed in parallel with each other, a large current such as a short- (Energizing portion), an excessive electromagnetic force is generated in the phase-to-phase direction, and this electromagnetic force also acts on the three-phase insulating frame supporting the conductor portion.

In the vacuum circuit breaker disclosed in Patent Document 1, since the insulating frame is made up of three phases in total, the mutual strength between the three phases can be ensured. However, when the breaking capacity of the vacuum circuit breaker is increased, the vacuum valve and the main circuit conductor portion are also increased in size, The frame becomes larger. For this reason, in order to produce a three-phase assembly, there is an increase in the initial cost due to the enlargement of the mold structure and a restriction of the manufacturer of the mold that can be manufactured. Therefore, there has been a problem in advancing the enlargement of the vacuum circuit breaker by using the three-phase type insulation frame.

On the other hand, in the case where the insulating frame is fixed to the bogie in three phases as in Patent Document 2, since the mold for manufacturing the insulating frame is smaller than the three-phase blanket type, the merit on the production surface is large , It is conceivable that the insulating frame is displaced by the above-described electromagnetic force. When the insulating frame is displaced, the contact portions of the contacts of the main circuit conductors are also displaced, so that the electrification performance is lowered and arcing may occur. In order to prevent this, measures such as increasing the rigidity of the insulating frame and the bogie frame for mounting the bogie frame, or increasing the load of the contact pressure of the contact portion are required, leading to an increase in cost.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a vacuum circuit breaker excellent in mechanical strength against an electromagnetic force in an up-down direction even in the case of a three-phase separate insulating frame.

A vacuum circuit breaker according to the present invention is a vacuum circuit breaker comprising: a vacuum valve in three phases; three insulation frames for receiving and holding vacuum valves in phases; and a vacuum valve There is provided a vacuum circuit breaker including a bogie frame having an instrument case accommodating a mechanism part, three insulating frames accommodating a vacuum valve are arranged rearwardly of the instrument case in left and right directions and a lower side thereof is fixed to a bogie frame, A latch portion is provided at an opposing portion between the insulating frame and the instrument case, and a latch portion restrains displacement of each insulating frame in a phase-to-phase direction. The latch portion includes a latch portion And a fitting hole provided on the side of the instrument case so as to fit into the protrusion.
The latch portion is constituted by a protruding portion provided on the opposite surface of the instrument case opposite to the respective insulating frame and an engaging hole provided on the insulating frame side to fit the protruding portion.
The latch portion is constituted by a flange portion provided on the opposing face of each insulating frame facing the instrument case, and an engaging plate provided on the instrument case side with a tip shape engaged with the flange portion.
In addition, the latch portion is constituted by both end portions of the opposing faces of the insulating frames facing the instrument case, and an engaging plate provided on the instrument case side and having a tip shape engaged with both end portions.

According to the vacuum circuit breaker of the present invention, the latch portions are provided at the opposed portions between the respective insulating frames and the instrument case to arrange the displacement of the insulating frames in the vertical direction. Therefore, Can be provided.

Since the insulation frame is not required to have an increased strength, the weight can be reduced, and a force in the lateral direction is not applied to the contacts of the fixed side of the vacuum valve and the connecting portion of the movable side conductor and the bushing. Can be reduced. Therefore, the size and weight of the vacuum circuit breaker can be reduced.

1 is a side view and a rear view showing a vacuum circuit breaker according to a first embodiment of the present invention.
2 is a side sectional view showing the interior of the vacuum circuit breaker of FIG.
Fig. 3 is a partially enlarged view showing a main part of Fig. 1. Fig.
4 is a plan sectional view of a vacuum circuit breaker according to a second embodiment of the present invention.
5 is a plan sectional view showing another embodiment of the vacuum circuit breaker according to the second embodiment of the present invention.

Embodiment 1

Fig. 1 is a side view of a vacuum circuit breaker according to a first embodiment of the present invention, and Fig. 1 (b) is a rear view of the circuit breaker shown in Fig. 1 (a). Fig. 2 is a side sectional view showing the inside of the vacuum circuit breaker shown in Fig. 1, and shows a state of being accommodated in a case such as a switchgear and mounted on a fixed frame. 3 is an enlarged view of an inner portion indicated by a chain line in Fig. 1. Fig.

1, the vacuum valve 2 constituting the cut-off portion of the vacuum circuit breaker 1 has a structure in which a fixed contact and a movable contact (both not shown) Are arranged and accommodated. The three-phase vacuum valve 2 is housed in an insulating frame 3 provided so as to surround the vacuum valve 2, as shown in Fig. 1 (b) . The fixed side conductor 4 connected to the fixed contact is led out from the upper side of the vacuum valve 2 in the direction orthogonal to the axis of the vacuum valve 2 and is connected to the movable contact The side conductors 5 are led out in the same direction as the fixed side conductors 4.

A contactor 6 is provided on each end of the fixed-side conductor 4 and the movable-side conductor 5. In the contactor 6, for example, a plurality of contact pieces are arranged in the circumferential direction, a spring is provided on the outer periphery thereof, and the contact piece is pressed by the spring in the center direction.

1 (a), the left side of the drawing is the front side of the vacuum circuit breaker 1. In the following description, the expressions such as the front face, the back face, the front-back direction, the left-right direction and the like are based on this front side.

The insulating frame (3) is mounted on the truck frame (7). The bogie frame 7 is provided with a wheel 7a at its lower portion so as to be movable in the front-rear direction. A face plate 7b is provided on the front side and a mechanism case 7c in which a manipulating mechanism (not shown) of the vacuum valve 2 is housed in the rear side of the face plate 7b. ).

The three insulation frames 3 for three phases are disposed rearward of the instrument case 7c of the bogie frame 7 in the left and right directions with the axis thereof directed in the vertical direction and the lower side is arranged on the bogie frame 7 Bolts or the like, and is viewed from the back side as shown in Fig. 1 (b).

Next, the internal structure of the vacuum circuit breaker 1 will be described with reference to Fig.

As shown in the drawing, the upper side connected to the fixed contact of the vacuum valve 2 is electrically connected to the fixed side conductor 4 and the fixed side conductor 4 is fixed to the insulating frame 3, 2 are mechanically fixed to the insulating frame 3.

On the movable contact side of the vacuum valve 2, on the other hand, the movable electrode rod 8 led downward is connected to the movable conductor 5 fixed to the insulating frame 3 via the flexible conductor 9, Respectively. An insulating rod 10 is connected to the movable electrode rod 8 in an axial direction and the insulating rod 10 is connected to an operating mechanism (not shown) accommodated in the mechanism case 7c via a link mechanism 11 ). The movable electrode rod 8 moves up and down via the insulating rod 10 by the operation of the operating mechanism and the movable contact of the vacuum valve 2 is driven to bring the movable electrode rod 8 into contact with the stationary contact, So that the vacuum circuit breaker 1 is opened and closed.

A case such as a switchgear in which the vacuum circuit breaker 1 is accommodated is provided with a fixed frame on which the vacuum circuit breaker 1 is placed. Fig. 2 shows a state of being mounted on the fixed frame. The bottom surface 12 of the fixed frame is provided with rails for guiding the wheels 7a of the bogie frame 7. A bushing 14 is provided on the rear wall 13 of the fixed frame. The fixed conductors 4 on the side of the vacuum valve 2 and the contacts 6 of the movable conductor 5 are fitted to the central conductor 14a of the bushing 14. [ The rear side of the upper and lower bushings 14 is connected to, for example, one main circuit bus line (not shown) and the other to a load side cable (not shown).

2 shows the connection state in which the contactor 6 and the center conductor 14a are connected to each other. However, by pulling out the handle provided on the face plate 7b of the vacuum circuit breaker 1 and pulling it forward, (14a) is disconnected, resulting in a disconnected state.

Next, the configuration of the latch portion 15 between the bogie frame 7 and the insulating frame 3, which is a feature of the present invention, will be described.

3 (a) is an enlarged view of a part III surrounded by a one-dot chain line in Fig. 1, and Fig. 3 (b) is a view in a direction of an arrow.

A columnar protrusion 16 is formed on the front surface side of the insulating frame 3 of each phase, that is, on the side opposite to the back surface of the instrument case 7c of the bogie frame 7. 3 (b), an engagement hole 17 having an inner diameter slightly larger than the outer diameter of the protrusion 16 is provided on the back surface side of the instrument case 7c. The fitting hole 17 is provided in a bent portion 7d that extends toward the back side of the box forming the instrument case 7c and bent downward by 90 degrees.

The protruding portion 16 and the fitting hole 17 constitute the latch portion 15 so that both of the protruding portion 16 and the latch portion 15 are engaged with the insulating frame 3 . That is, the insulating frame 3 is latched on the side of the bogie frame 7 in the latch portion 15 in the vicinity of the intermediate portion in the height direction, while the lower side is fixed to the bogie frame 7. [

3, the fitting hole 17 is provided on the bent portion 7d extending from the top plate of the instrument case 7c. However, the fitting hole 17 may be provided on the plate of another member, It may be installed.

Next, the operation of the latch portion 15 will be described.

As shown in Fig. 2, when the vacuum circuit breaker 1 is installed and used in a case of a switchgear or the like, the distance from the central conductor 14a of the upper bushing 14 to that of the fixed side conductor 4 and the vacuum valve 2 A current path is formed which flows to the center conductor 14a of the stationary contact and the movable contact-flexible conductor 9 -the movable conductor 5-the lower bushing 14. Since the three-phase vacuum valves 2 are accommodated in the independent insulating frame 3 and fixed and arranged in parallel, if a ground fault or the like occurs and a large short-circuit current flows in the current path, A large electromagnetic force is generated between the three-phase conductors by the current in the direction indicated by the arrow in Fig. 1 (b). Since the fixed side conductor 4 and the movable side conductor 5 are fixed to the insulating frame 3, an excessive electromagnetic force is applied to the insulating frame 3 in the up-and-down direction (left- The contact of the contactor 6 of the vacuum circuit breaker 1 with a force to displace in the upward and downward directions causes contact between the bushing 14 and the central conductor 14a to become non-uniform contact pressure The electrification performance is impaired and, in some cases, arcing may occur at the contact portion.

Thus, by providing the protruding portion 16 provided on the side of the insulating frame 3 and the latch portion 15 formed by the fitting hole 17 provided on the side of the bogie frame 7 as in the first embodiment, 3 can be restrained from being displaced in the up-and-down direction, the mechanical strength required for the insulating frame 3 can be maintained, displacement of the contactor 6 can be suppressed, and arcing at the contact portion can be prevented.

The protruding portion 16 can be formed at the same time when the insulating frame 3 is molded and the fitting hole 17 can be easily formed simply by increasing the dimension of the top plate of the instrument case 7c and drilling the hole have.

The shape of the protruding portion 16 and the fitting hole 17 is not limited to a circle but may be a square or a polygonal shape. Further, a plurality of the number may also be provided in one insulating frame as required.

It is also possible to provide the protruding portion on the side of the instrument case 7c and provide the fitting hole in each insulating frame 3. [

As described above, according to the vacuum circuit breaker of Embodiment 1, there are provided a vacuum valve for three phases, three insulation frames for housing and holding the vacuum valve in individual phases, and a mechanism case And a lower side of which is fixed to the bogie frame. The vacuum circuit breaker according to claim 1, wherein the insulating frame and the instrument case It is possible to provide a vacuum circuit breaker having an excellent mechanical strength against the electromagnetic force acting in the direction of the upper and lower sides, since the latch portions are provided in the opposing portions of the insulating frame.

In addition, since it is not necessary to increase the strength of the insulating frame more than necessary, the weight can be reduced.

In addition, since a force in the lateral direction is not applied to the contact to which the fixed side and the movable side conductor of the vacuum valve are connected to the bushing, the contact pressure can be reduced, displacement of the contact portion can be suppressed, .

In addition, since the stiffness of the bogie frame can be suppressed, the size and weight of the vacuum circuit breaker can be reduced.

Since the latch portion is constituted by the protruding portion provided on the opposing surface of each of the insulating frames facing the instrument case and the fitting hole provided on the instrument case side to fit the protruding portion, the latch portion can be constituted by a simple structure, .

Embodiment 2 Fig.

4 is a plan sectional view of a vacuum circuit breaker according to a second embodiment of the present invention. Since the vacuum circuit breaker equivalent to that of Fig. 1 of the first embodiment is viewed from the top, the same parts as those of Fig. 1 are denoted by the same reference numerals and the description thereof is omitted. The following description focuses on differences from the first embodiment.

The latch portion 15 between the insulating frame 3 and the bogie frame 7 is formed by the protruding portion 16 on the side of the insulating frame 3 and the fitting hole 17 on the side of the bogie frame 7 In this embodiment, as shown in Fig. 4, the front side of the insulating frame 3 having a substantially rectangular shape when viewed from the top, that is, the side opposite to the back side of the instrument case 7c of the bogie frame 7 The flange portion 3a of the vertical length is formed on both sides of the insulating frame 3 and the top plate of the instrument case 7c is extended toward the insulating frame 3, The engaging plate 18 having a tip shape adapted to engage the inside of the flange portion 3a is provided and the latch portion 15 is formed by engaging the tip end portion of the engaging plate 18 with the inside of the flange portion 3a .

4, the engaging plate 18 also serves as a top plate of the instrument case 7c. However, the engaging plate 18 may be formed of a member separate from the top plate and may be joined to the instrument case 7c.

Although the flange portion 3a is provided on both sides in the width direction of the insulating frame 3 in Fig. 4, the flange portion may be formed at only one position in the central portion in the width direction, So that the latch portion may be formed.

Next, another embodiment of the latch portion will be described.

5 is a plan sectional view of a vacuum circuit breaker showing another example of the latch portion. 4, the same parts are denoted by the same reference numerals and the description thereof will be omitted, and the difference from FIG. 4 will be mainly described. 5, a flange portion is not provided in the insulating frame 3, but an end portion 3b in the width direction of the insulating frame 3 having a substantially rectangular cross section is used as a latch portion on the side of the insulating frame 3, The instrument case 7c side is provided with an engaging plate 19 in which the top plate is extended toward the insulating frame 3 and the shape of the tip end portion is formed such that the entire width direction of each insulating frame 3 is sandwiched from the outside. The engaging plate 19 may be formed of a member separate from the top plate of the mechanism case 7c.

4 or 5, it is possible to prevent displacement of the insulating frame 3 in the up-and-down direction when a large current such as a short-circuit current flows in the vacuum valve 2, It is possible to prevent the occurrence of an arc at the contact portion.

The shape of the latch portion is not limited to those shown in Figs. 4 and 5, and the shape of the portion to be latched may be appropriately determined in accordance with the shape of the insulating frame side.

As described above, according to the vacuum circuit breaker of the second embodiment, the latch portion has the flange portion provided on the opposing face of each insulating frame facing the instrument case, and the engaging plate having the tip shape engaged with the flange portion and provided on the instrument case side It is possible to provide a vacuum circuit breaker excellent in mechanical strength against an electromagnetic force acting in the direction of an axis when a large current such as a short-circuit current flows, and the same effects as those of the first embodiment can be obtained.

Since the latch portion is constituted by both end portions of the opposing faces of the respective insulating frames facing the instrument case and the engaging plate provided on the instrument case side with a tip shape engaged with both ends, special processing for latching is required on the insulated frame side The above-described effects can be obtained.

1 Vacuum Breaker 2 Vacuum Valve
3 insulation frame 3a flange portion
3b End 4 Fixed side conductor
5 Movable side conductor 6 Contact
7 Bogie frame 7a wheel
7b face plate 7c instrument case
7d bending section 8 movable electrode bar
9 Flexible conductor 10 Insulation rod
11 Link mechanism 12 Floor surface
13 Rear Wall 14 Bushing
14a center conductor 15 latch portion
16 protrusion 17 fitting hole
18, 19 engaging plate

Claims (4)

A vacuum valve in three phases, three insulating frames for receiving and holding the vacuum valve separately, and a mechanism case accommodating an operation mechanism portion of the vacuum valve on the front side Wherein the three insulated frames in which the vacuum valve is accommodated are arranged in a left-right direction on the rear side of the instrument case and the lower side is fixed to the bogie frame,
A latch portion is provided at an opposed portion between each of the insulating frames and the instrument case, and the latch portion is provided with protrusions provided on opposing surfaces of the insulating frames facing the instrument case, And an engagement hole provided on the side of the mechanism case so that the latch portion restricts displacement of the insulation frames in the phase direction. A vacuum valve in three phases, three insulating frames for receiving and holding the vacuum valve separately, and a mechanism case accommodating an operation mechanism portion of the vacuum valve on the front side Wherein the three insulated frames in which the vacuum valve is accommodated are arranged in a left-right direction on the rear side of the instrument case and the lower side is fixed to the bogie frame,
A latch portion is provided at an opposing portion between each of the insulating frames and the instrument case, and the latch portion is provided with a protrusion portion provided on an opposing face of the instrument case opposite to the insulator frame, And an engagement hole provided on the side of the insulation frame so that the displacement of the insulation frames in the phase direction is restricted by the latch portion. A vacuum valve in three phases, three insulating frames for receiving and holding the vacuum valve separately, and a mechanism case accommodating an operation mechanism portion of the vacuum valve on the front side Wherein the three insulated frames in which the vacuum valve is accommodated are arranged in a left-right direction on the rear side of the instrument case and the lower side is fixed to the bogie frame,
A latch portion is provided at an opposed portion between each of the insulating frames and the instrument case; the latch portion includes a flange portion provided on an opposing face of each of the insulating frames facing the instrument case; And an engaging plate provided on the side of the mechanism case, wherein the latch portion restrains displacement of the insulating frames in a phase-to-phase direction. A vacuum valve in three phases, three insulating frames for receiving and holding the vacuum valve separately, and a mechanism case accommodating an operation mechanism portion of the vacuum valve on the front side Wherein the three insulated frames in which the vacuum valve is accommodated are arranged in a left-right direction on the rear side of the instrument case and the lower side is fixed to the bogie frame,
And a latch portion is provided at an opposing portion between each of the insulating frames and the instrument case, and the latch portion is provided with both end portions of the opposing surfaces of the insulating frames facing the instrument case, And a latching portion provided on the case side for restraining displacement of the insulating frame in the phase direction by the latch portion.

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