KR100205675B1 - Power board - Google Patents

Abstract

In the switchboard of the present invention, a circuit breaker having an electrical unit and a cable unit which are stacked in at least one stage or more formed in a box body, a three-phase longitudinal busbar disposed between the electrical unit and the back of the box body, and having a breaker in the electrical unit A first movable contactor which is stored in the electrical unit, and which is contacted with the longitudinal bus bar provided at the front end of the breaker to be opened and closed in the same direction as the movement direction of the breaker, a second movable contactor provided at the rear end of the breaker, and the second movable contact. In order to downsize the switchboard by contacting the contactor and covering the three-phase transverse conductor disposed between the electric unit and the cable unit with an insulating layer, providing a contact layer on the surface of the insulating layer, and reducing the height dimension of the box body. have.

Description

switchboard

1 is a front view of a multi-stage switchgear shown as an embodiment of the present invention.

2 is a cross-sectional view taken along the line II-II of FIG.

FIG. 3 is a cutaway perspective view of a portion cut along the line III-III of FIG. 2;

4 is a side view of FIG. 1; 5 is a circuit diagram showing the electrical circuit of FIG.

6A to 6D are exploded perspective views showing main parts of the multi-stage switchgear of FIG.

7 and 8 are perspective views showing the main portion near the power supply disconnection unit.

9A and 9B are cutaway perspective views and side cross-sectional views showing a part of the load-side disconnection unit cut out.

10 is a cross-sectional view of a switchboard of another embodiment.

* Explanation of symbols for main parts of the drawings

1: box body 1A: box body side

1B: Back side of box body 2: Door

3A, 3B: Partition plate 3C: Support plate

4: electric unit 5: cable

6: busbar unit 7: power bus

8: longitudinal bus 8A: insulation shell

10: bus bar insulation unit 13: connection unit

18: fixed contactor 20: vacuum circuit breaker

21: movable contact 23A: roller

25A: Load 38: Cable Head

40: ground metal gun 43: load cable

The present invention relates to a switchgear with improved arrangement of main circuit conductors such as power supply side conductors, load side conductors and the like. In general, a power receiving facility has a plurality of switchboards connected in parallel to a power bus. Each switchboard has been connected to the load via a load cable. The switchgear forms an electrically conductive unit on the front side and the back side via a partition plate provided inside the box body. A power supply side disconnection unit and a load side disconnection unit are provided in the partition plate.

The power supply disconnection unit on the conductive unit side and the power supply bus line are connected, and the load cable is connected to the load side disconnection unit. The breaker and both ends of the circuit are electrically folded by entering the breaker into the electrical chamber. The switchboard has a drawback in that the number of switchboards increases when the demand for load supply power increases and the number of switchboards increases. Therefore, as a measure for reducing the number of heat releases, for example, as described in Japanese Patent Application Laid-Open No. 60-25305, the box body is partitioned into three to four stages up and down, and an electrical unit is stacked on each partition stage. Single-switch distribution panels have been proposed.

This single-stage switchgear is equipped with a partition plate in the box body, and in the conductive unit on the rear surface of the partition plate, the sequential depth is widened from the lower side to the upper side so that the load cables do not overlap each other. Wiring work is facilitated.

However, as the number of steps increased, the depth dimension of the box body increased, and it was difficult to reduce the installation area compared with the reduction of the hot spot. SUMMARY OF THE INVENTION An object of the present invention is to provide a switchgear in which the installation area does not increase even if the volume increases. Another object of the present invention to provide a switchgear easy to check and repair. In order to achieve the above object, the switchboard of the present invention is a cable unit provided on at least one side of the left side and the right side of the electrical unit and the electrical unit formed in at least one stage formed in the box body, and the rear surface of the electrical unit and the box body. A breaker having a longitudinal busbar disposed between the first and second busbars, a breaker housed in the electric unit, and a first busbar provided to the breaker part provided in the breaker to open and close in the same direction as the moving direction of the breaker in the electric unit. The second movable contactor installed at the rear end of the movable contactor and the disconnecting unit and the second movable contactor are folded together, and the three-phase transverse conductor disposed between the electric unit and the cable unit and the three-phase transverse conductor are covered. The purpose is to provide a ground layer on the surface of the insulating layer.

As a result, since the charging current in the insulating layer flows from the ground layer to the ground, no charging voltage is applied to the surface of the insulating layer, and an insulation gap between the insulating layer and the electric unit is not necessary, so that the height dimension of the switchboard is increased accordingly. It can be reduced.

Best Mode for Carrying Out the Invention Embodiments of the present invention will be described below with reference to the drawings.

1 to 9 show the multi-stage switchgear of the present invention and are constructed as follows.

The box body 1 formed by folding the steel sheet has an insertion opening on the front side, and a door 2 freely opened and closed is provided on the left and right side surfaces 1A of the insertion opening of the box body 1. Two partition plates 3A and 3B are provided in a box body in which the door 2 is opened. An electric unit 4 is formed between the partition plate 3A and the partition plate 3B. A cable unit 5 is formed between the partition plates 3A and 3B and the box body side surface 1A. In the electric unit 4, the partition plate 3A is provided with six support plates 3C in the longitudinal direction between the partition plate 3B, and forms the electric unit 4 filled in six stages. The cable unit 5 is formed adjacent to the left and right sides of each unitary electric unit 4.

An electric circuit unit is formed on the upper side of the electric unit 4 and the cable unit 5 together with the busbar unit 6 as shown in FIGS. 3 and 5. The busbar unit 6 connects the three-phase power busbar 7 and the longitudinal busbar 8. The longitudinal busbars 8 have been arranged along the stacking direction of the six-stage electrical unit 4.

As the vacuum circuit breaker 20 moves in the electric unit, the vacuum circuit breaker 20 electrically folds the longitudinal bus 8 and the yellow conductor 32. The three-phase yellow conductor 32 is disposed between the electric unit 4 and the cable unit 5. The electrical unit side end of the three-phase conductor 32 is folded to the vacuum circuit breaker 20, and the cable unit side end is connected to the load cable 43 via the cable head 38. Each phase of the power source busbar 7 is arranged in a direction orthogonal to the moving direction by the vacuum circuit breaker 20 in the busbar unit, and the power unit busbar end of the electric unit side is connected to one end of the longitudinal busbar 8.

One end of the longitudinal busbar 8 extends from above the electric unit 4 to the back side of the box body and is bent downward in the middle so that the other end extends in the stepwise direction of the electric unit 4. As shown in FIGS. 7 and 8, the longitudinal busbar 8 is a band of a dimension in which the conductive member is covered with an insulating sheath 8A and the thickness L ₁ is narrower than the width L ₂ . A phase conductor or boot bar is used. And pokbu (L ₂₎ is disposed in a direction opposed to the electrical unit (4) kinds of bus bars (8) has been supported by the bus-side insulating unit (10). The busbar side insulating unit 10 is disposed between the electric unit 4 and the box body back surface 1B, and is supported on the partition plates 3A and 3B by fixing means such as screws, and the insulating member, for example, epoxy. It is comprised by resin.

As shown in FIGS. 6A and 7, the bus-side insulation unit 10 surrounds the periphery of the back surface 11 corresponding to the back surface 1B of the box body with the side wall 12 and the connection unit 13 therein. Forming.

The connecting unit is partitioned by two interphase insulating barriers 12D to form three connecting units 13. The upper wall and the lower wall 12A extend from the left and right side walls 12B to abut the partition plate 3B, and the upper and lower walls 12A are provided on the partition plate 3A by fixing means. Moreover, the pressure-resistant path 14 surrounded by the upper and lower side walls 12A, the left and right side walls 12B, the partition plates 13A and 13B, and the box body back surface 1B is formed. In the pressure-resistant path 14, a closing plate 15 is provided on a part of the surrounding surface other than the left and right side walls 12B, for example, the box body rear surface 1B. As shown in FIG. 4, the closing plate 15 forms a through hole in the box body 1B, and closes the through hole with a closing plate. The closing plate acts to close the through hole by normal pressure and open when the pressure in the pressure discharge path increases. The mounting sheet 16 provided on the rear surface of the connecting unit has a screw hole therein. The position of the mounting sheet 16 is slightly moved upwards (may be lower) than the center of the connection unit 13, and is installed. Through-holes 17 are formed in the upper and lower side surfaces 12A of the connecting unit 13. The longitudinal bus bar 8 which has passed through this through hole 17 is attached to the mounting sheet 16 by a clamping means such as a screw. A part of the longitudinal busbar 8 in the connection unit forms the first fixed contact 18 in which the insulating shell 8A is removed to expose the conductive member.

The first fixed contact 18 is in electrical contact with the first movable contact 21 of the vacuum circuit breaker 20. When the mounting sheet 16 is arranged in a folded position, the length between the mounting sheet 16 and the lower through hole 17 is smaller than the length of the longitudinal busbar 8 between the through holes in the absence of the mounting sheet 16. Since the bus bar size can be shortened, there is an advantage that the first movable contactor 21 is not deformed by the pressure when the first movable contactor 18 comes into contact with the first fixed contactor 18. In addition, when the thickness L ₁ of the first fixed contactor 18 is folded with the first movable contactor 21, the width portion L ₂ may be reduced in size in the depth direction as compared with the width of the first movable contactor 21. Can be.

The vacuum circuit breaker 20 will be described with reference to FIGS. 6C and 7. The trolley | bogie 23 provided with the roller 23A is provided with the breaker side insulating unit 24 which consists of an insulating member. In the unit, a shut-off part 25 made of a three-phase vacuum valve is arranged in the horizontal direction. Grooves 27 are formed between the side walls 26 of the insulating unit between the respective blocking portions. The groove 27 fits into the interphase insulating barrier 12D shown in FIG. Although not shown inside the breaker 25, a pair of electrodes are arranged correspondingly, and the rod 25A extends out of the breaker from each electrode.

When one movable side rod is moved, the other electrode is moved and opened and closed from one electrode. In general, the vacuum circuit breaker is longer than the height dimension in the direction perpendicular to the rod movement direction, that is, the opening and closing direction of the blocking portion. For example, the dimension of the opening-closing direction and the height direction of a breaking part is 3: 1 ratio. In the present invention, the blocking section 25 is arranged to be opened and closed in the same direction as the moving direction of the vacuum circuit breaker 20 in the electric unit. The first movable contact 21 and the second movable contact 22 are provided on the front rod 25A and the rear rod of the breaking section 25.

The first movable contactor is folded to the first fixed contactor 18. The second movable contact 22 extends above the first movable contact 21 and has an open end in the depth direction, and the second movable contact 22 folds to the second fixed contact 31 shown in FIGS. 6 to 9. The second fixed contact 31 is provided in the load side disconnection unit 30. And the withdrawal positions of the first movable contactor 21 and the second movable contactor 22 are arranged by knitting in the up and down direction when viewed from the insertion port side to reduce the depth dimension of the blocking portion 25, but the left and right directions or the inclined direction The same effect can be achieved even if it arrange | positions.

Moreover, in the present invention, the rod on the second movable contactor side is moved to facilitate adjustment of the rod movement speed and the like from the door side. The load side disconnecting unit 30 is disposed between the electric unit 4 and the cable unit 5 and is supported between the partition plates 3A and 3B and is configured as follows. Three-phase transverse conductors 32A, 32B, and 32C are disposed between the electric unit 4 and the cable unit 5. Branch conductors 33A to 33C are in contact with the transverse conductors 32A to 32C on the electrical unit side.

Further, the transverse conductors 32A to 32C on the cable unit side are bent toward the door side to form protruding conductors 34A to 32C. Each of these transverse conductors 32, branch conductors 33, and protruding conductors 34 is covered with an insulating resin, for example, an epoxy resin to form a fixed side insulating layer 35. Three load connecting units 36 are formed at positions corresponding to the second movable contacts 22 of the fixed side insulating layer 35. Second fixed contacts 31A, 31B and 31C are disposed in the load connection unit 36. Each of the fixed contacts 31A to 31C is formed at the front end of the branch conductors 33A to 33C and folds to the second movable contact 22 at the thickness portion L ₁ like the first fixed contact 18. .

As for the cable actual side of the fixed side insulating layer 35, as shown to FIG. 9A and 9B, the connection part 37 is provided in the front-end | tip of protrusion conductor 34A-34C. In the connecting portion 37, an insertion plug type cable head 38 is inserted. The insertion plug type cable head 38 is molded of an insulating resin member, for example, insulating rubber, to form the insertion side insulating layer 39.

The ground metal layer 40 is coated on the upper and left and right sides of the fixed side insulating layer surface on the electric unit side. In other words, a ground layer is provided on the surface of the base bus not facing the longitudinal busbar and the second movable contact. Each surface of the fixed side insulating layer 35 and the insertion side insulating layer 39 on the cable unit side is covered by the ground metal layer 40 except for the contact surfaces of the both insulating sides 35 and 39. The fixed side insulating layer on the cable unit side may be provided with a ground metal layer on the upper and lower surfaces.

The ground terminal 41 is grounded via a ground wire 41A. The insertion part 42 is provided in the cable head, the insertion part 42 is connected to the load cable 43, and the insertion part 42 is inserted into the connection part 37. The gap 100 is formed between the insulating layer 39 and the insertion side insulating layer 39, but the horizontal line 44 wound around each of the insulating layers 35 and 39 electrically connects the ground metal layers between the insulating layers. This prevents the ground metal layer 40 from being electrically blocked, thereby preventing electric shock when the cable head 38 is attached or detached.

Instead of the horizontal diameter line, a contact piece may be provided on one side of the insulating layers 35 and 39 to connect both ground layers. The directional video current transformer 45 and the current transformer 46 are detachably attached to the fixed side insulating layer 35. Since the directional image current transformer 45 is disposed in the fixed side insulating layer 35 between the electric unit 4 and the cable unit 5, a separate type is used.

Each current transformer 46 may be arranged along the direction in which the vacuum circuit breaker 2 is inserted, as shown in FIG.

Next, the effect | action and effect by the switchboard of this invention are demonstrated.

1. In the present invention, the moving direction of the vacuum circuit breaker 20 and the opening and closing direction of the breaker 25 are arranged in the same direction in the electric unit. For this reason, the height dimension of the vacuum circuit breaker 20 can be made lower than the arrangement | positioning direction of the interruption | blocking part 25 in the height direction, and the load side disconnection unit unit between the electric unit 4 and the cable unit 5 ( 30) can be deployed. As a result, the load-side disconnecting unit 30 can be arranged in the above-described place, as compared with the arrangement of the load disconnecting unit and the cable unit in the electric unit depth direction as in the prior art. Despite being placed in the depth direction, the depth of the box body could be reduced by about 20%.

2. Review the reduction in height dimension again.

An insulator capacitance exists between the fixed side insulating layer 35 and the insertion side insulating layer 36 covering the transverse conductor 32, the branch conductor 33, the load cable 43, and the like. Leakage current from each conductor is charged with an insulating capacitance. Since the charging current flows to the ground via the ground metal layer 40 and the ground line 41A of the present invention, the potential difference is almost zero. For this reason, almost no charging voltage is applied to the surface of the ground metal layer 40, and the gap formed between the load-side disconnection unit 30, the support plate 3C, and the ceiling plate 3D is hardly necessary, and the vacuum is not required. Since the breaker 20 should be provided with a gap which does not prevent the entry and exit of the circuit breaker 20, the dimensions of the stacking direction of the electric unit 4 and the cable unit 5 can be reduced, and the cable unit 5 You can shrink the whole. Moreover, even if a worker contacts the load side disconnection unit 30, there is no electric shock and it is safe.

3. In the present invention, the interphase insulating barrier 12D is fitted to the groove 27 in a state where both movable contacts 21 and 22 are in contact with both fixed contacts 18. As a result, the creepage insulation distance between the first movable contactors 21 of each phase becomes significantly longer, and the box width dimension can be reduced by that.

4. According to the present embodiment, when the door 2 is opened when the connection portion 37, the cable head, or the like is mounted, repaired or inspected, the cable head or the like can be immediately seen, and the door faces the aisle when the door is opened. Therefore, the work is remarkably easy due to the wide working place and the like.

In addition, when the cable head 38 is attached to or detached from the connecting portion 37, the fixed side insulating layer 35 and the movable side insulating layer 36 have no potential difference, so that electric shocks are prevented and work can be safely performed. In addition, three load cables 43 of the six-stage electrical unit 4 are drawn out to the left and the right of the six-stage electrical unit 4, and distributed to each cable unit 5 so as to distribute the load cables 43 in each cable unit. The arrangement of the wires was made small, the work space in the cable unit was increased, and the wiring work of the load cable 43 can be facilitated. In the present embodiment, when the worker mounts the directional video current transformer 45 and the current transformer 46 on the fixed side insulating layer 35, the current transformers 45 and 46 are inserted into the fixed side insulating layer bar 5, respectively. Since each current transformer can be supported by the fixed side insulating layer 35, the assembly work is remarkably easy since the worker does not need the jig which supports or supports each current transformer at the time of mounting.

In this case, the video current transformer uses a split type, and in the present invention, the detection current range of the ground fault current can be widened as much as that provided in the fixed side insulation layer 35, compared to the conventional current transformer mounted on the load cable. Can be.

5. In this embodiment, the abnormal pressure when the flashover occurs due to the impossibility of blocking in the switchboard is discharged as shown in FIG. 4 and FIG. That is, when the gas ionized by the short circuit accident in the circuit breaker 20 generate | occur | produces, the ionization gas P opens through the pressure-pressure path 14, and the closing plate 15 opens like a broken line, and discharges pressure to the outside, By preventing P from returning between the power supply side insulation unit 10 and the box body back surface 1B, the short circuit is prevented from directly shorting in the busbar unit 6 between the longitudinal busbars, thereby preventing the expansion of an accident. In addition, the above embodiment has been described with respect to a multi-stage switchgear, but can also be used for a switchboard that is not a normal one. As described above, the switchboard of the present invention can reduce the dimensions of the depth, the width, and the height, thereby miniaturizing the entire switchboard and at the same time having the effect of being safe.

Claims (7)

A longitudinal bus arranged in the box body, a plurality of electrical units stacked along a plurality of vertical busbars, a cable unit formed on at least one side of the left and right sides of the electrical unit, and a load side conductor disposed in the electrical unit and the cable unit ( A switchgear having a transverse conductor) and a circuit breaker having a circuit breaker which is moved in the electric unit and electrically opens and closes the longitudinal bus and the load-side conductor (cross conductor), wherein one side of the circuit breaker opens and closes in the same direction as the moving direction of the circuit breaker. Load side conductor (lateral side) in which contactor (first movable contactor) is installed on the longitudinal busbar, and the other side contactor (second movable contactor) of the breaker on one side corresponding to the upper and lower surfaces of the circuit breaker than one side contactor (first movable contactor) Electrically open and close the load side conductor (cross conductor) to the cable unit and cover the load side conductor (cross conductor) with an insulating layer, and on the opposite side to the breaker of the insulating layer. Switchboard characterized in that a resin layer. The switchgear according to claim 1, wherein said second movable contactor is placed on a driving side. According to claim 1, wherein each of the three-phase transverse conductor in the cable unit protrudes the projection conductor arranged in the direction of the unit insertion opening side, the cable head having a load cable is connected to the connecting portion provided at the tip of the projecting conductor, A switch panel in which the projecting conductor and the cable head are covered with a fixed side insulating layer and an insertion side insulating layer, and grounding layers are provided on both insulating layers. The switchgear according to claim 1, wherein an image transformer and a current transformer are mounted on the insulating layer and the ground layer. The switchgear according to claim 1, wherein the three-phase transverse conductors arranged in the multistage units are alternately arranged so as not to overlap with the adjacent end in the cable unit. 2. The breaker according to claim 1, wherein the first and second movable contactors are provided at the front and rear ends of the breaker to move in the same direction as the opening and closing direction of the breaker, and the breaker having a moving direction dimension longer than the right-angle dimension. Switchboard. The switchboard according to claim 1, wherein the second movable contactor is arranged by knitting on one side in a direction perpendicular to or inclined with respect to the first movable contactor.

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