JP2013165596A - Switchgear - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switchgear which enables cost reduction.SOLUTION: A switchgear comprises: a switch part at least including a switch to open/close a current path; a conductor 43 led out from the switch part; a solid insulator 30 whose surface covering the conductor 43 is ungrounded; and a shield 65 which is arranged around the conductor 43 in a manner embedded in the solid insulator 30.

Description

  The present invention relates to a switchgear having a shield embedded in a solid insulator.

  As a conventional switchgear, for example, there is one described in Patent Document 1. The switch gear moves linearly and can be switched between a disconnection and a grounding position, a vacuum valve that turns on and off current in a vacuum container having a vacuum inside, a ground disconnection part, and a vacuum valve The surface of the solid insulator is set to the ground potential, the ground disconnection portion and the vacuum valve are electrically connected, and current is turned on and off in the vacuum valve. The switchgear applies a conductive paint to the surface of the solid insulator to obtain a ground potential, thereby reducing the electric field in the air outside the insulator surface and suppressing partial discharge in the air. Since the electric field in the air outside the insulator surface is reduced, for example, even if a current sensor is attached outside the insulator, partial discharge does not occur.

JP 2011-41407 A

  However, in order to apply the conductive paint to bring the surface of the solid insulator to the ground potential, not only the actual application work but also the blast treatment of the surface of the solid insulator is necessary before the application. There is a risk of increasing costs due to an increase in the number of manufacturing processes and an increase in the manufacturing period, such as the necessity of drying treatment.

  Therefore, an object of the present invention is to provide a switchgear that can reduce costs.

  In order to solve the above-described problems, a switchgear according to the present invention is provided with a switch unit that includes at least a switch that switches any one of current on / off, disconnection, and grounding, and is pulled out from the switch unit. A conductor, a solid insulator whose surface covers the conductor is ungrounded, and a shield embedded in the solid insulator around the conductor.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the switchgear which can aim at cost reduction.

FIG. 3 is a front sectional view of the switchgear according to the first embodiment and is a diagram illustrating a voltage / current input state. It is a front sectional view of the switchgear according to the first embodiment, and is a diagram showing a disconnected state of voltage and current. It is a front sectional view of the switchgear according to the first embodiment, and shows a grounded state of voltage and current. It is the figure which showed the condition of the electric field of the current sensor attachment part which concerns on Example 1. FIG. It is the figure which showed the condition of the electric field of a current sensor attachment part when there is no shield for current sensors. It is the figure which showed the structure of the attachment part of the current sensor which concerns on Example 2. FIG. It is a front sectional view of the switchgear according to the third embodiment, and shows a state in which voltage and current are applied. FIG. 6 is a front sectional view of a switchgear according to a fourth embodiment, and shows a voltage / current application state.

  Hereinafter, preferred embodiments for carrying out the present invention will be described with reference to the drawings. In addition, the following is only an example of implementation, and it goes without saying that the content of the invention is not limited to the following embodiment.

  A first embodiment will be described with reference to FIGS.

As shown in FIGS. 1 to 3, the switchgear according to the present embodiment has at least a pair of contact points that can be separated from each other, and is provided in the atmosphere with a vacuum switch 1 that switches between on and off, A ground disconnect switch 10 that can switch between three positions of disconnect and ground, a flexible conductor 15 that connects the intermediate fixed electrode 13 of the ground disconnect switch 10 and the movable side of the vacuum switch 1, and a movable holder of the vacuum switch 1 A switch unit having a vacuum switch operating rod 20 mechanically connected to 7B and a ground disconnect switch operating rod 21 mechanically connected to the movable electrode 12 of the ground disconnect switch 10; A bus bushing 40 connected to the bushing-side fixed electrode 11 of the vessel 10 and a cable bushing 42 connected to the fixed side of the vacuum switch 1. Chidanro closing dexterity bushing side fixed electrode 11 and the bus bushing 40 and the cable bushing 42 is cast integrally with the solid insulator 30.
Further, the switch part is covered with a grounded metal container 31 so that it is possible to ensure that the operator is safe without setting the surface of the solid insulator to the ground potential. The bus bushing 40 is connected to a solid insulated bus whose surface is at ground potential, and the cable bushing 42 is connected to a cable whose surface is at ground potential.

  The ground disconnect switch 10 includes a ground disconnect switch movable electrode 12 that is linearly displaced at three positions, and a bushing-side fixed electrode 11 that is electrically connected to the movable electrode 12 via the movable electrode 12 in the closed position. The intermediate fixed electrode 13 and the movable electrode 12 include a ground-side fixed electrode 14 that is electrically connected to the intermediate fixed electrode 13 through the movable electrode 12 at the ground position.

  The vacuum switch 1 includes a fixed-side electrode 6A, a movable-side electrode 6B, a fixed-side ceramic insulating tube 2A, a movable-side ceramic insulating tube 2B, a fixed-side end plate 3A, and a movable-side end plate 3B. A fixed side holder 7A connected to the fixed side electrode 6A, a movable side holder 7B connected to the movable side electrode 6B, and an arc shield 5 for protecting the ceramic insulating cylinders 2A and 2B from an arc are provided. The holder 7A is connected to the cable side conductor 43 at the center of the cable bushing 42, and the vacuum switch 1 that can supply power to the load side is connected to the movable side end plate 3B and the movable side holder 7B. The movable side electrode 6B and the movable side holder 7B can be moved in the axial direction while maintaining the internal vacuum by the bellows 9, thereby switching between the on state and the cut off state. That. In addition, a bellows shield 8 is provided in the vicinity of the connection portion between the bellows 9 and the movable electrode 6B in order to protect the bellows 9 from an arc or the like during opening and closing, and the concentration of the electric field at the end of the bellows 9 is alleviated. You can also. A fixed-side electric field relaxation shield 4A is arranged around the fixed-side ceramic insulating cylinder 2A to alleviate electric field concentration at the connection portion with the fixed-side end plate 3A. A movable-side end is arranged around the movable-side ceramic insulating cylinder 2B. In order to alleviate the electric field concentration at the connection portion with the plate 3B, the movable-side electric field relaxation shield 4B is disposed. As a material for the vacuum switch operating rod 20, the ground disconnect switch operating rod 21, and the solid insulator 30, an epoxy resin having good mechanical strength and insulating properties and good moldability is suitable.

  The grounding disconnect switch 10 includes a bushing-side fixed electrode 11 connected to the busbar side via a busbar-side conductor 41 at the center of the busbar bushing 40, a grounding-side fixed electrode 14 having a ground potential, and their An intermediate fixed electrode 13 that is located in the middle and electrically connected to the movable holder 7B on the vacuum switch side via a flexible conductor 15 is provided, and the inside is air-insulated. These fixed electrodes 11, 13, and 14 are arranged on a straight line, and the inner diameters are all equal. As shown in FIG. 1 to FIG. 3, the grounded disconnect switch movable electrode 12 moves in the ground disconnect switch 10 with respect to each fixed electrode 11, 13, 14, thereby closing, disconnecting, and grounding at three positions. It becomes possible to switch to. 1 shows a current application state, FIG. 2 shows a disconnection state, and FIG. 3 shows a grounding state. The ground disconnecting switch movable electrode 12 is connected to an operating mechanism (not shown) and an operating rod 21. The ground disconnect switch movable electrode 12 is provided with a spring contact 16 to ensure electrical connection with the fixed electrodes 11, 13, and 14.

  As shown in FIG. 1 to FIG. 3 or FIG. 4, the cable bushing 42 includes a solid insulator 30 covering the cable side conductor 43 at the center of the cable bushing 42. The mounting portion 51 is provided, and the current sensor 50 is disposed on the mounting portion 51. Between the cable-side conductor 43 and the current sensor 50, a current sensor shield 60 is embedded in the solid insulator 30. Furthermore, in order to alleviate the triple junction electric field of the cable head part 81, the solid insulator 30, and the air, the tip of the cable is located on the tip side in the direction away from the switch part among the ends of the current sensor shield 60. A cable side embedded shield 61 embedded in the solid insulator 30 is disposed around the site. The current sensor 50 includes a current measuring current transformer (CT). Further, as shown in FIG. 1, one end of a capacitor 70 is connected to the current sensor shield 60, so that the voltage can be measured from the potential divided value based on the capacitance. The other end of the capacitor 70 is set to the ground potential as a reference potential.

  In the bus bushing 40, the solid insulator 30 covers the bus-side conductor 41 in the center of the bus bushing 40. In order to reduce the triple junction electric field between the solid insulator bus adapter 83 and the solid insulator and air, the solid insulation is provided. A bus-side embedded shield 66 is disposed in the object 30.

  Further, as shown in FIG. 1, a stepped step portion 59 is provided in the solid insulator 30, and portions parallel to the extending direction of the metal container 31 are formed on both sides. Thereby, it becomes easy to attach the grounded metal container 31.

  The state of the electric field at the mounting portion of the current sensor 50 when the current sensor shield 60 of FIG. 1 is present is shown in FIG. 4, and the electric field of the current sensor mounting portion when there is no current sensor shield 60 for comparison with FIG. This situation is shown in FIG.

  As shown in FIG. 4, by providing the current sensor shield 60, the electric field lines 90 in the aerial part 91 between the current sensor 50 and the surface of the solid insulator are reduced, the electric field on the surface of the solid insulator can be reduced, and partial discharge is performed. Can be suppressed.

  On the other hand, when there is no current sensor shield 60 as shown in FIG. 5, the electric lines of force 90 existing in the aerial part 91 between the current sensor and the solid insulator surface increase. That is, in this case, the electric field is concentrated and partial discharge is likely to occur.

  The material of the current sensor shield 60 is preferably aluminum which is a non-magnetic material. However, by making the current sensor shield 60 small, it is also possible to arrange iron or stainless steel which is a magnetic material.

  In the above description, the embedded shield is embedded in the solid insulator 30. However, even if the embedded shield is disposed on the surface of the solid insulator, the air shield 91 between the current sensor 50 and the surface of the solid insulator is disposed. Electric field lines can be reduced, and partial discharge can be suppressed.

  According to the present embodiment, the current sensor shield 60 is disposed between the cable-side conductor 43 and the current sensor 50 so as to be embedded in the solid insulator 30, and the air gap between the current sensor 50 and the solid insulator surface is arranged. The electric lines of force in the middle portion 91 are reduced, the electric field on the surface of the solid insulator can be reduced, and partial discharge can be suppressed. Therefore, it is not necessary to provide a ground potential on the surface of the solid insulator, and it is possible to realize cost reduction by reducing the number of parts and manufacturing processes.

  A second embodiment will be described with reference to FIG. In addition, about the location which overlaps with Example 1, description here is abbreviate | omitted.

  FIG. 6 shows the shape of a current sensor shield for improving heat dissipation. In the first embodiment, the shape of the current sensor shield is described as being a straight line without providing a bent portion. However, in this embodiment, the current sensor shield 60 is provided with a bent portion as shown in FIG. In the current sensor shield 60, by bringing a part close to the cable side conductor 43, heat from the current cable side conductor 43 is easily transmitted to the current sensor shield 60 in the close part, thereby improving heat dissipation. Is possible.

  Since only a part of the current sensor shield 60 is brought close to the cable side conductor, the insulation breakdown between the current sensor shield 60 and the cable side conductor 43 can be minimized.

  A third embodiment will be described with reference to FIG. In the following description, only differences from the above-described embodiments will be described, and description of overlapping points will be omitted.

  As shown in FIG. 7, the switchgear according to the present embodiment includes a current sensor 55 in a bus bushing 40 covered with a solid insulator so that the current sensor 55 described in each of the above embodiments can also be attached to the bus. The mounting portion 71 is provided, and the current sensor 55 is disposed on the mounting portion 71. A current sensor shield 65 is embedded between the bus-side conductor 41 and the current sensor 55 so as to be embedded in the solid insulator 30. Further, in order to alleviate the triple junction electric field of the solid insulation bus 82, the solid insulator 30, and the air, the tip of the solid insulation bus is located on the tip side in the direction away from the switch portion among the ends of the current sensor shield 65. A bus-side embedded shield 66 embedded in the solid insulator 30 is disposed around the position.

  There is a current sensor shield 65 between the bus-side conductor 41 and the current sensor 55, and the bus-side conductor 41 and the current sensor shield 65 are arranged in the solid insulator 30. As a result, current measurement on the bus side is possible. Further, as in the above embodiments, the potential can be measured by connecting one end of the capacitor 70 in series to the current sensor shield 65.

  Hereinafter, the fourth embodiment will be described with reference to FIG. 8. In the following, only points different from the above-described embodiments will be described, and description of overlapping points will be omitted.

  As shown in FIG. 8, in the switchgear according to the present embodiment, the coupling shield 63 including the current sensor shield 60 and the cable-side embedded shield 61 shown in the first embodiment is embedded in a solid insulator. Has been placed. It is not necessary to perform casting after manufacturing two parts and placing them at predetermined positions, and the number of parts and man-hours can be reduced.

  In each of the above embodiments, only the case where the current sensor is used has been described. However, even when the current sensor is not present, there is a shield that is embedded in the solid insulator around the conductor. And the effect which can suppress the partial discharge of the epoxy resin surface is acquired. In particular, since the epoxy resin surface is not grounded, when connecting a cable with a grounded surface or when a grounding plate is installed, the resin surface of floating potential-ambient gas-surface grounding at the contact part Triple junctions (points that serve as boundaries between the three members) are formed in contact with the cable or the ground plate, and electric field concentration tends to occur at the triple junctions. Therefore, when a shield is arranged on the inner side (in the solid insulator) of the triple junction, partial discharge on the surface of the epoxy resin can be effectively suppressed.

  In each embodiment, the case where the current sensor is arranged only on either the bus side or the cable side has been described, but it is of course possible to arrange the current sensor on both sides.

DESCRIPTION OF SYMBOLS 1 Vacuum switch 2A Fixed side ceramic insulation cylinder 2B Movable side ceramic insulation cylinder 3A Fixed side end plate 3B Movable side end plate 4A Fixed side electric field relaxation shield 4B Movable side electric field relaxation shield 5 Arc shield 6A Fixed side electrode 6B Movable side electrode 7A Fixed side holder 7B Movable side holder 8 Bellows shield 9 Bellows 10 Ground disconnect switch 11 Ground disconnect switch bushing side fixed electrode 12 Ground disconnect switch movable electrode 13 Ground disconnect switch intermediate fixed electrode 14 Ground disconnect switch ground fixed electrode 15 Flexible conductor 16 Spring contact 20 Vacuum switch operating rod 21 Ground disconnect switch operating rod 30 Solid insulator 31 Metal container 40 Busbar bushing 41 Busbar conductor 42 Cable bushing 43 Cable conductors 50 and 55 Current sensors 51 and 71 Mounting part 60, 65 Current sensor Vapor between the use shielded 61 cable side embedded shield 63 coupled shield 66 bus side embedded shield 70 capacitor 80 Cable 81 Cable head portion 82 a solid-insulated bus bars 83 solid insulated bus adapter 90 electric power line 91 current sensor and solid insulator surface Chubu

Claims (8)

  A switch part having at least a switch for switching on / off / disconnection / grounding of current, a conductor drawn from the switch part, a solid insulator whose surface covering the conductor is ungrounded, A switchgear comprising a shield disposed around the conductor and embedded in the solid insulator. The switchgear according to claim 1,
Furthermore, a current sensor arranged around the conductor is provided,
The switchgear is provided with a shield embedded between the conductor and the current sensor and embedded in the solid insulator. The switchgear according to claim 1 or 2,
The switchgear is characterized in that the shield is connected to one end of a capacitor. The switchgear according to any one of claims 1 to 3,
The switchgear is covered with a metal container, and the metal container is fixed to a stepped step portion provided on the solid insulator. The switchgear according to any one of claims 1 to 4,
The switchgear is characterized in that a part of the shield is bent toward the conductor. The switchgear according to any one of claims 1 to 5,
The switchgear is characterized in that the conductor is connected to a bus or a cable. The switchgear according to claim 6, wherein
An embedded shield embedded in the solid insulator is further disposed around a portion connected to the bus bar or cable on the distal end side in a direction away from the switch portion among the end portions of the shield. The switchgear featured. The switchgear according to claim 7,
The switchgear, wherein the shield and the embedded shield are integrally coupled.