JP2004048929A - Vacuum switchgear - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent grounding from occurring following generation of metallic vapor. <P>SOLUTION: This switch gear accommodates disconnectors 58, 60 and a breaker 62 in a vacuum vessel 10; the disconnector 58 is connected to a cable head 50 and the breaker is connected to a cable head 52; an electrode shield 182 is arranged around a movable electrode 176 and a fixed electrode 178 of the disconnectors 58, 60, and insulation shields 184, 186 are arranged around the electrode shield; the shield 184 is attached to a shield 172; the insulation shield 186 is inserted in a shield 188; the insulation shield 184 is connected to the shield 172; the insulation shield 186 is inserted in the shield 188; the spattering of the metallic vapor generated from the movable electrode 176 and the fixed electrode 178, or a movable electrode 170 and a fixed electrode 196 is prevented by the electrode shield 182, the insulation shields 184, 186 and the shield 172, thus preventing the vacuum vessel 10 from grounding due to the generation of the metallic vapor. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a vacuum switchgear, and more particularly, to a vacuum switchgear having a plurality of switches housed in a vacuum container and suitable for use as a power receiving and distribution facility of a power system.
[0002]
[Prior art]
A switchgear is provided in the power distribution system of the power system as one element of the power distribution equipment. Conventionally, air-insulation type switch gears have been widely used as this type of switch gear. However, in order to reduce the size, SF is used as an insulating medium. ₆ A gas-insulated type using a gas has been adopted. However, if the insulating medium is SF ₆ Since the use of gas may adversely affect the environment, in recent years, a vacuum insulation system using vacuum insulation has been proposed as an insulation medium.
[0003]
As a switchgear of the vacuum insulation type, for example, as described in JP-A-2000-268865, a main circuit opening / closing unit in which a fixed electrode and a movable electrode are arranged opposite to each other is provided in a vacuum container. Multiple pairs are accommodated, the movable electrode is connected to the bus-side conductor, the fixed electrode is connected to the load-side conductor, each main circuit opening / closing part is covered with an arc shield, and each bus-side conductor is connected via a flexible conductor It is configured to be. According to this switchgear, since the vacuum insulation system is employed, the insulation distance can be made shorter than in the gas insulation system, and the switchgear can be made compact.
[0004]
[Problems to be solved by the invention]
In the above prior art, since each main circuit opening / closing part is covered with an arc shield, a trip operation is performed at the time of a short circuit accident or the like, and when the movable electrode and the fixed electrode separate from each other, metal vapor is released from each electrode. , The metal vapor can be shielded by the arc shield. However, when a part of the metal vapor scatters from the gap of the arc shield and adheres to the vacuum container when the vacuum container is grounded, a current flows from the electrode to the metal vapor via the vacuum container to the ground point, and the ground is grounded. Tangles will occur.
[0005]
Further, in the prior art, the load-side conductor is connected to the load-side electrode rod, a part of the load-side electrode rod is protruded from the vacuum vessel, and the protruding portion is covered with a cylindrical insulator, and the cylindrical insulator is Is fixed to the wall surface of the vacuum vessel, and the other end is sealed with a sealing member, so that a vacuum gap is formed between the cylindrical insulator and the load-side electrode rod. That is, a vacuum gap is provided between the cylindrical insulator and the load-side electrode bar in order to reduce electric field concentration caused by a difference in dielectric constant between the metal and the insulator.
[0006]
However, to form a vacuum gap between the cylindrical insulator and the load-side electrode rod, it is necessary to increase the vacuum gap to alleviate the electric field concentration. The diameter of the entire cable head, including the cable head, is increased, so that the occupied space is increased and workability is reduced. In addition, when the switch is turned on, the shock generated when the movable electrode comes into contact with the fixed electrode is transmitted to the sealing member via the load-side electrode rod, and the pulling force in the opposite direction is applied to the sealing member and the cylindrical insulator. The strength of the joint surface between the cylindrical insulator and the sealing member may be reduced.
[0007]
An object of the present invention is to prevent a ground fault phenomenon from occurring due to generation of metal vapor.
[0008]
[Means for Solving the Problems]
In order to solve the above problem, the present invention provides a vacuum vessel to be grounded, a movable electrode held by a movable electrode rod, and a fixed electrode held by a fixed electrode rod facing each other, and is placed in the vacuum vessel. A plurality of stored switches, one or two or more bus conductors connected to the movable electrode rod or fixed electrode rod of each switch, and a part thereof connected to the movable electrode rod of each switch. A plurality of operating rods connected to an operating device outside the vacuum vessel, a plurality of load-side rods connected to fixed electrode rods of the respective switches and partially protruding outside the vacuum vessel, A plurality of insulating bushings disposed over the inside and outside of the container and covering the periphery of each of the load-side rods, wherein each of the switches is disposed around the movable electrode and the fixed electrode, and From the fixed electrode A tubular electrode shield to prevent scattering of metallic vapor raw, which is constituted of a vacuum switchgear comprising been configured to include a cylindrical insulating shield covering the periphery of the electrode shield.
[0009]
In configuring the vacuum switchgear, the bus conductor may be fixed to a vacuum vessel, and the movable electrode rod of each switch may be connected to the bus conductor via a flexible conductor.
[0010]
In configuring each of the vacuum switch gears, the following elements can be added.
[0011]
(1) The flexible conductor includes a pair of fixing portions fixed to the one of the bus bar conductors and the one of the movable electrode rods, respectively, and the one of the flexible conductors based on an axis of the one of the movable electrode rods. A fixed portion and a pair of curved portions that are separately arranged at both ends of the other fixed portion and connect the one fixed portion and the other fixed portion with curved paths, respectively, the pair of fixed portions; An operation rod insertion hole is formed in a fixing portion fixed to any one of the bus conductors.
[0012]
(2) The pair of curved portions of the flexible conductor are formed by alternately overlapping different metals.
[0013]
(3) a folding connection conductor connected to one bus conductor of the two or more bus conductors, and a folding flexible conductor connected to the other bus conductor of the connection conductor and the two or more bus conductors; A folding support rod connected to the folding connection conductor and fixed to the vacuum vessel, for urging the folding connection conductor toward the one bus conductor, and the folding flexible conductor, A pair of fixing portions respectively fixed to the other busbar conductor and the folding connection conductor; and a pair of fixing portions separated into both ends of the one fixing portion and the other fixing portion with reference to an axis of the folding connection conductor. And a pair of curved portions connecting the one fixed portion and the other fixed portion with curved paths, respectively, and the other bus of the pair of fixed portions The fixing portion fixed to the body formed by forming the turn-back support rod insertion hole.
[0014]
(4) A conductive coating is formed on a surface of each of the plurality of insulating bushes facing each of the load-side rods.
[0015]
(5) The plurality of insulating shields are divided into a movable electrode side and a fixed electrode side along the axial direction with respect to each of the electrodes.
[0016]
(6) The operating device, the switch, and the insulating bushing are linearly arranged along the axial direction.
[0017]
(7) The operating device is of an electromagnetic type.
[0018]
When forming a vacuum switchgear, a vacuum container to be grounded, a movable electrode held by a movable electrode rod, and a fixed electrode held by a fixed electrode rod face each other and are housed in the vacuum container. A plurality of switches, and one or two or more bus conductors connected to the movable electrode rod or fixed electrode rod of each switch, and a part thereof connected to the movable electrode rod of each switch, A plurality of operating rods connected to an operating device outside the vacuum vessel; a plurality of load-side rods connected to the fixed electrode rods of the switches and partially projecting out of the vacuum vessel; And a plurality of insulative bushings disposed around the inside and outside of the load-side rod and covering the periphery of each of the load-side rods, and the following elements can be added to this basic configuration.
[0019]
(1) The operating device, the switch, and the insulating bushing are arranged linearly along the axial direction.
[0020]
(2) A conductive coating is formed on a surface of the insulating bushing facing the load rod.
[0021]
According to the above-described means, a cylindrical electrode shield is arranged around the movable electrode and the fixed electrode, and an insulating shield is arranged around the electrode shield, so that metal vapor is generated from each electrode, Even if a part of the metal vapor is scattered from the gap between the electrode shields, the scattered metal vapor can be shielded by the insulating shield, and the metal vapor can be prevented from adhering to the vacuum vessel. It is possible to prevent the occurrence of a ground fault phenomenon with the generation of steam, thereby contributing to an improvement in reliability.
[0022]
In addition, by dividing the insulating shield into two parts, the movable electrode side and the fixed electrode side, a high voltage is applied between the movable electrode and the fixed electrode when the movable electrode and the fixed electrode are separated. In this case, the current can be prevented from flowing through the insulating shield, and the trip operation can be reliably performed.
[0023]
Furthermore, when a flexible conductor is inserted between the movable electrode rod of each switch and the bus bar conductor, when the movable electrode and the fixed electrode are in contact with each other, the movable electrode rod and the movable The current flows through the electrodes, and the current flowing through each one of the fixed portions and the current flowing through each of the other fixed portions out of the current flowing through each curved portion are in opposite directions, and the current flows through the one fixed portion and the other fixed portion. Generates electromagnetic forces in directions opposite to each other, and each electromagnetic force acts as a force in a direction to separate both ends of each curved portion from each other, so that the joining strength between the flexible conductor and the bus conductor can be increased, and the movable The contact force between the electrode and the fixed electrode can be increased.
[0024]
Further, by providing the connecting conductor for folding, the flexible conductor for folding and the supporting rod for folding, it is possible to connect adjacent switches in series via the connecting conductor for folding and the flexible conductor for folding.
[0025]
Also, by forming a conductive film on the surface of each insulating bushing facing each load side rod, the conductive film formation surface of the insulating bushing can be set to the same potential as the load side rod. The vacuum gap between the and the load side rod can be minimized. In other words, the insulating gap between the insulating bushing and the load-side rod is such that, for example, when a ceramic material is used as the insulating bushing, it is sufficient if there is a gap equal to the difference in thermal expansion between the ceramic material and the metal conductor. Become.
[0026]
Also, by arranging each actuator, each switch and each insulating bushing (cable head) linearly along the axial direction, the space between each switch can be minimized, and the switchgear Can be reduced.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a sectional front view of a main part showing an embodiment of a vacuum switchgear according to the present invention, FIG. 2 is a plan view of the vacuum switchgear shown in FIG. 1, FIG. 3 is a side view of the vacuum switchgear shown in FIG. FIG. 4 is a circuit configuration diagram of the vacuum switchgear shown in FIG. 1 to 4, the vacuum switchgear includes a vacuum vessel 10 made of stainless steel as one element of power receiving and distribution equipment in a power distribution system. The vacuum vessel 10 includes an upper plate 12, a lower plate 14, and a side plate 16, and the periphery (edge) of each plate is welded to each other, and each side portion reduces the thickness of each plate. In order to withstand vacuum pressure, it is drawn into a corrugated shape and grounded together with the equipment body. In the vacuum vessel 10, three-phase components are stored as components constituting a vacuum switchgear. In the present embodiment, only one phase is shown as a container for each phase separation.
[0028]
An exhaust pipe 18 and a vacuum measurement terminal 20 are fixed to the upper plate 12, and through holes 22, 24, 26, 28, and 30 are formed. A grounding operation rod 32 is inserted into the through hole 22 so as to reciprocate (up and down), and switch operation rods 34 and 36 are inserted into the through holes 24 and 26 so as to reciprocate (up and down). A turn-back support rod 38 is inserted into the through-hole 30 so as to reciprocate (vertically move), and a switch operating rod 40 is inserted into the through-hole 30 so as to reciprocate (vertically move). On the other hand, through holes 42, 44, and 46 are formed in the lower plate member 14, a # 1 cable head 48 is inserted into the through hole 42, and a # 2 cable head 50 is inserted into the through hole 44. The # 3 cable head 52 is inserted into the through hole 46.
[0029]
The inside of the vacuum vessel 10 is evacuated via an exhaust pipe 18. Inside the vacuum vessel 10, switches such as grounding switches 54 and 56, disconnectors 58 and 60, and circuit breakers are provided as switches. 62, copper bus conductors (ground buses) 64, 66 made of copper, and copper conducting bus conductors 68, 70, 72 made of copper. Further, support members 74, 76, 78, 80, 82, 84, 86 are accommodated in the vacuum vessel 10. One end of the support members 74, 76, 78 is fixed to the upper member 12, and the other end is fixed to the bus conductor 68 so as to support the bus conductor 68. One end of the support member 80 is fixed to the lower plate member 14, and the other end is fixed to the bus bar 66, and supports the bus bar 66. One end of each of the support members 82, 84, and 86 is fixed to the lower member 14, and the other end is fixed to the bus conductor 70, and supports the bus conductor 70.
[0030]
The grounding operation rod 32 for opening and closing the grounding switch 54 includes a columnar grounding terminal 88, a cylindrical aerial ceramic movable rod 90, a bellows 92, a substantially disk-shaped base 94, a flexible conductor 96, 98, a connecting rod 100 made of stainless steel, a connecting rod 102 made of copper, and a movable electrode 104 made of copper. A screw portion 106 is formed on the ground terminal 88, and an operating device (not shown) for grounding is fastened to the screw portion 106 so that the ground terminal 88 is grounded. Further, the bellows 92 is fixed to the upper plate 12, a movable rod 90 is connected to the open end of the bellows 92, and a base 94 is fixed to one axial end of the movable rod 90. . That is, the periphery of the ground terminal 88 is sealed by the base 94, the movable rod 90, and the bellows 92. Further, the movable rod 90 is joined to the flexible conductor 96 together with the base 94, and the base 94 is joined to the ground bus conductor 64. The flexible conductor 98 is joined to the ground bus conductor 64 and to the connecting rod 102. A connecting rod 100 is inserted into the axis of the connecting rod 102. The connecting rod 100 is slidably inserted into rod insertion holes 108a to 108d penetrating the flexible conductor 98, the busbar conductor 64, and the flexible conductor 96. The axial end is connected to the ground terminal 88. That is, when the ground terminal 88 reciprocates (moves up and down), the connecting rod 100 slides in the rod insertion openings 108 a to 108 d, and the movable electrode 104 comes into contact with the fixed electrode 110 joined to the bus conductor 66. Alternatively, the movable electrode 104 is separated from the fixed electrode 110. In this case, the flexible conductors 96 and 98 are curved in accordance with the reciprocation of the ground terminal 88. An operation rod (only part of which is shown) for operating the grounding switch 56 is substantially the same as the operation rod 32, and the movable electrode 104 is joined to the bus conductor 70. The fixed electrode 110 contacts the fixed electrode 110.
[0031]
The support members 80, 82, 84, and 86 are provided with support bases 112 and 114 made of copper and an insulating rod 116 made of a ceramic formed in a columnar shape. 114 are respectively joined. The support base 112 of the support member 80 is joined to the bus conductor 66, the support base 112 of the support members 82, 84, 86 is joined to the bus conductor 70, and the support base 114 of each of the support members 80, 82, 84, 86 Each is joined to the lower plate 14.
[0032]
A # 1 cable head 48 is joined to one end of the busbar conductor 66 via a substantially disk-shaped support base 118, and a plurality of arc-shaped grooves 118 a are provided on the cable base 48 side of the support base 118. They are formed concentrically. The # 1 cable head 48 includes a cylindrical load-side rod 120 formed in a cylindrical shape, and a ceramic insulating bushing 122 formed in a substantially cylindrical shape. A thread portion 124 is formed at an axial end of the load side rod 120. A cable constituting a power distribution system is fastened to the screw portion 124, and an insulating portion of the cable is mounted on the outer peripheral side of the insulating bushing 122. The axial ends of the load-side rod 120 and the insulating bushing 122 are respectively joined to the support base 118, and the insulating bushing 122 has a step 126 formed therein and has a smaller diameter than the step 126. 128 are formed. The joint between the load side rod 120 and the insulating bushing 122 and the support base 118 is accommodated in the vacuum vessel 10, and a part thereof is projected outside the vacuum vessel 10. A support ring 130 that contacts the step 126 and the lower plate 14 is arranged on the outer peripheral side of the step 128, and the bottom of the step 126 is supported by the support ring 130. Further, on the outer peripheral side of the support ring 130 and the step portion 126, a stainless steel shield 132 formed in a cylindrical shape is arranged.
[0033]
A connecting rod 134 made of copper and a support ring 136 are joined to the other end of the busbar conductor 66, and a connecting rod 138 is joined to the connecting rod 136. The other end of the connecting rod 138 is joined to the bus bar 68.
[0034]
The support members 74, 76, 78 joined to the busbar conductor 68 include a cylindrical support rod 140, a copper support base 142, a ceramic insulation rod 144, and a copper support base 146. Support bases 142 and 146 are respectively joined to both ends in the axial direction of the rod 144, a support rod 140 is joined to the support base 142, and an axial end of the support rod 140 is joined to the upper plate 12. The support base 146 is joined to the bus conductor 68. That is, the support members 74, 76, and 78 connect and support the bus bar conductor 68 to the upper plate 12 with the insulating rod 144 interposed therebetween.
[0035]
The operating rods 34, 36, 40 for opening and closing the disconnectors 58, 60, and the circuit breaker 62, respectively, include a cylindrical movable rod 148, a bellows 150, a support base 152, a ceramic insulating rod 154, and a copper support rod. The base 156 includes a connecting rod 158 made of stainless steel and formed in a substantially cylindrical shape. A screw 160 is formed at the axial end of the movable rod 148, and an operating device is fastened to the screw 160. A substantially disk-shaped support base 152 made of copper is joined to the other end of the movable rod 148 in the axial direction, and a bellows 150 is connected to the outer periphery of the support base 152. One end of the bellows 150 in the axial direction is fixed to the upper plate 12, and the movable rod 148 and the support base 152 are supported by the bellows 150 so as to reciprocate (vertically move). A ceramic insulating rod 154 is joined to the support base 152, and a copper support base 152 is joined to one axial end of the insulating rod 154. The connecting rod 158 is formed in the rod insertion hole 160 formed in the bus conductor 68 or the rod insertion hole 162 formed in the bus conductor 72, the disconnector 58, 60, and the rod insertion hole 166 formed in the flexible conductor 164 of the circuit breaker 62. And one end in the axial direction is connected to the fixed electrode rods 168 and 170 of the disconnectors 58 and 60 and the circuit breaker 62, respectively.
[0036]
The disconnectors 58 and 60 include a flexible conductor 164, a stainless steel arc diffusion prevention shield 172 formed in a cylindrical shape, an annular shield 174 formed in a substantially dish shape using stainless steel, a copper movable electrode rod 168, A movable electrode 176 made of copper, a fixed electrode 178 made of copper, a fixed electrode rod 180 made of copper, an electrode shield 182 made of stainless steel formed in a substantially cylindrical shape, and a ceramic formed in a cylindrical shape so as to cover the periphery of the electrode shield 182. The shields 188 of the disconnector 58 are joined to the fixed electrode rod 180 and the disc-shaped connection base 190. The shield 188 of the disconnector 60 is joined to the bus conductor 70 together with the fixed electrode rod 180.
[0037]
The shield 172 has its upper side joined to the bus conductor 68, and its bottom side fitted into the inner peripheral side of the insulating shield 184. The flexible conductor 164 has one end joined to the bus conductor 68 and the other end joined to the movable electrode rod 168. The shield 174 is disposed between the electrode shield 182 and the flexible conductor 164, and is configured to prevent scattering of metal vapor generated from the movable electrode 176 and the fixed electrode 178.
[0038]
The movable electrode 176 is held in a state of being joined to one end of the movable electrode rod 168 in the axial direction, and the fixed electrode 178 is joined and held to one end of the fixed electrode rod 180 in the axial direction. An electrode shield 182 is disposed around the movable electrode 176 and the fixed electrode 178 to prevent scattering of metal vapor generated from each electrode. A flange 192 is formed on the outer periphery of the axial center of the electrode shield 182, and an insulating shield 184 and an insulating shield 186 are vertically arranged around the electrode shield 182 with the flange 192 interposed therebetween. I have. The insulating shields 184 and 186 are divided into two on the movable electrode 176 and the fixed electrode 178 along the axial direction on the movable electrode side and the fixed electrode side. The insulating shields 184 and 186 are disposed so as to cover the outer peripheral area of each of the electrodes 176 and 178 together with the shields 172 and 188. Metal vapor is scattered from each of the electrodes 176 and 178, and a part thereof is scattered. Even when the metal vapor scatters from the gap between the electrode shields 182, the metal vapor is prevented from scattering. Further, the insulating shields 184 and 186 allow the current to flow through the insulating shields 184 and 186 even when the movable electrode 176 and the fixed electrode 178 are separated from each other when a circuit opening operation is performed and a potential difference occurs between the electrodes. Is prevented from flowing, and the opening operation is surely performed.
[0039]
On the other hand, the circuit breaker 62 includes a movable electrode 194 and a fixed electrode 196 disposed to face the movable electrode 194. The movable electrode 194 is joined to and held at one axial end of the movable electrode rod 170. The fixed electrode 196 is joined and held at one axial end of the fixed electrode rod 198. A stainless steel shield 200 is joined to the movable electrode rod 170 adjacent to the movable electrode 194, and a stainless steel shield 202 is joined to the fixed electrode rod 198 adjacent to the fixed electrode 198. Spiral grooves for confining the arc are formed on the surfaces of the movable electrode 194 and the fixed electrode 196. Other configurations of the circuit breaker 62 are the same as those of the disconnector 58. That is, the shield 172 is joined to the bus conductor 72, and the shield 188 is joined to the connection base 190 together with the fixed electrode rod 198. The # 2 cable head 50 and the # 3 cable head 52 are the same as the # 1 cable head 48.
[0040]
Further, in the circuit breaker 62, insulating shields 184 and 186 are arranged on the outer peripheral side of the electrode shield 182, and even if the movable electrode 194 and the fixed electrode 198 are separated from each other at the time of a trip, a potential difference is generated between the electrodes. Since the current can be prevented from flowing through the insulating shields 184 and 186, the trip operation can be reliably performed.
[0041]
On the other hand, the folding support rod 38 is provided for connecting the disconnector 60 and the circuit breaker 62 in series, and the support rod 38 is a movable rod 204, a bellows 206, a copper support base 208, and a ceramic support base 208. It comprises an insulating rod 210, a support base 212 made of copper, and a connecting rod 214 made of stainless steel. A support base 208 is joined to one end of the movable rod 204 in the axial direction, and a bellows 206 is connected to the outer peripheral side of the support base 208. One end of the bellows 206 in the axial direction is fixed to the upper plate 12. One end of the insulating rod 210 in the axial direction is joined to the support base 208, and the other end of the insulating rod 210 in the axial direction is joined to the support base 212. A connecting rod 214 is joined to the support base 212. The connecting rod 214 is reciprocally (up and down) freely inserted into a rod insertion hole 162 formed in the busbar conductor 72 and a rod insertion hole 166 formed in the flexible conductor 164, and the distal end thereof is made of copper. 216. One end of the connecting rod 216 in the axial direction is joined to the support base 218, and the support base 218 is joined to the bus conductor 70.
[0042]
That is, the bus conductor 70 and the bus conductor 72 are connected via the support base 218, the connecting rod 216, and the flexible conductor 164. In this case, the support base 218 and the connecting rod 216 function as a return connection conductor, the flexible conductor 164 functions as a return flexible conductor, and the support rod 38 attaches the support rod 216 and the support base 218 to the bus conductor 70 side. It will function as a turning back support rod.
[0043]
Each flexible conductor 164 (96, 98) includes a pair of fixing portions 164a, 164b and a pair of curved portions 164c, 164d, and the rod insertion hole 166 is formed as a through hole in the fixing portion 164a. Have been. The fixed part 164a is joined to the bus conductor 68 or 72, and the fixed part 164b is joined to the movable electrode rod 168 or 170. Each of the curved portions 164c and 164d is formed by laminating plate materials using different metals, for example, copper and stainless steel, and each of the curved portions 164c and 164d is based on the axis of the movable electrode rod 168 or 170. One end is joined to the fixed portion 164a, and the other end is joined to the fixed portion 164b. In this case, the current from the bus conductor 68 or 72 branches off to the curved portion 164c and the curved portion 164d via the fixed portion 164a, and the branched current flows through the movable electrode rod via the fixed portion 164b. 168 or 170. At this time, the directions of the currents at both ends of each of the curved portions 164c and 164d are opposite to each other. Therefore, the electromagnetic force generated by the current flowing through each of the curved portions 164c and 164d acts in a direction in which both ends of the curved portions 164c and 164d are separated from each other. As a result, due to this electromagnetic force, the joint between the fixed portion 164a and the bus conductor 68 or 72 is strengthened, and the joint between the fixed portion 164b and the movable electrode rod 168 or 170 is strengthened. The contact force between the fixed electrode 178 and the movable electrode 194 and the fixed electrode 196 can be increased.
[0044]
In addition, a conductive film is formed on the inner peripheral side of the insulating bushing 122 of the cable heads 48, 50, and 52 in the present embodiment, that is, on the surface facing the load side rod 120, and the inner peripheral side of the insulating bushing 122 is formed. The potential is the same as that of the load rod 120. Therefore, the insulating gap between the load side rod 120 and the insulating bushing 122 can be minimized. That is, since the inner peripheral side of the insulating bushing 122 and the load side rod 120 are maintained at the same potential, the difference in thermal expansion between the ceramic forming the insulating bushing 122 and the metal forming the load side rod 120 is specifically determined. Specifically, it is only necessary to provide a gap corresponding to the difference in thermal expansion that occurs when heating to 800 ° C. by brazing during assembly, and the space occupied by the cable heads 48, 50, and 52 is reduced. And workability can be improved.
[0045]
Furthermore, in the cable heads 48, 50, and 52 according to the present embodiment, a part of the cable heads 48, 50, and 52 is inserted into the vacuum vessel 10, and the step portion 126 is supported by the ring 130. Even if an impact force generated when the movable electrode 176 or 194 is pressed toward the fixed electrode 178 or 196 acts on each of the cable heads 48, 50 and 52, the impact force is received by the ring 130 and the lower plate member 14. Therefore, it is possible to prevent the cable heads 48, 50, and 52 from being deteriorated by the impact force.
[0046]
Also, the electromagnetic operation device (electromagnetic operation device connected to the operation rods 34 and 40), the switch (disconnector 58, circuit breaker 62), and the cable heads 50 and 52 (the load rod 120 and the insulating bushing 122) are connected. Since they are arranged linearly along the axial direction (vertical direction), the space between the switches can be minimized, and it is possible to contribute to downsizing of the switchgear.
[0047]
The vacuum switchgear having the above configuration can be used, for example, as a switch having the functions of a rated voltage of 24 kV, a rated current of 630 A / 1250 A, and a rated short-time current of 25 kA / 3 s (4 s).
[0048]
Next, a method for manufacturing a vacuum switchgear according to the present invention will be described with reference to the drawings. When manufacturing a vacuum switchgear, first, each component constituting the vacuum switchgear is divided into parts. For example, the vacuum vessel 10 is divided into an upper plate 12, a lower plate 14, and a side plate 16, and the support members 74 to 78 are divided into a support rod 140, a support base 142, an insulating rod 144, and a support base 146. For the disconnector 58, the fixed portions 164a and 164b, the curved portions 164c and 164d, the shields 172 and 174, the movable electrode rod 168, the movable electrode 176, the fixed electrode 178, the fixed electrode rod 180, the electrode shield 182, and the insulating shield 184 , 186, shield 188, and connection base 190.
[0049]
Next, each of the divided parts is divided into an upper part group arranged on the upper plate 12 side, for example, a part group constituting the support members 74 to 78, a part group constituting the operation rods 34, 36 and 40, and the like. , A lower component group arranged on the lower plate member 14 side, for example, a component group configuring the support members 80, 82, 84, 86, a component group configuring the cable heads 48, 50, 52, and the like. Further, the components are divided into components having an insulating property, for example, insulating rods 114, 116, 154, insulating shields 184, 186, an insulating bushing 122, and other components.
[0050]
Thereafter, as a brazing material, for example, a plate material of silver and copper (0.1 mm in thickness) is inserted as a brazing material between components other than the insulating components, and these component groups are placed in a vacuum atmosphere at 960 ° C. for about 10 minutes. By heating and then naturally cooling, the components are brazed to each other, the upper component group is fixed to the upper plate 12, and the lower component group is fixed to the lower plate 14.
[0051]
Next, the process shifts to a process for brazing an insulative component to the upper component group fixed to the upper plate 12 and the lower component group fixed to the lower plate 14. That is, as shown in FIGS. 5A and 5B, insulating rods 144 and 154 are fixed to the upper plate 12 as insulating parts, and the lower plate 14 is fixed to the lower plate 14 as shown in FIGS. As shown in (b), the insulating rod 116, the insulating shields 184 and 186, and the insulating bushing 122 are fixed as insulating parts. In the next step, a brazing material is inserted between the insulative component and the component to be brazed to the insulative component, for example, the flange 192 and the support base 118, and is inserted in a vacuum atmosphere. By heating at 835 ° C. for about 10 minutes, and then naturally cooling, the group of insulating parts and the group of other upper parts are fixed to the upper plate 12, and the group of parts having insulating property to the lower plate 14 and other lower parts To fix the parts group. At this time, since the copper supporting base 118 and the insulating bushing 122 have different coefficients of thermal expansion from each other, in the process of brazing the supporting base 118 and the insulating bushing 122, the supporting base 118 and the insulating bushing 122 are changed with a change in temperature. And a residual stress acts between them, and any of them is deformed as it is. However, since a plurality of arc-shaped grooves 118a are formed in the support base 118, even if residual stress acts between the support base 118 and the insulating bushing 122 due to a change in temperature, the residual stress Can be absorbed by the grooves 118a having a lower rigidity than the insulating bushing 122, and the support base 118 and the insulating bushing 122 can be securely brazed.
[0052]
Next, as shown in FIG. 7, the upper plate member 12 to which the upper part group is fixed and the lower plate member 14 to which the lower part group is fixed are arranged so as to face each other in an inert gas. A side plate member 16 is arranged adjacent to the lower plate member 14, and the periphery of the upper plate member 12, the lower plate member 14, and the side plate member 16 is fixed by TIG welding, and the vacuum vessel 10 is sealed.
[0053]
Next, as shown in FIG. 8, a vacuum pump 220 is connected to the exhaust pipe 18, and the inside of the vacuum vessel 10 is evacuated by the vacuum pump 220. In this case, the inside of the vacuum vessel 10 is heated at 430 ° C. for about 12 hours, and the inside of the vacuum vessel 10 is evacuated. After the inside of the vacuum container 10 is evacuated, a vacuum measuring device is connected to the vacuum measuring terminal 20 to measure whether or not the inside of the vacuum container 10 is maintained at a specified vacuum degree.
[0054]
In the present embodiment, the parts group fixed to the vacuum vessel 10 is divided into an upper parts group and a lower parts group, the upper parts group is fixed to the upper plate 12, and the lower parts group is fixed to the lower plate 14. Therefore, the assembling work can be easily performed.
[0055]
Also, when brazing each component group, it is performed in two steps by dividing the component into insulating components and other components, and the brazing in each process is performed at different temperatures. It is possible to reliably braze the component having the property and the other component.
[0056]
Further, in the present embodiment, when the operating rods 34, 36, 40 are operated, the flexible conductor 164 only bends with the reciprocation of the connecting rod 158, and the bus conductors 68, 72 are fixed. Therefore, even if the operation rods 34, 36, 40 are operated, the busbar conductors 68, 72 can be prevented from being deformed.
[0057]
In the present embodiment, the configuration in which the insulating shields 184 and 186 are provided as the disconnectors 58 and 60 has been described. However, the disconnectors 58 and 60 may be omitted.
[0058]
Further, in the present embodiment, the case where the bus conductors 68 and 72 are fixed has been described. However, as schematically shown in FIG. 9, a bus conductor 222 formed by stacking thin plates is used. A bending portion 224 is formed in the middle of the operation, the operation rods 34, 36, 40 are respectively connected to the bus conductor 222, and the bending portion 224 of the bus conductor 222 is bent in accordance with the operation of the operation rods 34, 36, 40. Can also be adopted.
[0059]
In the above embodiment, the three-circuit vacuum switchgear has the ground switches 54 and 56, the disconnectors 58 and 60, and the circuit breaker 62. However, depending on the circuit configuration, the ground switch may be used. The combination and number of the switches 54, 56, the disconnectors 58, 60, and the circuit breakers 62 can be arbitrarily set.
[0060]
For example, when the vacuum switchgear includes three disconnectors 58 and three grounding switches 54, a configuration as shown in FIG. 10 can be employed.
[0061]
When the vacuum switchgear is composed of two disconnectors 58 and two earthing switches 54, a configuration as shown in FIG. 11 can be adopted.
[0062]
Further, when the vacuum switchgear is composed of one circuit breaker 62 and one grounding switch 54, a configuration as shown in FIG. 12 can be adopted.
[0063]
As the circuit system, various circuit systems such as two circuits, three circuits, four circuits, five circuits or a combination of three circuits and four circuits can be adopted.
[0064]
Also, in consideration of connecting a plurality of vacuum switchgears in series, in order to apply a plurality of vacuum switchgears to the open loop system, disconnectors are arranged on both sides of a circuit breaker or a plurality of vacuum switches are arranged. In order to apply the gear to the closed loop system, all of the gears other than the grounding switch can be configured by circuit breakers.
[0065]
In the present embodiment, various switches arranged in the vacuum vessel 10 are vacuum-insulated, so that maintenance-free of the main circuit can be achieved, and by adopting an electromagnetic operation device as the operation device, Maintenance free can also be achieved. Further, by separating the inside of the vacuum vessel 10 for each phase, a short circuit accident can be prevented. Further, by constantly monitoring the degree of vacuum in the vacuum container 10, reliability can be improved.
[0066]
In the present embodiment, as a container for each phase separation, the vacuum container 10 contains only one-phase element. However, as shown in FIGS. , 60U,..., Three-phase circuit breakers 62U, 62V, 62W for the three phases (U-phase, V-phase, W-phase). In this case, on the outer peripheral surface of the vacuum vessel 10, that is, on the surface of the upper plate member 12, an electromagnetic actuator (electromagnetic operation) is associated with each of the operating rods 34 </ b> U,..., 36 </ b> U,. ), 232U, 234U, 234V, 234W, and each operating rod 34U,..., 36U,..., 40U, 40V, 40W and each electromagnetic operating unit 230U,. Are connected to each other. , 232U, 234U, 234V, 234W are configured to open and close the operation rods 34U,..., 36U,. In addition, each switch can be automatically opened and closed by a switching operation signal output from a controller (not shown).
[0067]
, 232U, 234U, 234V, 234W, switches for each phase (disconnectors 58U,..., 60U,..., Breakers 62U, 62V, 62W) and cable heads for each phase. (The load-side rods 120U, 120V, 120W, ..., and the insulating bushings covering the load-side rods) are linearly arranged along the axial direction (vertical direction), so that the space between the switches is minimized. This can contribute to miniaturization of the switchgear.
[0068]
【The invention's effect】
As described above, according to the present invention, the cylindrical electrode shield is arranged around the movable electrode and the fixed electrode, and the insulating shield is arranged around the electrode shield. Even if steam is generated and a part of the metal vapor is scattered from the gap between the electrode shields, the scattered metal vapor can be shielded by the insulating shield to prevent the metal vapor from adhering to the vacuum vessel. In addition to this, it is possible to prevent the occurrence of a ground fault phenomenon due to the generation of the metal vapor, thereby contributing to an improvement in reliability.
[Brief description of the drawings]
FIG. 1 is a sectional front view of a main part of a vacuum switchgear showing one embodiment of the present invention.
FIG. 2 is a plan view of the vacuum switchgear shown in FIG.
FIG. 3 is a side sectional view of a main part of the vacuum switchgear shown in FIG. 1;
FIG. 4 is a circuit configuration diagram of the vacuum switchgear shown in FIG. 1;
5A and 5B are diagrams for explaining a method of manufacturing a vacuum switchgear, wherein FIG. 5A is a configuration diagram of an upper plate member on which a higher-order component group is arranged, and FIG. 5B is an upper plate member on which the upper component group is fixed; 12 is a side view of FIG.
6A and 6B are views for explaining a method for manufacturing a vacuum switchgear according to the present invention, wherein FIG. 6A is a plan view of a lower plate material to which a lower component group is fixed, and FIG. It is a side view of the lower plate material performed.
FIG. 7 is a view for explaining a method for manufacturing a vacuum switchgear according to the present invention, and for explaining an operation method when welding an upper plate, a lower plate, and a side plate in an inert gas. FIG.
FIG. 8 is a sectional front view of a main part showing a state after the vacuum switchgear according to the present invention is assembled.
FIG. 9 is a schematic diagram for explaining another embodiment of the present invention.
FIG. 10 is a sectional front view of a main part when the present invention is applied to a vacuum switchgear having three disconnectors and three grounding switches.
FIG. 11 is a sectional front view of an essential part when the present invention is applied to a vacuum switchgear having two disconnectors and two grounding switches.
FIG. 12 is a sectional front view of an essential part when the present invention is applied to a vacuum switchgear having one circuit breaker and one grounding switch.
13A is a front view of a main part when a three-phase switch is housed in a vacuum switchgear, and FIG. 13B is a side view of a main part when a three-phase switch is housed in a vacuum switchgear. FIG.
[Explanation of symbols]
10 Vacuum container
12 Upper plate
14 Lower plate
16 Side plate
48, 50, 52 cable head
54, 56 Switch for grounding
58, 60 disconnector
62 circuit breaker
64, 66 Bus conductor for grounding
68, 70, 72 Bus conductor for conducting circuit
34, 36, 40 Operation rod
38 Support rod
96, 98, 164 Flexible conductor
168, 170 Movable electrode rod
176, 194 movable electrode
178, 196 Fixed electrode
180, 198 Fixed electrode rod
120 Load side rod
122 Insulating bushing
182 Electrode shield
184,186 Insulating shield

Claims (11)

A vacuum vessel to be grounded, a plurality of switches housed in the vacuum vessel with the movable electrode held by the movable electrode rod and the fixed electrode held by the fixed electrode rod facing each other, One or more bus conductors connected to a movable electrode rod or a fixed electrode rod of a switch, and a plurality of bus conductors connected to the movable electrode rods of the respective switches and a part of which is connected to an actuator outside the vacuum vessel. Operating rods, a plurality of load-side rods that are connected to the fixed electrode rods of the switches and partially protrude outside the vacuum vessel, and the load-side rods are arranged over the inside and outside of the vacuum vessel. A plurality of insulating bushings covering the periphery of the side rod, wherein each of the switches is disposed around the movable electrode and the fixed electrode to prevent scattering of metal vapor generated from the movable electrode and the fixed electrode. Cylindrical Electrode shield and vacuum switchgear comprising been configured to include a cylindrical insulating shield covering the periphery of the electrode shield. A vacuum vessel to be grounded, a plurality of switches housed in the vacuum vessel with the movable electrode held by the movable electrode rod and the fixed electrode held by the fixed electrode rod facing each other, One or more bus conductors connected to a movable electrode rod or a fixed electrode rod of a switch, and a movable electrode rod of each of the switches, a part of which is connected to each operating device outside the vacuum vessel. A plurality of operation rods, a plurality of load-side rods that are connected to the fixed electrode rods of the respective switches and partially protrude out of the vacuum vessel, and are disposed over the inside and outside of the vacuum vessel, A plurality of insulative bushings covering the periphery of the load-side rod, wherein each of the switches is disposed around the movable electrode and the fixed electrode to prevent scattering of metal vapor generated from the movable electrode and the fixed electrode. Blocking tube Electrode shield, and a cylindrical insulating shield covering the periphery of the electrode shield, the bus conductor is fixed to the vacuum vessel, the movable electrode rod of each switch through a flexible conductor A vacuum switchgear connected to the bus conductor. 3. The vacuum switch gear according to claim 2, wherein the flexible conductor includes a pair of fixed portions fixed to the one of the bus bar conductors and the one of the movable electrode rods, and a shaft of the one of the movable electrode rods. 4. A pair of curved portions that are separately disposed on both ends of the one fixed portion and the other fixed portion with respect to the center, and connect the one fixed portion and the other fixed portion with curved paths respectively. A vacuum switchgear, wherein an operating rod insertion hole is formed in a fixed part of the pair of fixed parts fixed to the bus conductor. 4. The vacuum switch gear according to claim 3, wherein the pair of curved portions of the flexible conductor are formed by alternately overlapping different metals. The vacuum switchgear according to any one of claims 1, 2, 3, and 4, wherein the connection conductor for folding connected to one of the two or more bus conductors, the connection conductor, A foldable flexible conductor connected to the other one of the two or more bus conductors, and a foldable connection conductor connected to the foldback connection conductor and fixed to the vacuum vessel, and A folding support rod urged to the side, wherein the folding flexible conductor is fixed to the other busbar conductor and the folding connection conductor, respectively, and a pair of fixing portions, and an axis of the folding connection conductor is provided. Routes that are separately disposed at both ends of the one fixed portion and the other fixed portion with reference to the one fixed portion and the other fixed portion, respectively. Connecting and a pair of curved portions, vacuum switchgear characterized by comprising formed aliasing supporting rod insertion hole in the fixing portion fixed to the other of the bus conductor of the pair of fixing portions. The vacuum switchgear according to any one of claims 1, 2, 3, 4, and 5, wherein a conductive coating is formed on a surface of each of the plurality of insulating bushes facing each of the load-side rods. A vacuum switchgear characterized by becoming. The vacuum switchgear according to any one of claims 1, 2, 3, 4, 5, and 6, wherein the plurality of insulative shields are movable electrodes along the axial direction with respect to each of the electrodes. A vacuum switchgear characterized by being divided into two sides, a fixed electrode side and a fixed electrode side. The vacuum switchgear according to any one of claims 1, 2, 3, 4, 5, 6, and 7, wherein the operation device, the switch, and the insulating bushing are linearly formed along an axial direction. A vacuum switchgear, characterized in that it is arranged in a vacuum switchgear. The vacuum switchgear according to any one of claims 1, 2, 3, 4, 5, 6, 7 and 8, wherein the operating device is of an electromagnetic type. A vacuum vessel to be grounded, a plurality of switches housed in the vacuum vessel with the movable electrode held by the movable electrode rod and the fixed electrode held by the fixed electrode rod facing each other, One or more bus conductors connected to a movable electrode rod or a fixed electrode rod of a switch, and a plurality of bus conductors connected to the movable electrode rods of the respective switches and a part of which is connected to an actuator outside the vacuum vessel. Operating rods, a plurality of load-side rods that are connected to the fixed electrode rods of the switches and partially protrude outside the vacuum vessel, and the load-side rods are arranged over the inside and outside of the vacuum vessel. A vacuum switchgear comprising: a plurality of insulating bushings covering the periphery of a side rod; wherein the operating device, the switch, and the insulating bushing are linearly arranged along an axial direction. A vacuum vessel to be grounded, a plurality of switches housed in the vacuum vessel with the movable electrode held by the movable electrode rod and the fixed electrode held by the fixed electrode rod facing each other, One or more bus conductors connected to a movable electrode rod or a fixed electrode rod of a switch, and a plurality of bus conductors connected to the movable electrode rods of the respective switches and a part of which is connected to an actuator outside the vacuum vessel. Operating rods, a plurality of load-side rods that are connected to the fixed electrode rods of the switches and partially protrude outside the vacuum vessel, and the load-side rods are arranged over the inside and outside of the vacuum vessel. A vacuum switchgear comprising: a plurality of insulating bushings covering a periphery of a side rod; and a conductive coating formed on a surface of the insulating bushing facing the load side rod.

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