JPH0688121U - Gas insulated switchgear - Google Patents

Abstract

(57) [Abstract] [Purpose] To reduce the size of the equipment by reducing the width dimension of the bus bar section unit of the gas insulated switchgear. [Composition] One section BU of busbars BUSa, BUSb in which a busbar conductor is housed in a busbar line extending in the lateral direction.
The feeder units F in which the terminal portions a1 and b1 of Sa1 and BUSb1 are adjacent to the busbar section units BS1 and BS2, respectively.
Located on the back side of 9, F1 and the other section B of the bus bar
The terminal portions a2 and b2 of USa2 and BUSb2 are arranged in the busbar section units BS1 and BS2. The terminal portions a1 and b1 of one section of the busbar are connected to the busbar dividing units BS1 and BS.
Connect to 2 from the rear side.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a gas-insulated switchgear installed in an electric station such as a substation.

[0002]

[Prior art]

 In gas-insulated switchgear installed in substations, etc., it is often the case that a large number of units including feeder units, busbar division units, transformer connection units, etc. are arranged side by side along the busbar. .

FIG. 9 shows, as an example, the NO. 3 banks and NO. A single wire connection diagram showing the structure of the four banks. In the figure, BUSa and BUSb are the busbars and otobusbars, F1 to F9, in which busbar conductors of three phases are housed in busbar conduits extending in the lateral direction. Is a feeder unit that constitutes a circuit for connecting the feeder to the upper bus BUSa and the second bus BUSb. In addition, BS1 has NO. The first section BUSa1 and NO. The first busbar division unit, BS2, which constitutes a circuit for dividing into the second section BUSa2 on the 4-bank side, has the second busbar BUSb as NO. The first section BUSb1 and NO. It is a second busbar sectioning unit that constitutes a circuit for sectioning into the second section BU Sb2 on the 3-bank side.

In this example, of the two sections of the busbar sectioned by each busbar section unit, one section connected to the feeder unit arranged immediately next to each busbar section unit is the first section, and the other section is the other section. The section is called the second section.

Further, M3 and M4 are NO. 3 banks of transformers TR3 and NO. This is a transformer connection unit that constitutes a circuit for connecting the 4-bank transformer TR4 to the O-bus BUSb, and BC is a bus-bar communication unit that constitutes a circuit for connecting between the instep A and the O-bus BUSa and BUSb. is there.

[0006] Each feeder unit is for busbar side disconnectors DSa and DSb, one end of which is connected to the upper busbars BUSa and Otsubusu BUSb, and for feeder connection, one end of which is connected to the other ends of the busbar side disconnectors DSa and DSb. It consists of a circuit breaker CBf and a cable head CHd as a feeder connecting means.

In the illustrated single-line connection diagram, a disconnector represented by a symbol having a grounded fixed contact is a three-position disconnector in which a movable contact is switched to three positions of an open position, a closed position, and a grounded position. It is a vessel. The ground circuit part of this 3-position disconnector can be replaced with an independent grounding switch.

The transformer connecting units M3 and M4 shown in the figure include a disconnector DSt having one end connected to the O-bus BUSb, a circuit breaker CBt having one end connected to the other end of the disconnector DSt, and a circuit breaker CBt. It is composed of a disconnecting switch DSp1 having one end connected to one end and an instrument transformer PT connected to the other end of the disconnecting switch DSp1 via a disconnecting switch DSp2. Each of the transformer connecting units M3 and M4 The other end of the circuit breaker CBt is connected to the voltage transformers TR3 and TR4 via a cable or the like.

The bus bar segmenting unit BS1 is connected to the NO. The first busbar section disconnector DS1 whose one end is connected to the first section BUSa1 on the bank 3 side and the NO. Of the second busbar section disconnector DS2, one end of which is connected to the second section BUSa2 on the 4-bank side, and the other end of the first busbar section disconnector DS1 and the second busbar section disconnector DS2. A busbar breaker CBs connected to the other end is provided.

In addition, the bus bar segmenting unit BS2 is connected to the O. bus bus BUSb NO. The first busbar section disconnecting switch DS1 whose one end is connected to the first section BUSb1 on the bank 4 side, and the second bus line NO. The second busbar section disconnector DS2, one end of which is connected to the second section BUSb2 on the 3rd bank side, and the other end of the first busbar section disconnector DS1 and the second busbar section disconnector DS2. And a busbar section breaker CBs connected to the other end of the busbar section.

The busbar communication unit BC includes a disconnector DSc1 having one end connected to the upper busbar BUSa, a disconnector DSc2 having one end connected to the second bus BUSb, and the other end of the disconnector DSc1 and the disconnector DSc2. It consists of a circuit breaker CBc connected between the ends.

Although not shown, NO. 1 bank and NO. The same gas insulation switchgear that constitutes two banks is provided. 1 bank and NO. The two banks of transformers are connected to the upper bus BUSa via respective transformer connection units.

The constituent equipment of each unit constituting the above gas insulated switchgear is housed in a container in which SF ₆ gas is sealed, and a vertically long rectangular parallelepiped in which an operation device, an operation panel, etc. are housed on the front side of each unit. The box of is placed. The series of units are arranged side by side so as to form a row along the busbars BUSa and BUSb, with the busbars BUSa and BUSb located on the back side.

10 and 11 show the NO. 4 bank feeder unit F1 and bus bar sorting units BS2 and BS1 and NO. This figure schematically shows the conventional structure of a part consisting of a three-bank feeder unit F9.

As shown in FIG. 11, the upper bus BUSa and the second bus BUSb are arranged vertically side by side on the rear side of the unit, and in each unit, the circuit including the disconnector on the bus side is arranged from the bus to the front side ( It is pulled out (in the direction orthogonal to the busbar) and connected to a circuit breaker.

That is, in the feeder units F1 and F9, the circuits including the disconnectors DSa and DSb are drawn out from the upper bus BUSa and the second bus BUSb in the direction directly crossing the respective busbars and connected to one end of the circuit breaker CBf. Has been done.

In the busbar section unit BS1, a circuit including the disconnector DS1 is drawn out from the terminal portion a1 of the first section BUSa1 of the busbar BUSa in a direction orthogonal to the busbar and connected to the upper end of the connecting conductor L1 ′, The lower end of the connecting conductor L1 'is connected to one end of the circuit breaker CBs. A circuit including the disconnector DS2 is drawn out from the terminal portion a 2 of the second section BUSa2 of the busbar BUSa in a direction orthogonal to the busbar and is connected to the other end of the circuit breaker C Bs.

In the busbar segmenting unit BS2, a circuit including the disconnector DS1 is drawn out from the terminal portion b1 of the first section BUSb1 of the busbar BUSb in the direction orthogonal to the busbar and is connected to one end of the circuit breaker CBs to cut off the circuit. The other end of the container CBs is connected to the lower end of the connecting conductor L2 '. A circuit including the disconnector DS2 is drawn out from the terminal portion b2 of the second section BUSb2 of the busbar BUSb in the direction orthogonal to the busbar and is connected to the upper end of the connecting conductor L2 '.

[0019]

[Problems to be solved by the device]

 10 and 11, in the feeder units F1 and F9, one end of each circuit breaker is located at the same position in the lateral direction (longitudinal direction of the bus bar) at the same position as the bus bar BUSa via the disconnectors D Sa and DSb. And BUSb, all components can be accommodated in a space with a relatively narrow width. The width dimension a of this feeder unit is the standard width dimension of the unit.

On the other hand, since it is necessary to introduce the terminals of the two sections of the respective busbars into the busbar segmenting units BS1 and BS2, all the devices within the space having the width dimension of the standard dimension a above. Cannot be accommodated, and a space with a width dimension 2a that is twice the standard width dimension of the unit is required for each busbar section unit.

As described above, in the conventional gas-insulated switchgear, a space having a width dimension twice that of the other units is required to arrange the busbar section unit, so that the entire gas-insulated switchgear is large. There was a problem that it became a shape and required a large installation space.

An object of the present invention is to provide a gas-insulated switchgear in which the components of the bus bar segmenting unit can be accommodated in the space for one unit and the size of which is reduced.

[0023]

[Means for Solving the Problems]

 The present invention comprises a bus bar in which a bus conductor is housed in a laterally extending bus line conduit, and a large number of units including a bus bar dividing unit which constitutes a circuit for dividing the bus bar into two sections. Thus, the present invention relates to a gas-insulated switchgear in which a large number of these units are arranged side by side along the busbar with the busbar located on the back side.

In the present invention, the terminals of one section of the busbar are arranged in another unit adjacent to the busbar section unit, and the terminals of each section of the busbar are connected to the busbar section unit from the rear side. I chose

The other unit adjacent to the bus bar sorting unit is a feeder unit that constitutes a circuit for connecting the feeder to the normal bus bar. Generally, a feeder unit includes a busbar-side disconnector whose one end is connected to the busbar, and a line-breaking circuit breaker whose one end is connected to the other end of the busbar-side disconnector and whose other end is connected to the feeder connecting means. There is. The busbar section unit includes a first busbar disconnecting switch having one end connected to one section of the busbar, a second busbar disconnecting switch having one end connected to the other section of the busbar, and a first busbar disconnecting switch. And a busbar section breaker connected between the other end of the busbar section disconnector and the other end of the second busbar section disconnector.

In this case, the terminal portion of one section of the busbar is arranged in the feeder unit adjacent to the busbar section unit, and one end of the busbar section unit connecting conductor provided on the rear side of the feeder unit is connected to the feeder unit. Connect to the terminal of one section. The first busbar section disconnector of the busbar section unit is arranged below the busbar section breaker and is connected to the other end of the busbar section unit connecting conductor on the back side. The second disconnecting switch for busbar section is arranged above the breaker for busbar section and is connected to the end of the other section of the busbar on the rear side.

In the present invention, the “bus” is a conductor that connects a number of units of a gas insulated switchgear and is arranged in a bus line that extends in the direction in which the units are arranged (horizontally). The conductor portion arranged in the vertically extending conduit is not called a busbar.

[0028]

[Action]

 In the conventional gas-insulated switchgear, the two section terminals of the busbar are introduced into the busbar section unit, and the terminals of both sections are connected via a disconnector and a circuit breaker. Therefore, a space having a width dimension twice that of the other units is required to accommodate the components of the bus bar section unit.

On the other hand, in the present invention, the terminals of one section of the busbar are arranged in another adjacent unit, and the terminals of each section of the busbar are connected to the busbar section unit on the rear side. As a result, the components of the bus bar section unit can be arranged in a space having the same width dimension as other units, and the installation space for the gas insulated switchgear can be reduced.

[0030]

【Example】

 The schematic construction of the essential part of the embodiment of the present invention is shown in FIGS. 1 and 2 show an embodiment in which the present invention is applied to the gas insulated switchgear shown in FIG. 9. FIG. 4 bank feeder unit F1 and bus bar sorting units BS2 and BS1 and NO. FIG. 2 is a single-line connection diagram that schematically shows the configuration of the portion including the three-bank feeder unit F9, and FIG. 2 is an explanatory diagram that shows the three-dimensional arrangement of the devices of the same portion.

In this embodiment, the NO. The terminal section a1 of the first section (one section) BUSa1 on the side of the three banks is arranged in the feeder unit F9 adjacent to the bus bar sorting unit BS1 and is connected to the bus bar side disconnector DSa of the feeder unit F9. ing. On the rear side of the feeder unit F9, a busbar section unit connecting conductor L1 is arranged, and the upper end of the conductor L1 is located at the terminal end a1 of the first section BUSa1 of the upper busbar BUSa from the rear side of the unit F9. It is connected. The first busbar section disconnector DS1 of the busbar section unit BS1 is arranged below the busbar section breaker CBs and is connected to the lower end of the busbar section unit connecting conductor L1. The terminal section a2 of the second section (other section) BU Sa2 of the upper bus BUSa is arranged in the bus section unit BS1, and the terminal section a2 is the second bus line disconnecting switch DS2 of the bus section unit BS1. Is connected from the rear side of the unit. The current transformer CTs is attached to the conductor connecting between the circuit breaker CBs and the disconnector DS1 in the unit BS1.

In addition, the O. bus BUSb NO. The terminal section b1 of the first section (one section) BUSb1 on the four bank side is arranged in the feeder unit F1 and connected to the busbar side disconnector DSb of the feeder unit F1. The feeder unit F1 is provided with a busbar section unit connecting conductor L2 on the back surface side, and the upper end of the busbar section unit connecting conductor L2 is connected to the busbar side disconnector DSb of the feeder unit F1 from the rear side of the unit. ing. The first busbar section disconnector DS1 of the busbar section unit BS2 is arranged below the busbar section breaker CBs and is connected to the lower end of the busbar section unit connecting conductor L2. The terminal part b2 of the second (other section) BUSb2 of the Otobus BUSb is arranged in the busbar section unit BS2, and the terminal end b2 is connected to the second busbar disconnecting switch DS2 of the busbar section unit BS2. It is connected from the back side of the unit. In the unit BS2, the current transformer CTs is attached to the conductor connecting the circuit breaker CBs and the disconnector D S1. The other configuration is the same as the conventional one.

In this embodiment, the terminal portion a1 of the first section BUSa1 of the upper busbar BUSa is arranged in the feeder unit F9 adjacent to the busbar sorting unit BS1, and the terminal portion a1 is located on the rear side of the unit. Since it is connected to the unit BS1, it is possible to arrange all the components of the bus bar segmenting unit BS1 in the space of the standard width dimension a for one unit. Similarly, all the constituent devices of the bus bar segmenting unit BS2 can be arranged in the space of the standard width dimension a for one unit.

Specific configuration examples of the units shown in FIGS. 1 and 2 are shown in FIGS. 3 to 8. FIG. 3 shows the structure of the bus bar sorting unit BS1. In this example, the cylindrical main container 3 is supported on the installation base 1 via the pedestal 2, and is installed on the upper part of the rear surface of the main container 3. A cross-shaped busbar container 5 is connected to the branched pipe portion 3a via an insulating spacer 4. One end of a tubular container 7 is connected to the branch pipe portion 3c provided at the lower part of the back surface of the main container 3 via an insulating spacer 6, and the other end of the container 7 is connected to the branch pipe portion 3c via an insulating spacer 8 to form a cross tubular shape. A container 9 is connected. The container 9 is supported by the mount 10 with respect to the installation base 1. Reference numeral 11 ′ is a tubular busbar container arranged below the busbar container 5. On the front side of the main container 3, a vertically elongated rectangular parallelepiped operation box 12 is arranged.

In the main container 3, there are accommodated busbar section breakers CBs for three phases. Each circuit breaker C Bs is supported by a support plate 13 mounted so as to close a nozzle base portion 3d provided on the front side of the middle portion of the main container. The busbar container 5 accommodates the conductor 14 constituting the terminal portion a2 of the second section BUSa2 of the upper busbar and the second disconnecting switch DS2 for separating the busbar, and the second section of the upper busbar. The terminal portion a2 of BUSa2 is connected to one end of the circuit breaker CBs via the disconnector DS2, the penetrating conductor of the insulating spacer 4 and the connecting conductor 15 arranged in the main container.

A three-phase conductor 16 is housed in the tubular container 7, and one end of this conductor is connected to the other end of the circuit breaker CBs via a through conductor of the insulating spacer 6 and a connecting conductor 17. The conductor 18 and the first busbar section disconnecting switch DS1 for three phases are accommodated in the container 9, and one end of the conductor 18 is connected to the other end of the conductor 16 through the disconnecting switch DS1 and the through conductor of the insulating spacer 8. Has been done. The conductor 16 is equipped with current transformers CTs. In addition, a conductor 19 forming the second section BUSb2 of the Otobus is stored in the container 11 '. An operation device of the circuit breaker CBs, an operation panel, etc. are housed in the operation device box 12, and a door 12a is attached to the front side of the operation device box 12.

FIG. 4 shows a feeder unit F9 arranged adjacent to the bus bar segmenting unit BS1, which is arranged adjacent to the bus bar segmenting unit BS1 as shown in FIG. . In FIG. 4, reference numeral 3 denotes a main container similar to that provided in the busbar segmenting unit BS1, which is a cross-shaped busbar container via an insulating spacer in a branch pipe portion 3b provided at an intermediate portion on the back side of the main container 3. 11 is connected. In addition, a branch pipe portion 22a provided on the side surface of the tubular container 22 is connected to the rear end of the busbar container 15 via an insulating spacer 21, and the lower end of the container 22 is connected to the tubular container via an insulating spacer 23. The upper ends of 24 are connected. An upper end of a cross-shaped container 26 is connected to a lower end of the container 24 via an insulating spacer 25, and a lateral pipe line 26a of the container 26 is provided with an insulating spacer on a lateral pipe line 9a of the container 9 of the busbar section unit BS1. Connected through. Further, the container 11 'of FIG. 3 is connected to the lateral pipe line 11a of the bus bar container 11 via an insulating spacer. The lower part of the container 26 is supported by the installation base 1 via the pedestal 27, and the lateral pipe line 26a of the container 26 is connected to the insulating pipe 32 (see FIG. 5) in the lateral pipe line 9a of the container 9 of the bus bar section unit BS 1. Connected).

In this feeder unit F9, a feeder connecting circuit breaker C Bf is housed in the main container 3, and a conductor 28 constituting the terminal portion a1 of the first section BUSa1 of the upper busbar is housed in the busbar container 5. The disconnector DSa and the connecting conductor 29 are accommodated, and the conductor 28 is connected to one end of the circuit breaker CBf via the disconnector DSa. A conductor 30 is arranged in the container 22, and one end of the conductor 30 is connected to the terminal portion a1 of the first section BUSa1 of the upper bus through the through conductor of the insulating spacer 21 and the connecting conductor 29. Further, a conductor 31 extending in the vertical direction is housed in the container 24, and the upper end and the lower end of the conductor 31 are connected to the through conductor of the insulating spacer 23 and the through conductor of the insulating spacer 25, respectively. An L-shaped conductor 33 (see FIG. 5) is housed in the container 26, and one end of the conductor 33 is connected to the penetrating conductor of the insulating spacer 25. The other end of the conductor 33 is connected to the conductor 18 in the container 9 via the through conductor of the insulating spacer 32. In this example, the conductors 30, 31, 33 and 18 connect the terminal portion a1 of the first section of the upper busbar to the first busbar disconnecting disconnector D S1 of the busbar sorting unit BS1. L1 is constructed.

In the busbar container 11, a conductor forming the second section BUSb2 of the Otobus and a disconnector DSb are housed, and the conductor forming the section BUSb2 is connected via the disconnector DSb and a predetermined conductor. Is connected to one end of the circuit breaker CBf.

A cable head CHd for connecting a terminal portion of a cable forming a feeder is arranged in the lower part of the main container 3, and the cable head is connected to the other end of the circuit breaker C Bf via a predetermined conductor. ing.

FIG. 6 shows a busbar dividing unit BS2 for dividing the Otsubusu BUSb. In this example, a main container 3 ′ which is shorter than the main container 3 is used, and the main container 3 ′ is provided in the main container 3 ′. The circuit breaker CBs is stored. The busbar container 11 is connected to the branch pipe portion provided on the upper part on the back side of the main container 3'through an insulating spacer, and the terminal portion b2 of the second section BUSb2 of the Otsu busbar is connected to the busbar container 11. The constituent conductors and the second busbar disconnecting switch DS2 are housed. The disconnector DS2 is connected to one end of the circuit breaker CBs via a through conductor of an insulating spacer that divides the containers 11 and 3'and a connecting conductor 15 '.

Similar to the busbar section unit B S1, one end of the container 7 is connected to the branch pipe portion provided on the lower portion of the back surface of the main container 3 ′ through the insulating spacer 6, and the other end of the container 7 is connected. A container 9 is connected to the end via an insulating spacer 8. A conductor 16 and a current transformer CTs are stored in the container 7, and a conductor 18 and a disconnector DS1 are stored in the container 9.

A busbar container 5 ′ is arranged above the container 11, and a conductor forming the first section BUSa 1 of the instep busbar is housed in the busbar container.

FIG. 7 shows a feeder unit F1. This feeder unit F1 is arranged adjacent to the bus bar sorting unit BS2 as shown in FIG. The main part of the feeder unit F1 is constructed in the same manner as the main part of the feeder unit F9, and the conductor forming the terminal part b1 of the first section BUSb1 of the Otsu bus is accommodated in the bus container 11 together with the disconnector DSb. ing. In this feeder unit F1, a branch pipe portion provided on the side surface of the container 22 is connected to the back side of the busbar container 11 via an insulating spacer 21, and the lower end of the container 22 is connected via an insulating spacer 25. The upper end of the container 26 is connected. The containers 22 and 26 are the same as the containers 22 and 26 used in the feeder unit F9 shown in FIG. 4, respectively, and the conductors 30 and 33 are housed in the containers 22 and 26, respectively. And 18 form a connecting conductor L2.

SF ₆ gas is sealed at a predetermined pressure in each container of each unit shown in FIGS. 3 to 8.

In the above embodiment, the gas insulated switchgear having the double busbar configuration is taken as an example. However, even when the busbar section unit is provided in the gas insulated switchgear having the single busbar configuration, the first section of the busbar is provided. The present invention can be applied in the same manner as in the above-mentioned embodiment by arranging the terminal section of the second section in the adjacent feeder unit and the terminal section of the second section in the busbar section unit. Further, in this case, the terminal section of the first section and the terminal section of the second section of the busbar are respectively arranged in the feeder units on both sides of the busbar section unit, and the terminal sections of both sections are routed through a predetermined pipeline. It is also possible to adopt a structure in which the busbar section unit is connected from the rear side.

Although the grounding switch is not shown in the above embodiment, it is needless to say that the grounding switch is provided at a necessary position.

[0048]

[Effect of device]

 As described above, according to the present invention, the terminals of one section of the busbar are arranged in the other adjacent units, and the terminals of each section of the busbar are connected to the busbar section unit on the rear side. Therefore, the components of the bus bar section unit can be arranged in a space having the same width dimension as other units, and there is an advantage that the installation space of the gas insulated switchgear can be reduced.

[Brief description of drawings]

FIG. 1 is a single wire connection diagram showing a configuration of a main part of an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a three-dimensional arrangement of devices of the embodiment of FIG.

FIG. 3 is a side cross-sectional view showing a configuration example of a busbar segmenting unit for an instep busbar used in an embodiment of the present invention.

FIG. 4 is a side sectional view of a feeder unit arranged adjacent to the bus bar segmenting unit of FIG. 3 in an embodiment of the present invention.

5 is a rear view showing a state in which the unit of FIG. 3 and the unit of FIG. 4 are arranged side by side.

FIG. 6 is a side cross-sectional view showing a configuration example of a busbar dividing unit for an Otsu bus used in an embodiment of the present invention.

FIG. 7 is a side sectional view of a feeder unit arranged adjacent to the bus bar segmenting unit of FIG. 6 in an embodiment of the present invention.

8 is a rear view showing a state in which the unit of FIG. 6 and the unit of FIG. 7 are arranged in parallel.

FIG. 9 is a single wire connection diagram showing a partial configuration example of a gas insulated switchgear having a double busbar configuration.

FIG. 10 is a single wire connection diagram showing a configuration of a main part of a conventional gas-insulated switchgear.

11 is an explanatory diagram showing a three-dimensional arrangement of devices of the gas insulated switchgear of FIG.

[Explanation of symbols]

 BUSa Kobus BUSa1 1st section of Kobus a1 Terminal of 1st section of Kobus BUSa2 2nd section of Kobus a2 Terminal of 2nd section of Kobus BUSb Otobus BUSb1 1st of Obus Section b1 Terminal section of the first section of the Otobus line BUSb2 Second section of the Otobus line b2 Terminal section of the second section of the Otobus line BS1 Busbar section unit for the Kobusen line BS2 Busbar section unit for the Otobus line F1 ~ F9 Feeder unit CBf Feeder connection breaker CBs Busbar section breaker DSa 1st busbar disconnector DSb 2nd busbar disconnector DS1 1st busbar disconnector DS2 2nd busbar disconnector L1 Connection conductor L2 Connection conductor

Claims (2)

[Scope of utility model registration request] 1. A bus bar which houses a bus bar conductor in a bus line duct extending in a lateral direction, and a large number of units including a bus bar dividing unit which constitutes a circuit for dividing the bus bar into two sections. A gas-insulated switchgear in which the plurality of units are juxtaposed along the busbar with the busbars located on the rear side, wherein the end of one section of the busbar is adjacent to the busbar segmenting unit Is disposed on the back side of the unit, the terminal section of the other section of the bus bar is disposed in the bus bar section unit, and the terminal section of one section of the bus bar is connected to the bus bar section unit from the back side. Characteristic gas-insulated switchgear. 2. A busbar which houses a busbar conductor in a laterally extending busbar line, a busbar sectioning unit which constitutes a circuit for partitioning the busbar into two sections, and a feeder which is connected to the busbar. A plurality of units including a feeder unit that constitutes a circuit for, the plurality of units in a state in which the bus bar is located on the back side, and in a state in which the feeder unit is adjacent to the bus bar section unit. The feeder unit is arranged in parallel along the bus bar, and the feeder unit has a bus bar side disconnector whose one end is connected to the bus bar, and a line in which one end is connected to the other end of the bus bar side disconnector and the other end is connected to feeder connecting means. A busbar disconnecting unit, wherein the busbar segmenting unit includes a first busbar segmenting disconnector, one end of which is connected to one section of the busbar, and a busbar segmenting unit, which is connected to the other section of the busbar. A second busbar disconnecting disconnector having ends connected thereto, and a busbar disconnecting disconnector connected between the other end of the first busbar disconnecting disconnector and the other end of the second busbar disconnecting disconnector. In a gas-insulated switchgear including a switch, a terminal section of one section of the busbar is arranged in a feeder unit adjacent to the busbar section unit, and a terminal section of the other section of the busbar is the busbar section unit. A busbar segmenting unit connecting conductor is provided on the back side of the feeder unit, and one end of the conductor is connected to a terminal portion of one section of the busbar, and a first busbar of the busbar segmenting unit. The disconnecting switch for sectioning is arranged below the busbar-dividing circuit breaker and is connected to the other end of the busbar-segmenting unit connecting conductor on the rear side, and the second busbar-segmenting disconnector is the busbar-segmenting disconnector. A gas-insulated switchgear arranged above the container and connected to a terminal portion of the other section of the bus bar on the back side.