JP7228538B2 - gas insulated switchgear - Google Patents

Description

An embodiment of the present invention relates to a gas-insulated switchgear.

Gas-Insulated Switchgear (GIS) is widely used for system switching of high-voltage power transmission systems. A gas-insulated switchgear has a tank, a conductor, and a spacer. An insulating gas is sealed inside the tank. A conductor is located inside the tank and extends in the axial direction of the tank. The spacer axially partitions the interior of the tank and supports the conductor.

When a ground fault between a conductor and a tank or a short circuit between three-phase conductors occurs, an arc discharge occurs inside the gas insulated switchgear. Gas-insulated switchgear is required to have high reliability against arc discharge.

JP-A-10-32915

CIGRE Session 1998 - WG 21/23/33-03, ASSESSMENT OF THE BEHAVIOUR OF GAS-INSULATED ELECTRICAL COMPONENTS IN THE PRESENCE OF AN INTERNAL ARC, by G. BABUSCI. E. COLOMBO. R. SPEZIALI. BERGMANN. M. LISSANDRIN. G. CORDIOLI. C. PIAZZA.

The problem to be solved by the present invention is to provide a gas-insulated switchgear having high reliability against arc discharge.

A gas-insulated switchgear according to an embodiment has a tank, a conductor, and a partition member. The tank is formed in a cylindrical shape and filled with insulating gas. A conductor is located inside the tank and extends in the axial direction of the tank. The partition member axially partitions the inside of the tank and supports the conductor. The lower area of the tank is the area of the conductor projected onto the tank below the conductor in the first axial range adjacent to the partition member in the axial direction. The top area of the tank is the area where the conductor is projected onto the tank above the conductor in the first axial extent. The thickness of the tank in the lower region is thicker than the thickness of the tank in the upper region. The tank has a tank support member formed in the lower region.

The side view of a gas insulated switchgear. BRIEF DESCRIPTION OF THE DRAWINGS Side sectional drawing of the gas insulated switchgear of 1st Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS Front sectional drawing of the gas insulated switchgear of 1st Embodiment. 1 is a cross-sectional front view of a three-phase gas-insulated switchgear; FIG. FIG. 2 is a side cross-sectional view of a gas-insulated switchgear of a first modification of the first embodiment; Front sectional drawing of the gas insulated switchgear of the 1st modification of 1st Embodiment. FIG. 4 is a side cross-sectional view of a gas-insulated switchgear of a second modification of the first embodiment; Front sectional drawing of the gas insulated switchgear of the 2nd modification of 1st Embodiment. FIG. 11 is a side cross-sectional view of a gas-insulated switchgear according to a third modification of the first embodiment; The front sectional view of the gas insulated switchgear of the 3rd modification of 1st Embodiment. FIG. 11 is a side cross-sectional view of a gas-insulated switchgear according to a fourth modification of the first embodiment; The front sectional view of the gas insulated switchgear of the 4th modification of 1st Embodiment. FIG. 11 is a side cross-sectional view of a gas-insulated switchgear of a fifth modification of the first embodiment; The front sectional view of the gas insulated switchgear of the 5th modification of 1st Embodiment. Side sectional drawing of the gas insulated switchgear of 2nd Embodiment. Front sectional drawing of the gas insulated switchgear of 2nd Embodiment. FIG. 2 is a side cross-sectional view of a gas-insulated switchgear of a reference embodiment;

Gas-insulated switchgear according to embodiments will be described below with reference to the drawings.
In this application, the Z direction, X direction and Y direction of the orthogonal coordinate system are defined as follows. The Z direction is the vertical direction and the +Z direction is the upward direction. The X and Y directions are horizontal. The Y direction is the axial direction of the main busbar 10, and the X direction is the axial direction of the line-side busbar 6. As shown in FIG.

FIG. 1 is an example of a side view of a gas-insulated switchgear. The gas-insulated switchgear 1 mainly includes a main busbar 10 (10a, 10b), a circuit breaker 4, a track-side busbar 6, and a bushing 7. The main busbar 10 extends in the Y direction, and the line-side busbar 6 extends in the X direction. The line-side busbar 6 is connected to the transmission line through a bushing 7 . The circuit breaker 4 and the line-side busbar 6 are connected in series. A plurality of circuit breakers 4 and line-side busbars 6 are connected in parallel to a main busbar 10 . The circuit breaker 4 opens and closes between the main busbar 10 and the trackside busbar 6 .

The conductors of the gas-insulated switchgear 1 are arranged inside a tank filled with insulating gas. In each figure below, the basic internal structure of the gas-insulated switchgear 1 is described as an example. Although the internal structure of the gas-insulated switchgear 1 is described as an example in each of the following figures, the other components of the gas-insulated switchgear are similarly formed.

(First embodiment)
2 and 3 are cross-sectional views of the gas-insulated switchgear according to the first embodiment. 2 is a side cross-sectional view taken along line BB of FIG. 3. FIG. 3 is a front cross-sectional view taken along line AA of FIG. 2. FIG. The gas-insulated switchgear 1 has a tank 12 , a conductor 15 , an insulating gas 19 , and a spacer (partition member) 17 .

The tank 12 is made of a metal material such as aluminum. The tank 12 is formed by processing and welding a metal pipe or metal plate. Tank 12 may be a casting tank that is cast. An insulating gas 19 is sealed inside the tank 12 . The tank 12 has a tubular portion 12 p and a flange 13 . The tubular portion 12p is formed in a substantially cylindrical shape. In the present application, the axial direction of the tank 12 may be simply referred to as the axial direction, and the radial direction of the tank 12 may be simply referred to as the radial direction. The flanges 13 are formed at both ends in the axial direction of the cylindrical portion 12p. The flange 13 widens radially outward of the tank 12 . Tank 12 is grounded.

The conductor 15 is made of a metal material such as aluminum and shaped like a round bar. Conductor 15 extends in the axial direction of tank 12 . In the case of a single-phase gas-insulated switchgear, one conductor 15 is arranged along the central axis of the tank 12 . FIG. 4 is a front sectional view of a three-phase gas-insulated switchgear. In the case of a three-phase gas-insulated switchgear, three conductors 15a, 15b, 15c are arranged around the central axis of the tank 12. FIG.

The insulating gas 19 is, for example, sulfur hexafluoride (SF ₆ ) gas. An insulating gas 19 is enclosed inside the tank 12 . Insulating gas 19 improves the insulation between conductor 15 and tank 12 . The insulating gas 19 improves the insulation between three-phase conductors.

The spacer 17 is made of an insulating material such as epoxy resin. The spacer 17 is formed in the shape of a cone or disk. A peripheral portion of the spacer 17 is sandwiched between the flanges 13 of the adjacent tanks 12 and fixed to the flanges 13 . The spacer 17 partitions the interior of the tank 12 in the axial direction. Spacer 17 seals insulating gas 19 inside tank 12 . Since the tank 12 is divided into a plurality of units in the axial direction by the spacer 17, maintenance of the tank 12 can be performed on a unit-by-unit basis. At the center of spacer 17 is a metallic electrode 18 which is electrically and mechanically connected to conductor 15 by various contact structures.

Arc discharge in the gas-insulated switchgear 1 will be described. First, the pressure rise of the insulating gas 19 due to arc discharge will be described.
When a ground fault between the conductor 15 and the tank 12 or a short circuit between three-phase conductors occurs, arc discharge occurs inside the gas insulated switchgear 1 . The arc discharge causes the conductor 15 and the tank 12 to react with the insulating gas 19, generating heat of reaction. The temperature and pressure of the insulating gas 19 rise due to heat of reaction due to the arc discharge and heat of the arc discharge itself. The gas-insulated switchgear 1 is required to have strength against pressure rise of the insulating gas 19 due to arc discharge.

The Institute of Electrical Engineers of Japan, Electrical Standards Committee Standard, Gas Insulated Switchgear, JEC-2350: 2016, 5.14.1 The following contents are described in the commentary on container strength. Resistant to pressure rise due to internal failures such as arc discharge means that the final pressure value obtained by adding the gas pressure rise value due to internal failures up to the main protection failure clearing time to the maximum working pressure is within the strength of the container. . It should be noted that there are cases where users are required to endure the pressure rise until the backup protection failure clearing time. The following formula 1 is generally used as a calculation formula for gas pressure rise due to internal failure.

ΔP is the gas pressure rise (MPa), C is the coefficient (single-phase 0.3, three-phase 0.2 × √3), I is the fault current (rated short-time withstand current) (kA), t is the fault clearing time ( ms), V is the volume of the container in liters.
The following formula 2 is generally used as a formula for calculating the strength of a container against internal pressure.

P is the strength of the container (MPa), t is the thickness of the main shell (mm), σ is the specified minimum tensile strength of the material (N/mm ² ), η is the welding efficiency, and D is the inner diameter of the container (mm). .
In order to ensure the strength of the gas-insulated switchgear 1 against the pressure rise of the insulating gas 19, the minimum plate thickness t of the tank 12, which is a container, is determined so as to satisfy Equation (2).

Secondly, the burn-through phenomenon caused by arc discharge will be explained.
At the arc leg where the arc and tank 12 contact, the heat of the arc melts the metallic material of tank 12 . A burn-through phenomenon, in which a hole is formed in the tank 12, occurs depending on the magnitude of the arc current and the duration of the energization. Various empirical formulas have been reported to calculate the minimum plate thickness of the tank 12 necessary to prevent the burn-through phenomenon.

_tb is the burn through time, h is the container thickness, and _Is is the short circuit current. The parameter k is 173 (ms kA/mm ² ) when the container material is aluminum and 750 (ms kA/mm ² ) when the container material is iron.
In order to prevent burn-through, the minimum plate thickness h of the tank 12, which is a container, is determined so as to satisfy Equation 3. Of the minimum plate thickness t of the tank 12 obtained from Equation 2 and the minimum plate thickness h of the tank 12 obtained from Equation 3, the larger one is set as the minimum plate thickness of the tank 12 .

Even if the plate thickness of the tank 12 is equal to or greater than the minimum plate thickness obtained from Equations 2 and 3, the tank 12 may be perforated.
The arc generated inside the tank 12 moves axially due to the electromagnetic force and stays near the spacer 17 . The arc is in contact with the conductor 15 mainly near the spacer 17 for a long time. At the portion where the arc contacts the conductor 15, the metal material of the conductor 15 is melted by the heat of the arc. The molten metal material falls to the bottom of tank 12 . If the short circuit current is large or if the fault current lasts for a long time, the amount of falling molten metal increases. The metal material of the tank 12 is melted by the molten metal staying at the bottom of the tank 12 . It is believed that this causes the tank 12 to be perforated. While the metal material throughout the thickness of the tank 12 is being melted, the thickness of the unmelted portion may become unable to withstand the pressure of the insulating gas 19 and a hole may be formed. We will refer to these phenomena as secondary burnthrough.
The secondary burn-through is suppressed by the gas-insulated switchgear 1 of the embodiment.

As shown in FIG. 2, a first range 20y is defined adjacent to the spacer 17 in the axial direction (Y direction). The first range 20y in the axial direction is the length of the inner diameter 12d of the tank 12 from the contact position between the spacer 17 and the tank 12 to the inside of the tank 12 . In other words, the first axial extent 20y is the extent of the length of the inner diameter 12d of the tank 12 at the axial ends of the tank 12 . A region where the conductor 15 is projected onto the tank 12 below the conductor 15 in the first range 20 y in the axial direction is defined as a lower region 20 of the tank 12 . An upper region 21 of the tank 12 is defined as a region where the conductor 15 is projected onto the tank 12 above the conductor 15 in the first range 20 y in the axial direction. The axial length of the lower region 20 and the upper region 21 is the axial length of the first area 20y, which is equal to the length of the inner diameter 12d of the tank 12. As shown in FIG. As shown in FIG. 3, the X-direction lengths of lower region 20 and upper region 21 are equal to the length of outer diameter 15 d of conductor 15 .

As shown in FIG. 2, the thickness 20t of tank 12 in lower region 20 is thicker than the thickness 21t of tank 12 in upper region 21 . In the present application, the “thickness of the tank” refers to the radial thickness of the portion of the tank 12 excluding the flange 13 . The thickness of the tank 12 in the regions other than the lower region 20 (including the upper region 21) is equivalent to the minimum plate thickness obtained from Equations 2 and 3. The thickness of the tank 12 in the lower region 20 is thicker than the minimum plate thickness obtained from Equations 2 and 3. A thick portion is formed in the lower region 20 so that the tank 12 is thicker than the upper region 21 . The thick portion may be formed at least in the lower region 20 and may be formed in a region wider than the lower region 20 . In the example of FIG. 3, the thick portion is formed in a region wider than the lower region 20 in the X direction. A tank 12 having a thick portion is integrally formed by casting.

In the case of the three-phase gas-insulated switchgear shown in FIG. 4, below the three-phase conductors 15a, 15b, 15c are the lower regions 20a, 20b, 20c, respectively. Above the three-phase conductors 15a, 15b, 15c are upper regions 21a, 21b, 21c. The thickness 20t of the tank 12 in the lower regions 20a, 20b, 20c is thicker than the thickness 21t of the tank 12 in the upper regions 21a, 21b, 21c. In the example of FIG. 4, the thick portion is formed entirely between the ends in the X direction of the three-phase conductors 15a, 15b, and 15c.

Thus, in the gas-insulated switchgear 1 of the first embodiment, the thickness 20t of the tank 12 in the lower region 20 is thicker than the thickness 21t of the tank 12 in the upper region 21 .
As described above, the heat of the arc melts the metallic material of conductor 15 in the vicinity of spacer 17 . Molten metal falls into a lower region 20 of tank 12 . In the gas-insulated switchgear 1 of the first embodiment, the thickness of the tank 12 in the lower region 20 is large. Even if the dropped molten metal stays in the lower region 20, the formation of a hole in the tank 12 (secondary burn-through) is suppressed. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

When the inner diameter 12d of the tank 12 is large, the distance between the conductor 15 and the tank 12 is large. At this time, there is a possibility that the melted metal material of the conductor 15 may fall to a position away from the vertically downward direction in the axial direction. The length of the lower region 20 in the axial direction (Y direction) is equal to the length of the inner diameter 12 d of the tank 12 . Therefore, the possibility of molten metal falling within the lower region 20 is high. The length of the lower region 20 in the circumferential direction of the tank 12 may be the length of the inner diameter 12 d of the tank 12 .

A first modification of the first embodiment will be described.
5 and 6 are cross-sectional views of a gas-insulated switchgear according to a first modification of the first embodiment. 5 is a side cross-sectional view taken along line BB of FIG. 6. FIG. 6 is a front cross-sectional view taken along line AA of FIG. 5. FIG. A description of the first modification that is the same as the first embodiment is omitted.

As shown in FIG. 6, the tank 12 has support members 25 . The support member 25 supports the tank 12 with respect to the installation surface of the gas-insulated switchgear. The support member 25 is integrally formed with the tank 12 by casting. A support member 25 is formed below the tank 12 including the lower region 20 . The length of the support member 25 in the X direction is greater than or equal to the length of the lower region 20 in the X direction. A lower end surface of the support member 25 is a horizontal surface.

As shown in FIG. 5, the axial length of support member 25 is equal to or greater than the axial length of lower region 20 . The support member 25 is formed to protrude downward from the outer peripheral surface of the tank 12 . The thickness 20t of the tank 12 in the lower region 20 is thicker than the thickness 21t of the tank 12 in the upper region 21 . The thickness 20t of the tank 12 in the lower region 20 is the height of the support member 25 in the Z direction.

Thus, the tank 12 of the first variant has a support member 25 for the tank 12 formed in the lower region 20 . The support member 25 increases the thickness of the tank 12 in the lower region 20, thereby suppressing the formation of holes in the tank 12 due to secondary burn-through. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

A second modification of the first embodiment will be described.
7 and 8 are cross-sectional views of a gas-insulated switchgear according to a second modification of the first embodiment. 7 is a side cross-sectional view taken along line BB of FIG. 8. FIG. 8 is a front cross-sectional view taken along line AA of FIG. 7. FIG. A description of the second modification that is the same as the first embodiment is omitted.

As shown in FIG. 8, the tank 12 has a peripheral member 27. As shown in FIG. The outer peripheral member 27 is arranged on the outer peripheral surface of the lower region 20 . The outer peripheral member 27 is made of the same metal material as the tank 12, such as aluminum. The outer peripheral member 27 is a metal plate having a predetermined thickness and is fixed to the outer peripheral surface of the tank 12 by welding or the like. Since the outer peripheral member 27 is made of the same material as the tank 12, welding of the outer peripheral member 27 to the tank 12 is facilitated. The outer peripheral member 27 may be formed on the outer peripheral surface of the tank 12 by coating (thermal spraying) a metal material or the like.

As shown in FIG. 7, the thickness 20t of the tank 12 in the lower region 20 is thicker than the thickness 21t of the tank 12 in the upper region 21 . The thickness 20 t of the tank 12 in the lower region 20 is the sum of the thickness of the cylindrical portion 12 p of the tank 12 and the thickness of the outer peripheral member 27 .

Thus, the tank 12 of the second modified example has the outer peripheral member 27 with a predetermined thickness arranged on the outer peripheral surface of the lower region 20 . The peripheral member 27 increases the thickness of the tank 12 in the lower region 20, thereby suppressing the formation of holes in the tank 12 due to secondary burn-through. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

A third modification of the first embodiment will be described.
9 and 10 are cross-sectional views of a gas-insulated switchgear according to a third modification of the first embodiment. 9 is a side cross-sectional view taken along line BB of FIG. 10. FIG. 10 is a front cross-sectional view taken along line AA of FIG. 9. FIG. A description of the third modification that is the same as the first embodiment is omitted.

As shown in FIG. 10 , the tank 12 has a recess (handhole) 30 and a closing plate (lid) 34 . A recess 30 is formed in the lower region 20 . The recess 30 is recessed radially outward of the tank 12 . The bottom of the recess 30 is open. The recess 30 is formed integrally with the tank 12 using the same forming material as the tank 12 . The closing plate 34 closes the bottom opening of the recess 30 . The closing plate 34 may be detachable from the recess 30 . By removing the closing plate 34, maintenance of the inside of the tank 12 can be performed through the recess 30. As shown in FIG.

As shown in FIG. 9, the thickness 20t of tank 12 in lower region 20 is thicker than the thickness 21t of tank 12 in upper region 21 . The thickness 20t of the tank 12 in the lower region 20 is the thickness of the closing plate 34 . The closing plate 34 is made of a material having a higher melting point than the material forming the tank 12 . For example, the closing plate 34 is made of an iron material having a higher melting point than aluminum, which is the material of the tank 12 . The closing plate 34 may be made of the same material as the tank 12 .

Thus, the tank 12 of the third modification has the recess 30 formed in the lower region 20 and the closing plate 34 that closes the bottom of the recess 30 . The closing plate 34 is made of a material having a higher melting point than the material forming the tank 12 . As described above, the heat of the arc causes the metal material of the conductor 15 to melt and fall onto the closing plate 34 at the bottom of the tank 12 . Since the melting point of the blocking plate 34 is high, the melting of the blocking plate 34 and the formation of a hole in the tank 12 (secondary burn-through) are suppressed. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

A fourth modification of the first embodiment will be described.
11 and 12 are cross-sectional views of a gas-insulated switchgear according to a fourth modification of the first embodiment. 11 is a side cross-sectional view taken along line BB of FIG. 12. FIG. 12 is a front cross-sectional view taken along line AA of FIG. 11. FIG. A description of the fourth modification that is the same as the first embodiment will be omitted.

As shown in FIG. 12, tank 12 has recess 30 . A recess 30 is formed in the lower region 20 . The recess 30 is recessed radially outward of the tank 12 . A bottom wall 39 closes the bottom of the recess 30 . The recess 30 and the bottom wall 39 are integrally formed with the tank 12 from the same material as the tank 12 .

As shown in FIG. 11, the thickness 20t of tank 12 in lower region 20 is thicker than the thickness 21t of tank 12 in upper region 21 . The thickness 20t of the tank 12 in the lower region 20 is the thickness of the bottom wall 39 of the recess 30 . The bottom wall 39 increases the thickness of the tank 12 in the lower region 20, thereby inhibiting secondary burn-through from perforating the tank 12. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

A fifth modification of the first embodiment will be described.
13 and 14 are cross-sectional views of a gas-insulated switchgear according to a fifth modification of the first embodiment. 13 is a side cross-sectional view taken along line BB of FIG. 14. FIG. 14 is a front cross-sectional view taken along line AA of FIG. 13. FIG. A description of the fifth modification that is the same as the first embodiment is omitted.

As shown in FIG. 14, the tank 12 has an inner circumferential member 40. As shown in FIG. The inner peripheral member 40 is arranged on the inner peripheral surface of the lower region 20 . The inner peripheral member 40 is a metal plate having a predetermined thickness and is fixed to the inner peripheral surface of the tank 12 by welding or the like. The inner peripheral member 40 may be formed on the inner peripheral surface of the tank 12 by coating with a metal material or the like.

As shown in FIG. 13, the thickness 20t of tank 12 in lower region 20 is thicker than the thickness 21t of tank 12 in upper region 21 . The thickness 20 t of the tank 12 in the lower region 20 is the sum of the thickness of the cylindrical portion 12 p of the tank 12 and the thickness of the inner circumferential member 40 . The inner peripheral member 40 is made of a material having a higher melting point than the material forming the tank 12 . For example, the inner peripheral member 40 is made of an iron material having a higher melting point than aluminum, which is the material of the tank 12 . The inner peripheral member 40 may be made of the same material as the tank 12 .

Thus, the tank 12 of the second modified example has the inner peripheral member 40 with a predetermined thickness arranged on the inner peripheral surface of the lower region 20 . The inner peripheral member 40 increases the thickness of the tank 12 in the lower region 20, thereby suppressing the formation of holes in the tank 12 due to secondary burn-through. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.
Since the material forming the inner peripheral member 40 has a high melting point, secondary burn-through is suppressed even if the thickness of the inner peripheral member 40 is reduced. By reducing the thickness of the inner peripheral member 40, the insulating distance between the inner peripheral member 40 and the conductor 15 is ensured.

(Second embodiment)
15 and 16 are cross-sectional views of the gas-insulated switchgear according to the second embodiment. 15 is a side cross-sectional view taken along line BB of FIG. 16. FIG. 16 is a front cross-sectional view taken along line AA of FIG. 15. FIG. A gas-insulated switchgear 201 of the second embodiment differs from that of the first embodiment in that it has a sleeve member 50 . The description of the second embodiment as to what is the same as the first embodiment is omitted.

As shown in FIG. 15, the cylindrical portion 12p of the tank 12 is formed with a constant thickness.
As shown in FIG. 16, the sleeve member 50 is a metal tube having a predetermined thickness and is arranged on the outer peripheral surface of the conductor 15. As shown in FIG. The sleeve member 50 may be formed on the outer peripheral surface of the conductor 15 by coating with a metal material or the like. As shown in FIG. 15, a second range 50y is defined adjacent to the spacer 17 in the axial direction (Y direction). The second range 50y in the axial direction is the length of the outer diameter 15d of the conductor 15 from the end of the conductor 15 on the side of the spacer 17 to the inside of the tank 12 . The sleeve member 50 covers the outer peripheral surface of the conductor 15 at least in the axial second range 50y. The sleeve member 50 may cover the outer peripheral surface of the conductor 15 in a range wider than the second range 50y in the axial direction.

The sleeve member 50 is made of a material having a smaller reaction heat with the insulating gas 19 than the material of the conductor 15 . The sleeve member 50 is made of a material having a higher melting point than the material of the conductor 15 . For example, when the conductor 15 is made of aluminum and the insulating gas 19 is sulfur hexafluoride (SF ₆ ) gas, the sleeve member 50 is made of iron, copper, or the like.

Thus, the gas-insulated switchgear 201 of the second embodiment has the sleeve member 50 . The sleeve member 50 covers the outer peripheral surface of the conductor 15 in a second range 50y adjacent to the spacer 17 in the axial direction. The sleeve member 50 is made of a material having a smaller reaction heat with the insulating gas 19 than the material of the conductor 15 .
As described above, the arc generated inside the tank 12 moves axially due to the electromagnetic force and stays near the spacer 17 . The arc contacts sleeve member 50 located adjacent spacer 17 . The forming material of the sleeve member 50 has a small heat of reaction with the insulating gas 19 . Melting of the forming material of the sleeve member 50 due to heat is suppressed, and dropping of the molten metal is suppressed. Secondary burn-through prevents the tank 12 from being punctured. Therefore, the gas-insulated switchgear 201 has high reliability against arc discharge.

The sleeve member 50 is made of a material having a higher melting point than the material of the conductor 15 .
Since melting of the material forming the sleeve member 50 is suppressed, dropping of the molten metal is suppressed. Secondary burn-through prevents the tank 12 from being perforated. Therefore, the gas-insulated switchgear 201 has high reliability against arc discharge.

A reference form will be described.
FIG. 17 is a side cross-sectional view of a gas-insulated switchgear of a reference embodiment. The reference embodiment differs from the first embodiment in that it has a pressure release device 60 . The description of the reference form regarding the same points as the first embodiment is omitted.

The pressure release device 60 releases the insulating gas 19 to the outside of the tank 12 when the pressure of the insulating gas 19 enclosed inside the tank 12 exceeds a predetermined pressure. The pressure release device 60 reduces the internal pressure of the tank 12 . A plurality of pressure relief devices 60 are attached to the tank 12 .

As previously mentioned, the heat of the arc causes the metallic material of conductor 15 to melt and fall to the bottom of tank 12 . The metal material of the tank 12 is melted by the molten metal staying at the bottom of the tank 12 . At the same time, the temperature and pressure of the insulating gas 19 rise due to heat of reaction due to arc discharge. A secondary burn-through occurs in which the tank 12 is perforated by the pressure of the insulating gas 19 before the metal material throughout the thickness of the tank 12 melts.

The pressure release device 60 reduces the internal pressure of the tank 12 . Normally, one pressure relief device 60 is provided for each gas compartment, but when the tank volume is large, the rate at which the internal pressure decreases is slowed down. A plurality of pressure relief devices 60 quickly reduce the internal pressure of the tank 12 . Secondary burn-through prevents the tank 12 from being perforated. Therefore, the gas-insulated switchgear 301 has high reliability against arc discharge.

The pressure relief device 60 may be attached to the gas-insulated switchgear of the first embodiment, its modification, and the second embodiment. This suppresses the formation of holes in the tank 12 due to secondary burn-through. Therefore, the gas-insulated switchgear 1 has high reliability against arc discharge.

According to at least one embodiment described above, the thickness 20t of the tank 12 in the lower region 20 is thicker than the thickness 21t of the tank 12 in the upper region 21 . Thereby, the gas-insulated switchgear has high reliability against arc discharge.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1, 201... Gas insulated switchgear, 12... Tank, 12d... Inside diameter, 15... Conductor, 15d... Outside diameter, 17... Spacer (partition member), 19... Insulating gas, 20... Lower area, 20t... Thickness, 20y First range 21 Upper region 21t Thickness 25 Supporting member 27 Peripheral member 30 Recess 34 Closing plate 40 Inner peripheral member 50 Sleeve member 50y Second range , 60... Pressure relief device.

Claims (5)

a tank formed in a cylindrical shape and filled with insulating gas;
a conductor disposed inside the tank and extending in the axial direction of the tank;
a partition member that partitions the interior of the tank in the axial direction and supports the conductor;
A region obtained by projecting the conductor onto the tank below the conductor in the axial first range adjacent to the partition member in the axial direction is defined as a lower region of the tank, and the conductor is defined in the axial first range. is projected onto the tank above the conductor, the thickness of the tank in the lower area is thicker than the thickness of the tank in the upper area, and
the tank has a support member for the tank formed in the lower region ;
Gas insulated switchgear. a tank formed in a cylindrical shape and filled with insulating gas;
a conductor disposed inside the tank and extending in the axial direction of the tank;
a partition member that partitions the interior of the tank in the axial direction and supports the conductor;
A region obtained by projecting the conductor onto the tank below the conductor in the axial first range adjacent to the partition member in the axial direction is defined as a lower region of the tank, and the conductor is defined in the axial first range. is projected onto the tank above the conductor, the thickness of the tank in the lower area is thicker than the thickness of the tank in the upper area, and
The tank has a recess formed in the lower region and a closing plate that closes the bottom of the recess,
The closure plate is formed of a material having a higher melting point than the material forming the tank ,
Gas insulated switchgear. a tank formed in a cylindrical shape and filled with insulating gas;
a conductor disposed inside the tank and extending in the axial direction of the tank;
a partition member that partitions the interior of the tank in the axial direction and supports the conductor;
A region obtained by projecting the conductor onto the tank below the conductor in the axial first range adjacent to the partition member in the axial direction is defined as a lower region of the tank, and the conductor is defined in the axial first range. is projected onto the tank above the conductor, the thickness of the tank in the lower area is thicker than the thickness of the tank in the upper area, and
The tank has an inner peripheral member with a predetermined thickness arranged on the inner peripheral surface of the lower region,
The inner peripheral member is formed of a material having a higher melting point than the material forming the tank ,
Gas insulated switchgear. The first range in the axial direction is a range of the length of the inner diameter of the tank from the contact position between the partition member and the tank to the inside of the tank.
The gas insulated switchgear according to any one of claims 1 to 3 . a pressure release device that releases the insulating gas to the outside of the tank when the pressure of the insulating gas exceeds a predetermined pressure;
The gas insulated switchgear according to any one of claims 1 to 4 .

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