KR101083758B1 - Recovery device for analyzer gas of sf6-gas insulated switchgear and its method - Google Patents

Abstract

PURPOSE: An analyzed gas storing device of an SF6-gas insulated switchgear and a storing method thereof are provided to reduce operation costs by reusing SF6 gas stored in a storage tank. CONSTITUTION: A storage tank(140) is connected to a gas analyzer(120) through a pipe(101a,101b). The analyzed gas is stored in a storage tank. A vacuum compressor(150) vacuumizes the pipe and the storage tank. A parallel pipe(105) is connected in parallel to the pipe connected to the vacuum compressor. The parallel pipe is connected to the pipe between gas analyzer and the vacuum compressor and the pipe between the vacuum compressor and the storage tank. A first switch valve(161) controls the gas which flows from the gas analyzer to the vacuum compressor. A second switch valve(162) controls the gas which flows in the parallel pipe. A trigonal valve(165) discharges gas which passes through the vacuum compressor to the outside. A third switch valve(163) controls the gas flowing in the pipe.

Description

Analysis of sulfur hexafluoride gas insulated switchgear Gas storage device and its method {RECOVERY DEVICE FOR ANALYZER GAS OF SF6-GAS INSULATED SWITCHGEAR AND ITS METHOD}

The present invention relates to an analysis gas storage device and a method for analyzing sulfur hexafluoride gas insulated switchgear, and more particularly, by using a vacuum compressor on one side of a gas analyzer for analyzing a gas for performance test of the gas insulated switchgear. In the analysis gas storage device and the method of the sulfur hexafluoride gas insulated switchgear device and a method for installing a storage device for storing the gas after the analysis, so as to store all the gas after the analysis in the gas analyzer without releasing to the outside (atmosphere) It is about.

In general, most substations, breakers, switchgear and some transformers are gas-insulated products with SF6 gas as an insulating material in order to check the system for replacement or maintenance. In particular, a large amount of SF6 gas is installed and operated in substations.

SF6 gas is a compound consisting of fluorine (F) and sulfur (S), also referred to as 'sulfur hexafluoride'. SF6 gas has been known for its excellent insulation in 1937 since it was first discovered in 1900, and has been widely used as an electric insulator until now.

SF6 gas is inert, odorless and nontoxic gas under normal conditions and does not decompose up to 500 ℃. Insulation force is about 2.5 times higher than air, and at 3 atmospheres, it has the same insulation power as insulation oil. SF6-Gas is heavier than air, but it is only 1/140 of insulating oil, which is a big advantage in miniaturization and lightening of power equipment.

As is commonly known, GIS (Gas Insulated Switchgear) is the main component of substations, CB (Circuit Breaker), Disconnecting Switch, Earthing Switch, Lightning Arrester, Main Bus The main bus, the feeder bus, and the like are concentrated, and the specific part is filled with SF6 gas having excellent insulation and extinguishing characteristics, thereby miniaturizing the substation and improving safety and reliability.

Currently, gas insulators used in substations and large power receiving facilities use SF6 gas GIS, which seals and seals the opening and closing parts with SF6 gas.

The SF6 gas is a core power device of an ultra-high voltage substation, which is used for insulation materials or semiconductor manufacturing processes of most major power devices except transformers, and is embedded in a metal tank filled with SF6 gas. Have. SF6 gas is one of the best materials on earth with its insulation and arc removal capabilities. Accordingly, it is widely used as an insulator for power equipment such as breakers, switchgear, and switchgear. When the power is turned on and off, or when the general power supply and the emergency power supply are exchanged with each other, an arc of high temperature and high pressure is generated at the contact point. Inside the SF6 gas, the arc can be removed quickly. In addition, the filling parts such as buses through which electricity flows should be sufficiently separated from each other so that the separation distance within the SF6 gas can be significantly narrowed. This leads to the advantage of reducing the volume and weight of the device.

On the other hand, the global warming index and lifespan are very long. It is also an environmental pollutant. As a result, the Kyoto Protocol on Climate Change, which entered into force in February 2005, regulates its use. SF6 gas has the highest global warming effect among the six global warming gases defined by the Kyoto Protocol. In particular, the global warming index is 23,400 times higher than the representative global warming gas, carbon dioxide (CO2), which is regarded as the most serious environmental pollutant.

However, in the case of gas insulated power equipment such as GIS, most countries in Korea and abroad still apply the insulation method using SF6 gas.

In the case of overhauling or expanding the SF6 gas facility, the company is blowing up existing gas and filling new gas in order to reduce gas purity, mix impurities, and extend working hours. SF6 gas is emerging as the biggest headache of electric fields. In the case of the related 170V GIS, the SF6 gas filled in the GIS is removed after the periodical inspection and the new SF6 gas is injected after discarding the extracted SF6 gas.

This phenomenon is the same not only in GIS expansion but also in GIS, heavy electric equipment inspection of SF6 gas insulation method such as switchgear and breaker, and disposal after product replacement. This discarded SF6 gas accelerates environmental pollution.

Therefore, it is necessary to recover the SF6 gas from the gas insulator so as not to discharge to the outside.

As an example of a conventional gas recovery apparatus, the Republic of Korea Patent Publication No. 10-2011-0017572 will be described with reference to FIG. 1, as shown, the gas recovery apparatus, the insulation is filled in the GIS (1) A storage tank 2 in which SF6 gas, which is a medium gas, is recovered and stored, a suction pump 3 for sending the SF6 gas to the storage tank 2, a vacuum of the GIS 1 and a storage tank 2, A vacuum pump (4) installed for injection, a compressor (5) for differentially recovering SF6 gas in the GIS (1) to the storage tank (2), and the SF6 gas recovered in the storage tank (2) A cooling system 6, a heating unit 7 for vaporizing SF6 liquefied through the cooling system 6, a flow passage 8 having one or more valves and connecting the respective components, and the compressor 5 ), The suction pump (3), the vacuum pump (4), the cooling system (6), and the output of the heating section 7 to control the storage tank (2) A controller (not shown) which manages the temperature and determines an operating state of automatic recovery and recharging of residual SF6 gas in the GIS 1 is operated.

Here, the cooling system 6 is composed of a compressor 6a, a condenser 6b, an expansion valve 6c, and an evaporator 6d constituting a conventional refrigeration cycle.

In addition to the gas recovery device, a gas analyzer (not shown) is installed for performance test of the SF6 gas filled in the GIS 1.

The gas analyzer analyzes the gas by receiving a predetermined amount of the SF6 gas filled in the GIS 1, and determines whether to replace the SF6 gas based on the analyzed gas information.

However, in the related art, all of the gases analyzed by the gas analyzer are released to the atmosphere, that is, SF6 gas, which is an environmental substance, is released into the atmosphere, thereby contaminating the environment.

In addition, since the SF6 gas is analyzed and released through the gas analyzer to the atmosphere, there is a problem that the cost increases as a new purchase for the shortage after the SF6 gas analysis.

In addition, there was a problem that the overall structure is complicated, manufacturing costs increase.

An object of the present invention for solving the above problems is to install a storage device for storing the gas after the analysis using a vacuum compressor on one side of the gas analyzer for analyzing the gas for the performance test of the gas insulated switchgear, the gas By storing all the gases after analysis in the analyzer without releasing them to the outside (atmosphere), it does not release SF6 gas, which is an environmental pollutant, to reduce environmental pollution. The present invention provides a method and an analysis gas storage device for sulfur hexafluoride gas insulated switchgear that can reduce costs by reusing gas stored in a storage tank without purchasing, and can reduce manufacturing cost due to the simple structure.

In order to achieve the above object, the present invention provides a gas insulated switchgear using sulfur hexafluoride gas as an insulating material, the gas insulated switchgear is connected to the gas insulated switchgear through a pipe, and receives some gas from the gas insulated switchgear. And a storage device connected to the gas analyzer for analysis and connected to the gas analyzer through a pipe and receiving and storing the gas analyzed by the gas analyzer, wherein the storage device is connected to the gas analyzer through a pipe to connect the gas. A storage tank for storing the gas analyzed by the analyzer; A vacuum compressor installed on a pipe connecting the gas analyzer and the storage tank to vacuum the pipe and the storage tank; A parallel pipe connected in parallel to the pipe connected to the vacuum compressor, one end of which is connected to the pipe between the gas analyzer and the vacuum compressor, and the other end of which is connected to the pipe between the vacuum compressor and the storage tank; A first opening / closing valve installed on a pipe between the gas analyzer and the vacuum compressor to control on / off gas flowing from the gas analyzer to the vacuum compressor side; A second opening / closing valve installed on the parallel pipe to control on / off gas flowing in the parallel pipe; A three-way valve installed on a pipe between the vacuum compressor and the other end of the parallel pipe to discharge gas passing through the vacuum compressor to the outside or to flow to the storage tank; And a third opening / closing valve installed on a pipe between the storage tank and the other end of the parallel pipe to control on / off gas flowing in the pipe.

In addition, a method for storing the gas analyzed by the gas analyzer using the analysis gas storage device of the sulfur hexafluoride gas insulated switchgear, the first step of turning off the gas analyzer, the first opening and closing valve and the second opening and closing valve And opening a third opening / closing valve, wherein the three-way valve is configured to change a direction such that air passing through the vacuum compressor is discharged to the outside; and after the second step, the vacuum compressor is operated to store the second valve. Discharging the gas in the tank, the pipe, and the parallel pipe to the outside to vacuum the storage tank, the pipe, and the parallel pipe, and closing the second opening / closing valve when the vacuum is completed through the third step. The three-way valve is a fourth step of changing the direction so that the air passing through the vacuum compressor flows to the storage tank side, and after the fourth step, the gas analyzer The gas analyzer is turned on to perform a gas analysis and the analyzed gas is introduced into and stored in the vacuum storage tank through the vacuum compressor, and when the gas analysis is completed through the fifth step, the gas analyzer is analyzed. And turning off the gas remaining in the pipe through the vacuum compressor into the storage tank, and closing the first opening / closing valve, the second opening / closing valve, and the third opening / closing valve. It is characterized by.

The present invention, by installing a storage device for storing the gas after the analysis using a vacuum compressor on one side of the gas analyzer for analyzing the gas for the performance test of the gas insulated switchgear, outside the gas after the analysis in the gas analyzer By storing all the materials without emitting them into the atmosphere, the environmental pollution substances are not discharged to the atmosphere, thereby reducing environmental pollution, and the overall structure of the storage device is simple, thereby reducing manufacturing costs.

In addition, the shortage due to the SF6 gas analysis can be reduced by reusing the SF6 gas stored in the storage tank without purchasing a new SF6 gas.

If there are impurities in the storage tank, the pipe, and the parallel pipe, all the impurities are released to the outside during the operation of the vacuum compressor for vacuum of the storage device, thereby storing the SF6 gas that has been analyzed by the gas analyzer after the vacuum. When stored in, it is possible to fundamentally block the mixing of impurities.

1 is a configuration diagram showing an example of a conventional gas recovery apparatus;
2 is a block diagram showing an analysis gas storage device of the sulfur hexafluoride gas insulated switchgear according to the present invention;
3 is a configuration diagram showing a vacuum at FIG. 2;
FIG. 4 is a configuration diagram illustrating gas storage after vacuum in FIG. 2.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The analysis gas storage device 100 of the sulfur hexafluoride gas insulated switchgear according to the present invention includes a gas insulated switchgear 110, a gas analyzer 120, and a storage device 130.

The gas insulated switchgear 110 includes a circuit breaker (CB), a disconnecting switch, an earthing switch, a lightning arrester, a main bus, and a branch that are main components of a substation. By condensing a circuit (Feeder Bus) and the like, and filling a specific part with SF6 gas, which is an insulating material having excellent insulation and extinguishing characteristics, the substation can be miniaturized and safety and reliability can be improved.

Since the gas insulated switchgear 110 is known, a detailed description thereof will be omitted.

The gas analyzer 120 is connected to the gas insulated switchgear 110 and the pipe 101 to receive a predetermined amount of SF6 gas from the gas insulated switchgear 110 to analyze the gas.

The user analyzes the SF6 gas through the gas analyzer 120 and determines whether to replace the SF6 gas based on the analyzed gas information.

Since the gas analyzer 120 is also a known product, a detailed description thereof will be omitted.

The storage device 130 includes a storage tank 140, a vacuum compressor 150, a parallel pipe 105, a first open / close valve 161, a second open / close valve 162, and three directions. The valve 165 and the third open / close valve 163 are configured to be included.

The storage tank 140 is spaced apart from the gas analyzer 120 at a predetermined interval and connected to the gas analyzer 120 through the pipes 101a and 101b to store the gas analyzed by the gas analyzer 120. do.

On the outer surface of the storage tank 140, a pressure gauge 141 for displaying the pressure in the storage tank 140 is installed.

In addition, the vacuum compressor 150 is installed on a pipe 101a connecting the gas analyzer 120 and the storage tank 140 to the pipes 101a and 101b, the parallel pipe 105 and the storage tank ( 140) to serve as a vacuum.

Of course, the vacuum compressor 150 may serve not only to vacuum the pipes 101a and 101b, the parallel pipe 105 and the storage tank 140 but also to blow a gas such as SF6 gas.

In the vacuum compressor 150, the left side (gas analyzer 120 side) is the inlet side and the right side (the storage tank 140 side) is the outlet side.

The parallel pipes 105 are connected in parallel to the pipes 101a and 101b to which the vacuum compressor 150 is connected.

At this time, one end of the parallel pipe 105 is connected to the pipe (101a) between the gas analyzer 120 and the vacuum compressor 150, the other end is between the vacuum compressor 150 and the storage tank 140 It is connected with the pipe 101b.

The first opening / closing valve 161 is installed on the pipe 101a between the gas analyzer 120 and the vacuum compressor 150 to turn on gas flowing from the gas analyzer 120 to the vacuum compressor 150. Off control.

In this case, the first opening / closing valve 161 may be installed on the pipe 101a between one end of the parallel pipe 105 and the gas analyzer 120.

On the other hand, the first opening and closing valve 161 is opened when the vacuum, after the vacuum SF6 gas after the analysis from the gas analyzer 120 is also opened when storing in the storage tank 140, the storage tank 140 After all SF6 gas has been stored, it is closed.

The second opening / closing valve 162 is installed on the parallel pipe 105 to control on / off gas flowing in the parallel pipe 105.

The second opening / closing valve 162 is opened when the vacuum, SF6 gas after the analysis from the gas analyzer 120 after the vacuum is closed when storing in the storage tank 140, SF6 gas in the storage tank 140 It is closed even after all are saved.

Meanwhile, a suction pressure gauge 164 may be installed on the parallel pipe 105.

In addition, the three-way valve 165 is provided on the pipe 101b between the vacuum compressor 150 and the other end of the parallel pipe 105.

The three-way valve 165 discharges the gas passed through the vacuum compressor 150 to the outside through the change of direction, or flows the gas passed through the vacuum compressor 150 to the storage tank 140 side. .

That is, in the vacuum of the pipes 101a and 101b, the parallel pipe 105 and the storage tank 140, the vacuum compressor 150 is connected to the pipes 101a and 101b by a vacuum function as shown in FIG. The air filled in the pipe 105 and the storage tank 140 is discharged to the three-way valve 165. At this time, the three-way valve 165 discharges the air discharged from the vacuum compressor 150 to the outside (atmosphere). It will play a role.

In addition, when the SF6 gas is stored after vacuum, as shown in FIG. 4, the gas analyzer 120 is analyzed by the differential pressure between the gas analyzer 120 and the storage tank 140 and by the blowing function of the vacuum compressor 150. SF6 gas is passed through the vacuum compressor 150, wherein the three-way valve 165 serves to flow the SF6 gas passed through the vacuum compressor 150 to the storage tank 140 side.

The third opening / closing valve 163 is installed on the pipe 101b between the storage tank 140 and the other end of the parallel pipe 105 to turn on / off gas flowing in the pipe 101b. To control.

The third opening / closing valve 163 is opened when the vacuum is opened, the SF6 gas after the analysis from the gas analyzer 120 after the vacuum is also opened when storing in the storage tank 140, SF6 gas in the storage tank 140 It is closed after all have been saved.

Hereinafter, a method of storing the gas analyzed by the gas analyzer 120 using the analysis gas storage device 100 of the sulfur hexafluoride gas insulated switchgear according to the present invention will be described.

First, a first step of turning off the gas analyzer 120 is performed.

The gas analyzer 120 is turned on when it is necessary to analyze the SF6 gas, and is normally turned off.

When gas analysis is required, the pipes 101a and 101b, the parallel pipe 105 and the storage tank 140 are first vacuumed before the gas analyzer 120 is turned on, that is, the gas analyzer 120 is turned off. It must be made in a state.

Therefore, in order to store the gas analyzed by the gas analyzer 120 as in the present invention, it is necessary to first turn off the gas analyzer 120.

Meanwhile, in the state in which the gas analyzer 120 is turned off, SF6 gas filled in the gas insulation switchgear 110 is not supplied to the gas analyzer 120, and when the gas analyzer 120 is turned on, the gas insulation switch is turned on. A predetermined amount of SF6 gas filled in the device 110 is supplied to the gas analyzer 120 and then supplied to the storage device 130.

Next, the first opening / closing valve 161, the second opening / closing valve 162, and the third opening / closing valve 163 are opened, and the three-way valve 165 has air passing through the vacuum compressor 150 outside. Proceed with the second step of changing the direction to release to (atmosphere).

That is, when all of the first, second, and third open / close valves 161, 162, 163 are opened, the pipes 101a, 101b, the parallel pipe 105, and the storage tank 140 are in communication with each other.

After the second step, by operating the vacuum compressor 150 to discharge the gas in the storage tank 140, the pipes (101a, 101b) and parallel pipe 105 to the outside to the storage tank 140 And a third step of evacuating the pipes 101a and 101b and the parallel pipe 105.

Since the gas analyzer 120 is turned off, when the vacuum compressor 150 is operated, air filled in the pipes 101a and 101b and the parallel pipe 105 is transferred to the vacuum compressor 150 as shown in FIG. 3. In this case, the air filled in the storage tank 140 flows through the third opening / closing valve 163 to the parallel pipe 105, and then passes through the second opening / closing valve 162 to the vacuum compressor 150. Will be inhaled.

Thereafter, the air sucked into the vacuum compressor 150 is discharged to the three-way valve 165 and then discharged to the outside through the three-way valve 165.

As such, when the vacuum compressor 150 is operated, all of the air filled in the storage tank 140, the pipes 101a and 101b, and the parallel pipe 105 are discharged to the outside, so that the storage tank 140 and the pipe 101a, 101b) and the parallel pipe 105 are maintained in a vacuum state.

In addition, when there are impurities in the storage tank 140, the pipes 101a and 101b, and the parallel pipe 105, all of the impurities are external to the impurities during the operation of the vacuum compressor 150 for the vacuum of the storage device 130. By being discharged to, when the SF6 gas is stored in the storage tank 140 in a step to be described later, it is possible to fundamentally block the mixing of impurities.

Subsequently, when the vacuum is completed through the third step, the second opening / closing valve 162 is closed, and the three-way valve 165 passes through the vacuum compressor 150 to the storage tank 140. Proceed with the fourth step of diverting direction to flow.

That is, in the fourth step, the parallel pipe 105 is closed by closing the second opening / closing valve 162, so that the SF6 gas analyzed by the gas analyzer 120 is stored through the pipes 101a and 101b. It is to be introduced into the tank 140.

If the fourth step is passed, the gas analyzer 120 is turned on.

Subsequently, after the fourth step, a fifth step of performing gas analysis by turning on the gas analyzer 120 is performed.

When the gas analyzer 120 is turned on, a predetermined amount of SF6 gas is supplied into the gas analyzer 120 from the gas insulated switchgear 110, and the gas analyzer 120 is supplied from the gas insulated switchgear 110. Analyze the gas.

The SF6 gas analyzed in the gas analyzer 120 is introduced into and stored in the storage tank 140 in the vacuum state by the blowing function of the vacuum compressor 150.

Of course, SF6 gas, which has been analyzed in the gas analyzer 120, is naturally introduced into the vacuum storage tank 140 by the pressure difference between the gas analyzer 120 and the storage tank 140 in the vacuum state. There is a part.

Referring to FIG. 4, the SF6 gas analyzed in the gas analyzer 120 passes through the first and second valves 161, passes through the vacuum compressor 150, and passes through the vacuum compressor 150. Is passed through the three-way valve 165 and the third opening and closing valve 163 to the storage tank 140 is stored.

When the gas analysis is completed through the fifth step, the gas analyzer 120 is turned off and the gas remaining in the pipes 101a and 101b through the vacuum compressor 150 into the storage tank 140. After entering and storing, a sixth step of closing all of the first open / close valve 161, the second open / close valve 162, and the third open / close valve 163 is performed.

In the sixth step, even if the gas analyzer 120 is turned off, the pipes 101a and 101b are still filled with SF6 gas.

Accordingly, the SF6 gas filled in the pipes 101a and 101b using the blowing function of the vacuum compressor 150 to introduce all the SF6 gas filled in the pipes 101a and 101b into the storage tank 140. All will be introduced into the storage tank 140.

Thereafter, after all of the SF6 gas is stored in the storage tank 140, the first opening / closing valve 161, the second opening / closing valve 162, and the third opening / closing valve 163 are closed to close the storage tank 140. SF6 gas stored in the inside is prevented from being released to the outside.

Meanwhile, since a predetermined amount of SF6 gas filled in the gas insulated switchgear 110 is used for the SF6 gas analysis of the gas analyzer 120, the deficiency of the SF6 gas is caused by the SF6 gas stored in the storage tank 140. Will be reused.

As such, by reusing the SF6 gas stored in the storage tank 140 without purchasing a new SF6 gas, the cost can be reduced, and the overall structure of the storage device 130 can be simplified, thereby reducing the manufacturing cost.

Meanwhile, the SF6 gas stored in the storage tank 140 is supplied to the gas insulated switchgear 110 by using a separate equipment.

100: analysis gas storage device 101,101a, 101b: pipe
105: parallel pipe 110: gas insulated switchgear
120: gas analyzer 130: storage device
140: storage tank 150: vacuum compressor
161: first opening and closing valve 162: second opening and closing valve
163: third open and close valve 165: three-way valve

Claims (2)

Gas insulated switchgear 110 using sulfur hexafluoride gas as an insulating material, the gas insulated switchgear 110 and the pipe 101 is connected through the gas insulated switchgear 110 and some gas supplied from the gas Including a gas analyzer 120 for analyzing the gas, the storage device 130 is connected to the gas analyzer 120 and the pipes (101a, 101b) and receives and stores the gas analyzed by the gas analyzer 120. But
The storage device 130,
A storage tank 140 connected to the gas analyzer 120 through pipes 101a and 101b to store the gas analyzed by the gas analyzer 120;
A vacuum compressor 150 installed on pipes 101a and 101b connecting the gas analyzer 120 and the storage tank 140 to vacuum the pipes 101a and 101b and the storage tank 140;
The vacuum compressor 150 is connected in parallel to the pipe (101a, 101b) connected, one end is connected to the pipe (101a) between the gas analyzer 120 and the vacuum compressor 150 and the other end is the vacuum compressor A parallel pipe 105 connected with the pipe 101b between the 150 and the storage tank 140;
A first opening / closing valve 161 installed on a pipe 101a between the gas analyzer 120 and the vacuum compressor 150 to control on / off gas flowing from the gas analyzer 120 to the vacuum compressor 150 side; ;
A second opening / closing valve (162) installed on the parallel pipe (105) to control on / off gas flowing in the parallel pipe (105);
Three-way installed on the pipe 101b between the vacuum compressor 150 and the other end of the parallel pipe 105 to discharge the gas passing through the vacuum compressor 150 to the outside or to flow to the storage tank 140 side. Valve 165;
And a third open / close valve 163 installed on the pipe 101b between the storage tank 140 and the other end of the parallel pipe 105 to control on / off gas flowing in the pipe 101b. Analysis gas storage device of sulfur hexafluoride gas insulated switchgear, characterized in that made. A method of storing the gas analyzed by the gas analyzer 120 using the analysis gas storage device of the sulfur hexafluoride gas insulated switchgear according to claim 1,
A first step of turning off the gas analyzer 120;
The first opening / closing valve 161, the second opening / closing valve 162, and the third opening / closing valve 163 are opened, and the three-way valve 165 is configured to discharge air passing through the vacuum compressor 150 to the outside. The second step of switching directions;
After the second step, by operating the vacuum compressor 150 to discharge the gas in the storage tank 140, the pipes (101a, 101b) and parallel pipe 105 to the outside to the storage tank 140 And a third step of vacuuming the pipes 101a and 101b and the parallel pipes 105,
When the vacuum is completed through the third step, the second opening / closing valve 162 is closed and the three-way valve 165 is configured such that air passing through the vacuum compressor 150 flows to the storage tank 140. The fourth step of switching
After the fourth step, the gas analyzer 120 is turned on to perform gas analysis, and the analyzed gas is introduced into and stored in the storage tank 140 in the vacuum state through the vacuum compressor 150. The fifth step,
When the gas analysis is completed through the fifth step, the gas analyzer 120 is turned off and the gas remaining in the pipes 101a and 101b through the vacuum compressor 150 into the storage tank 140. Sulfur hexafluoride gas insulated switchgear, characterized in that it comprises a sixth step of closing the first opening and closing valve 161, the second opening and closing valve 162 and the third opening and closing valve 163 after the inflow. Method of analysis gas storage.

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