KR101043371B1 - Method for eliminating moisture of gis current transformer section using excitation characteristics of the current transformer - Google Patents

Abstract

PURPOSE: A method for eliminating water in the current transformer section of a GIS(Gas Insulated Switchgear) is provided to prevent a short circuit by eliminating moisture contained in the insulating paper of a GIS current transformer section. CONSTITUTION: A SF6(Sulphur Hexafluoride) gas reclaimer valve(14) is connected to the current transformer section coke of a GIS installed in an operating case(1) of a GIS. SF6 gas is collected in the main body of a SF6 gas reclaimer(16). The SF6 gas removes foreign substances and moisture with a filter(17) installed inside the main body of the SF6 gas reclaimer. The SF6 gas, which is collected by the compression of the inner main body of the SF6 gas reclaimer, is compressed and kept. The connection of a SF6 gas reclaimer valve with a current transformer section coke(2) of the GIS is disconnected.

Description

Method for eliminating moisture of GIS current transformer section using excitation characteristics of the current transformer}

The present invention relates to a method for removing water in a gas insulated switchgear section by using the excitation characteristics of a current transformer, in particular SF ₆ in a gas insulated switchgear (GIS: gas insulated switchgear). During the purification of the gas, when the vacuum is formed, the temperature of the coil of the current transformer is raised by using the voltage (saturation voltage) applied within the limit of the excitation characteristic (saturation test) of the current transformer, and is contained in the insulating paper by the temperature difference. Moisture is naturally discharged into the air, and the discharged water is removed in the vacuum forming step to form a vacuum of 0.2 Torr or less, followed by injection of SF ₆ gas, and the moisture content does not increase until the GIS is subsequently opened. It is to provide a water removal method of the GIS current transformer section using the excitation characteristics of the current transformer.

In general, GIS (gas insulated switchgear) uses the excellent physical properties of SF ₆ , an inert gas in power substations, to safely operate under abnormal conditions such as short-circuit accidents as well as switching current in a steady state. It is a complex mechanical device used for over 170kV class transformers to protect the system by opening and closing. GIS is a switchboard, current transformer, and voltage transformer, such as a breaker, disconnector, and earthing switch, inside a metal enclosure grounded with SF ₆ gas. ), And an accessory such as a lightning arrester.

The most common cause of breakdown of substation equipment is discharge due to insulation breakdown caused by moisture, which causes insulation paper to be damaged, causing short circuit, and finally causing breakdown of substation equipment. Serious safety accidents can be caused by such a faulty substation, and it is best to completely remove moisture to prevent such safety accidents. However, the conventional technique is to remove the moisture contained in the insulation paper of the GIS current transformer section. There was no way.

In general, the current transformer of the insulation paper impregnation method of the GIS is provided with three times more insulation paper than the other sections, and the GIS in the prior art performs a vacuum process by simply doubling the vacuum time compared to the other sections without removing moisture. There was this. Furthermore, in the prior art, despite the fact that the vacuum process time in the GIS current transformer section is three times longer than the other sections, in the presence of moisture (that is, after not forming a vacuum below the prescribed value of 0.2torr), SF ₆ Injecting gas. Since SF ₆ gas is injected in a state in which no vacuum below the prescribed value is formed, more moisture (500 PPM to 1000 PPM in the operating state) is released due to self-heating of the current transformer CT during GIS operation.

In addition, the prior art has a problem that the occurrence of safety accidents and the life of the current transformer is shortened due to the insulation breakdown caused by moisture present in the GIS current transformer section, and the purification process time of SF ₆ gas of the GIS is increased.

The present invention is to solve the above problems, SF _{6 in the} GIS During the purification of the gas, when the vacuum is formed, the temperature of the current transformer coil is raised to the applied voltage within the limit of the excitation characteristic of the current transformer to naturally discharge the moisture present in the insulating paper to the outside due to the temperature difference. removing the object of the SF ₆ gas is injected after the formation of a vacuum below the 0.2torr, service until a subsequent opening GIS removes moisture from the GIS using the current transformer section woman characteristics so as not to increase the moisture content of the current transformer method It is done.

Water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention comprises the steps of connecting the SF ₆ gas recovery valve to the current transformer section of the GIS installed cock of the GIS operation box; Recovering SF ₆ gas to the SF ₆ gas recoverer body using a recovery pump; Removing the foreign matter and moisture by the SF ₆ gas recovered by the recovery step to the filter installed in the interior of the SF ₆ gas collector body; Comprising: stored by compressing the SF ₆ gas recovery compresses the inside of the SF ₆ gas collector body; Disconnecting the SF ₆ gas return valve connected to the current transformer section coke of the GIS; Connecting a vacuum pump valve to a current transformer section coke of the GIS installed in the GIS operating box; Connecting a current transformer tester set to a current transformer terminal provided in a current transformer terminal box installed in the GIS operating box through a current transformer terminal connection line; Testing the excitation characteristics of the current transformer with the current transformer tester set; Applying a voltage within a limit of the current transformer excitation characteristic; Driving a vacuum pump to form a vacuum; Disconnecting the vacuum pump valve connected to the current transformer section coke of the GIS installed in the GIS operating box; Releasing the voltage applied to the current transformer; Reconnecting the SF ₆ gas return valve to the current transformer section coke of the GIS installed in the GIS operation box; Injecting SF6 gas, which is compressed and stored in the SF ₆ gas recoverer body, into the GIS at a prescribed value; And disconnecting the SF ₆ gas recovery valve connected to the current transformer section coke of the GIS installed in the GIS operating box.

In addition, in another preferred embodiment according to the present invention, the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer is in the case of more than 0.2torr (tor) by checking the vacuum state with a vacuum system installed in the vacuum pump body after the vacuum forming step The method may further include checking a vacuum state that returns to forming the vacuum again.

Further, in another preferred embodiment of the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention, in the step of applying a voltage within the excitation characteristic limit, the current transformer is C800 type on the 154KV line of such a current transformer limit of excitation characteristics A saturation voltage of 800V is applied.

Further, in another preferred embodiment of the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention, in the step of applying a voltage within the excitation characteristic limit, the current transformer is C800 type on the 345KV line of the current transformer limit the excitation characteristic A saturation voltage of 800V is applied.

Through the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention it is possible to remove the water contained in the insulating paper of the GIS current transformer section, it is possible to form a vacuum of the GIS current transformer section to 0.2torr or less. In addition, SF ₆ gas may be injected in a vacuum of 0.2 torr or less to prevent a short circuit due to insulation breakdown caused by insulation damage of the insulating paper. In addition, it prevents damage to insulating paper, which improves the safety of the GIS, extends the life of the current transformer, reduces replacement costs and maintenance costs, and shortens the vacuum forming time, thereby reducing the overall SF ₆ gas refining process time. It has an effect.

1 is a schematic block diagram of a method for removing water in a GIS current transformer section using excitation characteristics of a current transformer according to the present invention.
Figure 2 shows a flow chart of the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, the same components are designated by the same reference numerals.

1 is a schematic block diagram of a method for removing water in a GIS current transformer section using excitation characteristics of a current transformer according to the present invention, and FIG. 2 is a procedure of a method for removing water in a GIS current transformer section using an excitation characteristic of a current transformer according to the present invention. Shows a figure.

Water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention is the connection step (S11), SF ₆ gas recovery step (S12), SF ₆ gas removal step (S13) of the SF ₆ gas recovery valve, compressed storage step (S14) of the SF ₆ gas, SF ₆ release phase of the gas collector valve (S15), female characteristics of the vacuum pump connection phase of the valve (S16), the connection phase of the current transformer tester set (S17), the current transformer test phase ( S18), applying a voltage within the range of the excitation characteristic (S19), vacuum forming step (S20), the release step of the vacuum pump valve (S21), the step of releasing the voltage (S22), reconnecting the SF ₆ gas recovery valve Step S23, a prescribed value SF ₆ gas injection step S24, and a release step S25 of the SF ₆ gas recovery valve.

When the water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention is started (S10), the current transformer section of the GIS installed in the GIS operation box (1) through the SF ₆ gas recovery pipe (11) (2) To the SF ₆ gas return valve (14). SF ₆ gas after the connecting step (S11) of the collector valve, opening the valve SF ₆ gas recovery period, thereby operating the recovery pump 15 is collecting the SF ₆ gas to the SF ₆ gas collector body (16). SF ₆ to remove any debris and moisture by a subsequent gas recovery step (S12), the recovered SF ₆ gas to the filter 17 provided in the interior of the SF ₆ gas collector body (16). At this time, the moisture removal management value of the SF ₆ gas is 300PPM, the tolerance should be maintained below 500PPM. At least the moisture contained in the SF ₆ gas in the SF ₆ gas recoverer should be kept below the control value, and the moisture contained in the SF ₆ gas is preferably 100 PPM or less.

The SF ₆ gas from which moisture has been removed is compressed inside the SF ₆ gas recoverer main body 16 and stored in the SF ₆ gas recoveror main body 16 or the SF ₆ gas liquefaction tank 18. After the compression storage step (S14) of the SF ₆ gas, thereby releasing the connection of the SF ₆ gas recovery period valve 14 is connected to the GIS of the current transformer section cock (2). After the release step S15 of the SF ₆ gas recovery valve, the vacuum pump valve 7 is connected to the current transformer section coke 2 of the GIS installed in the GIS operation box 1 through the vacuum pipe 5.

Water removal method of the GIS current transformer section using the excitation characteristics of the current transformer according to the present invention, as shown in Figure 1, the SF ₆ gas recovery valve 14 connected to the current transformer section cock 2 of the GIS to recover the SF ₆ gas Afterwards, the SF ₆ gas recovery valve 14 may be removed, and the vacuum pump valve 7 may be connected, and the SF ₆ gas recovery piping 11 and the vacuum piping 5 are coupled to the current transformer section coke 2 of the GIS. One pipe is connected and connected to the GIS current transformer section coke by opening and closing the SF ₆ gas recovery valve 14 installed in the SF ₆ gas recovery pipe 11 and the vacuum pump valve 7 installed in the vacuum pipe 5. It may be configured to be connected or released. After the connecting step (S16) of the vacuum pump valve, the current transformer tester set 21 through the current transformer terminal connecting line 19 to the current transformer terminal 20 provided in the current transformer terminal box 3 installed in the GIS operating box (1). Connect it. In a preferred embodiment of the present invention, five current transformer terminals 20 are provided, but are not necessarily limited thereto.

After the current transformer tester set connection step S17, the excitation characteristics of the current transformer are tested with the current transformer tester set 21. The excitation characteristic test of the current transformer should be sufficiently high that the saturation voltage is high enough to provide reliable protection in the high current range, the measuring current transformer must be accurate within the ratings, and be formed to have the characteristic of saturating in case of an accident and protecting the instrument and circuit. . In addition, the current transformer for the relay must be able to react in case of an accident, so it must be formed so as not to saturate at recurrent.

The saturation voltage of the current transformer does not increase the secondary current even if the primary current increases when the current transformer is saturated, and can be obtained by increasing the excitation current by 50% when the saturation point of the current transformer increases by 10%. .

Table 1 shows the current transformer error class for each relay. In the saturation voltage by the error class of Table 1, C800 means the saturation voltage is 800V, and it means to pressurize within the current limit of 5A in the range of 800V.

Current transformer error class for each voltage relay
For relay


Burden [VA]

Voltage

C Class

T Class
23KV

C200
T200
50
66KV

C400
T400
100
154KV

C800
T800
200
345KV

C800
T800
200
BUS pro.

C800

After the step of testing the excitation characteristics of the current transformer (S18), the voltage within the limit determined in this test is connected to the current transformer terminal of the current transformer section of the GIS to turn on the power while adjusting the voltage and current. By using the voltage (saturation voltage) applied within the limits of the excitation characteristic (saturation test), the temperature of the coil of the current transformer is increased, and the moisture contained in the insulating paper of the current transformer can be naturally discharged to the outside due to the temperature difference. do.

In another preferred embodiment of the present invention, in applying the voltage within the excitation characteristic limit (S19), the current transformer is turned on while checking the excitation characteristic test considering that the excitation characteristic limit is 800V in the C800 type on the 145KV line of the current transformer. It is desirable to. In another preferred embodiment of the present invention, in the step of applying a voltage within the excitation characteristic limit (S19), the current transformer is a C800 type in the 345KV line of the current transformer, considering that the excitation characteristic limit is 800V, It is preferable to add.

After applying the voltage (S19), the vacuum pump 9 is driven to form a vacuum, and the water discharged from the insulating paper of the current transformer is removed by the vacuum pipe 5 connected to the vacuum pump 9 of the GIS. It is possible to form a vacuum to 0.2torr or less inside.

Preferably, after the vacuum forming step (S20), further comprising the step of checking the vacuum state of the GIS with a vacuum gauge 8 installed in the vacuum pump body (10). If the checked vacuum state is 0.2torr or more, the flow returns to the vacuum forming step S20 to drive the vacuum pump 9 to rebuild the vacuum and check the reformed vacuum state. If the reformed vacuum is 0.2torr or less, the next step is performed.

After the vacuum check step S26, the connection of the vacuum pump valve 7 connected to the current transformer section cock 2 of the GIS installed in the GIS operating box 1 is released. Thereafter, the voltage applied to the current transformer is released. After releasing the voltage applied to the current transformer (S22), SF ₆ Reconnect the SF ₆ gas return valve 14 to the current transformer section cock 2 of the GIS installed in the GIS operating box 1 through the gas return pipe 11. After the SF ₆ gas recovery valve connecting step (S23), the SF ₆ gas that is compressed and stored in the SF ₆ gas recovery body 16 is injected into the GIS at a prescribed value. The prescribed value of such SF ₆ gas is preferably 5 kg / cm 2 · G. In order to inject SF ₆ gas of the prescribed value into the GIS, a pressure gauge 13 is provided in the SF ₆ gas recoverer main body 16 to check whether it corresponds to the prescribed pressure. After the SF ₆ gas injection step S24, the connection of the SF ₆ gas recovery valve 14 connected to the current transformer section cock 2 of the GIS installed in the GIS operation box 1 is released. When the moisture in the GIS current transformer section is removed by using the excitation characteristics of the current transformer according to the present invention, the moisture contained in the insulating paper of the current transformer is completely removed, and SF ₆ is injected at a prescribed value. The gas preferably contains moisture of 30 PPM or less. Therefore, the moisture content does not increase until the GIS is opened in the future, the discharge does not occur due to the breakdown of the insulation, and the short circuit caused by the damage of the insulation paper does not occur, and finally the failure of the substation facility can be prevented. .

The invention is not limited to the variants shown in the drawings, but may be extended to other embodiments that fall within the scope of the appended claims.

1: GIS operation box, 2: Current transformer section coke of GIS,
3: current transformer terminal box, 4: operation box valve,
5: vacuum piping 6: vacuum measuring valve,
7: vacuum pump valve, 8: vacuum gauge,
9: vacuum pump, 10: vacuum pump body,
11: SF6 gas recovery pipe, 12: SF ₆ gas measuring valve,
13: pressure gauge, 14: SF ₆ gas recovery valve,
15: recovery pump, 16: SF ₆ gas recovery body,
17: filter, 18: SF ₆ gas liquefaction tank,
19: current transformer terminal connecting line, 20: current transformer terminal,
21: current transformer tester set, S10: start,
S11: connection step of the SF ₆ gas recovery valve S12: SF ₆ gas recovery step,
S13: water removal step of SF ₆ gas, S14: compression storage step of SF ₆ gas,
S15: release step of SF ₆ gas recovery valve, S16: connection step of vacuum pump valve,
S17: connect the current transformer tester set, S18: excitation characteristic test step,
S19: applying voltage, S20: vacuum forming step,
S21: releasing the vacuum pump valve, S22: releasing the voltage,
S23: connection step of the SF ₆ gas recovery valve, S24: SF ₆ gas injection step,
S25: release step of SF ₆ gas return valve, S26: check of vacuum state.

Claims (4)

Connecting the SF ₆ gas recovery valve 14 to the current transformer section coke 2 of the GIS installed in the GIS operation box 1 (S11);
Recovering SF ₆ gas to the SF ₆ gas recoverer main body 16 using the recovery pump 15 (S12);
The method comprising the SF ₆ gas recovery by said recovery step (S12) to remove the debris and moisture by the filter 17 provided in the interior of the SF ₆ gas collector body (16) (S13);
Comprising: stored by the SF ₆ gas recovery period compressing the SF ₆ gas recovery by compressing the main body (16) (S14);
Disconnecting the SF ₆ gas return valve (14) connected to the current transformer section cock (2) of the GIS (S15);
Connecting a vacuum pump valve (7) to a current transformer section coke (2) of the GIS installed in the GIS operation box (S16);
Connecting a current transformer tester set (21) to a current transformer terminal (20) provided in the current transformer terminal box (3) installed in the GIS operating box (1) through a current transformer terminal connecting line (19);
Testing an excitation characteristic of a current transformer with the current transformer tester set 21 (S18);
Applying a voltage within the limit of the current transformer excitation characteristic (S19);
Driving a vacuum pump 9 to form a vacuum (S20);
After the vacuum forming step (S20) to check the vacuum state by the vacuum system 8 installed in the vacuum pump body 10 is 0.2torr or more, to check the vacuum state to return to the step of forming the vacuum again (S20) Step S26;
Disconnecting the vacuum pump valve (7) connected to the current transformer section cock (2) of the GIS installed in the GIS operating box (S21);
Releasing the voltage applied to the current transformer (S22);
Re-connecting the SF ₆ gas return valve 14 to the current transformer section coke 2 of the GIS installed in the GIS operation box 1 (S23);
Injecting SF ₆ gas, which is compressed and stored in the SF ₆ gas recoverer main body (16), into a GIS at a prescribed value (S24); And
Disconnecting the SF ₆ gas recovery valve 14 connected to the current transformer section coke 2 of the GIS installed in the GIS operation box 1 (S25); How to remove water in the transformer section.
The excitation characteristic of the current transformer according to claim 1, wherein in the step (S19) of applying the voltage within the excitation characteristic limit, the current transformer is applied with a saturation voltage having a limit of 800 V excitation characteristic to the C800 type on the 154KV line of the current transformer. Water removal method of GIS current transformer section using
The excitation characteristic of the current transformer according to claim 1, wherein in the step (S19) of applying the voltage within the excitation characteristic limit, the current transformer has a saturation voltage of 800 V excitation characteristic applied to the C800 type in the 345KV line of the current transformer. Water removal method of GIS current transformer section using

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