KR20220129171A - Semi-automatic purging system and method for gas analysis of insulating oil - Google Patents

Abstract

The present invention relates to a semi-automatic purging system and method for gas-in-oil analysis securing a headspace by pushing out and discharging insulating oil while injecting argon gas into a vial filled with the insulating oil in order to use a headspace analysis method for gas-in-oil analysis of transformer insulating oil. The semi-automatic purging system according to an embodiment of the present invention comprises: an argon gas supply unit supplying or blocking argon gas at a constant pressure to an argon gas injection unit or vial by adjusting a main valve; an argon gas injection unit injecting the argon gas into the vial through a gas injection needle by adjusting the amount or time of the argon gas supplied from the argon gas supply unit according to the preset amount of discharged insulating oil; and an insulating oil discharge unit discharging the insulating oil from the vial through a venting needle according to the amount of the argon gas injected into the vial. Accordingly, accuracy of the gas-in-oil analysis can be increased.

Description

Semi-automatic purging system and method for gas analysis of insulating oil

The present invention relates to a semi-automatic purging system and method for gas-in-oil analysis, and in order to use a headspace analysis method for gas-in-oil analysis of transformer insulating oil, by injecting argon gas into a vial filled with insulating oil and pushing and discharging the insulating oil It relates to a gas-in-oil analysis semi-automatic purging system and method for securing a headspace.

In general, a transformer is one of the main equipment of a power supply system, and high reliability is required. In such a transformer, electrical or mechanical performance deteriorates due to deterioration during operation, and abnormalities occur. Failure to detect such a phenomenon in advance and take appropriate measures may cause serious accidents.

In addition, when abnormal phenomena such as insulation breakdown or local overheating occur inside the transformer, heat is necessarily generated. and gas is generated. At this time, most of these gases are dissolved in the insulating oil.

Therefore, it is possible to diagnose the type and extent of internal defects by extracting and analyzing the gas by extracting the insulating oil of the transformer. The transformer manager can prevent large losses by setting the concentration control standard of these gas-in-oil and monitoring it periodically or continuously to detect it at the early stage of an abnormality and take appropriate measures and prevent the progression to an unexpected accident such as a transformer explosion. have.

In order to measure the type and concentration of the gas dissolved in the insulating oil, a device for extracting the gas dissolved in the insulating oil in a gaseous state is required. In addition, as a method for extracting the gas-in-oil of the insulating oil, there are a membrane method, an air bubbling method, a headspace method, and the like.

Among them, the diaphragm method or the bubble degassing method has disadvantages such as a low extraction rate, a complicated structure, a long extraction time, and the insulation oil is saturated with air after extraction, so it is not suitable as a method applied to a continuous monitoring device in the field. However, the headspace method is a method that compensates for the disadvantages of the diaphragm method or the bubble degassing method, and has the advantage of a simple structure and convenient operation, and thus is widely used.

On the other hand, when applying the headspace analysis method for gas-in-oil analysis of transformer insulating oil, a space for extracting dissolved gas is secured by extracting a certain amount of insulating oil using a syringe from a vial filled with insulating oil. .

In addition, air is removed from the secured space, and argon gas, which is a carrier gas, is injected for a predetermined period of time (eg, for 10 minutes). However, in this method, the extraction amount varies depending on the operator who extracts the insulation oil using a syringe, and an error occurs in the extraction amount of the insulation oil. In addition, there is a problem in that it is not possible to check the amount of argon gas filled due to the colorless and odorless argon gas when the argon gas is filled after taking out the insulating oil using a syringe.

Republic of Korea Patent Registration No. 10-2003405 (published on July 24, 2019)

Therefore, the technical problem to be achieved by the present invention is to solve the disadvantages of the prior art, and the purpose is to discharge a certain amount of insulating oil regardless of the operator when discharging the insulating oil from the vial for gas-in-oil analysis of insulating oil. In addition, the purpose of this is to increase the accuracy of gas-in-oil analysis by reducing the error in the amount of argon gas filled after the insulating oil is removed from the vial.

In addition, the purpose is to prevent errors occurring in the next insulating oil extraction due to insulating oil or foreign substances remaining in the discharge needle (venting needle) after the insulating oil discharge operation for gas-in-oil analysis of insulating oil.

A semi-automatic purging system for gas-in-oil analysis according to an aspect of the present invention for achieving this technical task includes an argon gas supply unit, an argon gas injection unit, an insulating oil discharge unit, an insulating oil removal unit, and a power supply unit. In addition, the argon gas supply unit supplies or blocks the argon gas at a constant pressure to the argon gas injection unit or the vial through the control of the main valve.

In addition, the argon gas injection unit injects argon gas into the vial through a gas injection needle by adjusting the amount or time of the argon gas supplied from the argon gas supply unit according to a preset discharge insulating flow rate. The insulating oil discharge unit discharges insulating oil from the vial through a venting needle according to the amount of argon gas injected into the vial. In addition, the insulating oil removal unit removes residual insulating oil or foreign substances remaining in a venting needle after the discharging of insulating oil is completed through the insulating oil discharging unit.

Preferably, the argon gas supply unit includes a regulator that adjusts the pressure of the argon gas supplied to the argon gas injection unit or the vial to keep it constant. In addition, the argon gas injection unit includes a flow rate controller for adjusting the amount of argon gas injected into the vial.

Preferably, the insulating oil removal unit absorbs the insulating oil remaining in the venting needle using a vacuum pump after the insulating oil discharge operation, or when the venting needle is blocked by foreign substances, the vacuum pump Remove foreign substances through the pressure of

In addition, the semi-automatic purging method for gas-in-oil analysis according to another aspect of the present invention includes the steps of driving a vial mounting part to connect a vial filled with insulating oil to a gas injection needle and a venting needle, and a gas injection needle Injecting argon gas into a vial through includes

Preferably, the step of discharging the insulating oil through the discharge needle includes: a control unit controlling a regulator to constantly adjust the pressure of argon gas; and the control unit connecting a main valve to an argon gas injection unit or Supplying argon gas to the vial at a constant pressure, the control unit controlling the flow rate controller to adjust the argon gas injection amount according to the preset discharge insulating flow rate, and the control unit connecting the gas switch to control the gas injection needle and injecting argon gas into the vial through the vial while simultaneously evacuating the insulating oil from the vial through the evacuation needle.

As described above, the semi-automatic purging system and method for gas-in-oil analysis according to the present invention has the effect of discharging a certain amount of insulating oil regardless of the operator when discharging the insulating oil from the vial for gas-in-oil analysis of insulating oil. In addition, it is possible to increase the accuracy of gas-in-oil analysis by reducing the error in the amount of argon gas filled after withdrawing the insulating oil from the vial so that the headspace space is filled only with argon gas.

In addition, there is an effect of reducing the cost of argon gas for purging by injecting only an appropriate amount of argon gas filled in the headspace space. In addition, after the insulating oil discharge operation for gas-in-oil analysis of insulating oil, the insulating oil or foreign substances remaining in the discharge needle (venting needle) are removed and the error occurring in the next insulating oil extraction due to the insulating oil or foreign substances remaining in the discharge needle (venting needle) This has the effect of increasing the accuracy of gas-in-oil analysis by preventing

1 is a block diagram showing a semi-automatic purging system for gas-in-oil analysis according to an embodiment of the present invention.
Figures 2a, 2b and 2c is a configuration diagram showing a gas-in-oil analysis semi-automatic purging system according to an embodiment of the present invention.
3 is a flowchart illustrating a semi-automatic purging method for gas-in-oil analysis according to an embodiment of the present invention.
4 is a view showing in detail the step (S20) of discharging the insulating oil of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. In addition, terms such as “…unit”, “…group”, “…module”, etc. described in the specification mean a unit that processes at least one function or operation, which is implemented by hardware or software or a combination of hardware and software. can be

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings.

Like reference numerals in each figure indicate like elements.

1 is a block diagram showing a semi-automatic purging system 10 for gas-in-oil analysis according to an embodiment of the present invention, and FIGS. 2a, 2b and 2c are semi-automatic purging system 10 for gas-in-oil analysis according to an embodiment of the present invention It is a diagram showing the configuration. That is, Figure 2a is a view showing the front side of the gas-in-oil analysis semi-automatic purging system 10 of the present invention, Figure 2b is a view showing the back side of the gas-in-oil analysis semi-automatic purging system 10 of the present invention, Figure 2c is this It is a view showing that the vial 20 is mounted and operated in the argon gas injection unit 200 and the insulating oil discharge unit 300 of the present invention.

Gas-in-oil analysis semi-automatic purging system 10 according to an embodiment of the present invention is a vial 20 using argon gas in the pretreatment process carried out when using the headspace analysis method for gas-in-oil analysis of the insulating oil of the transformer. ), the insulating oil can be constantly discharged.

As shown in FIG. 1, the semi-automatic purging system 10 for gas-in-oil analysis according to an embodiment of the present invention is an argon gas supply unit 100, an argon gas injection unit 200, an insulating oil discharge unit 300, an insulating oil removal unit ( 400 ) and a power supply unit 500 . The argon gas supply unit 100 may include an argon high-pressure cylinder 110 in which argon gas is stored, a main valve 120 and a regulator 130 .

In addition, the argon gas supply unit 100 supplies or blocks argon gas at a constant pressure from the argon high-pressure cylinder 110 to the argon gas injection unit 200 or the vial 20 through the control of the main valve 120 . At this time, the regulator 130 adjusts the pressure of the argon gas supplied to the argon gas injection unit 200 or the vial 20 through the argon gas supply unit 100 to keep it constant.

The argon gas injection unit 200 injects argon gas into the vial 20 by adjusting the amount or time of the argon gas supplied from the argon gas supply unit 100 according to a preset discharge insulating flow rate. That is, the argon gas injection unit 200 injects the argon gas into the vial 20 so that a set amount of insulating oil is discharged from the vial 20 .

In addition, the argon gas injection unit 200 includes a gas switch 210 , a flow rate controller 220 , a flow rate display unit 230 , and a gas injection needle 240 . The gas switch 210 selectively supplies (On) or blocks (Off) the argon gas supplied from the argon gas supply unit 100 . The flow controller 220 is driven under the control of the user or the controller 700 to adjust the amount of argon gas injected into the vial 20 .

Also, the flow rate display unit 230 displays the amount or pressure value of the argon gas injected into the vial 20 according to the control of the flow rate controller 220 . At this time, the argon gas supplied from the argon gas supply unit 100 is injected into the vial 20 through the gas injection needle 240 . That is, the gas injection needle 240 is connected to the vial 20 filled with insulating oil driven under the control of the user or the controller 700, and the argon gas supply unit 100 through the gas injection needle 240. Argon gas supplied from

As such, the argon gas injection unit 200 constantly adjusts the amount of argon gas injected into the vial 20 and the amount of insulating oil discharged from the vial 20 through the flow rate controller 220 and the flow rate display unit 230 . can be adjusted

The insulating oil discharge unit 300 discharges the insulating oil from the vial 20 according to the amount of argon gas injected into the vial 20 . The insulating oil discharge unit 300 is driven under the control of the user or the control unit 700 to selectively discharge (On) or block the insulating oil discharged from the vial 20 through the venting needle (320). Off) and a flow path switch 310 and a venting needle 320 connected to the vial 20 for discharging the insulating oil.

That is, the venting needle 320 is connected to the vial 20 containing the insulating oil under the control of the user or the controller 700, and the vial 20 through the gas injection needle 240. The insulating oil in the vial 20 is pushed out and discharged through the venting needle 320 according to the amount of argon gas supplied to or the pressure of the argon gas.

Through this, a headspace space filled with argon gas is secured at the top of the vial 20 . In addition, since the insulating oil is discharged from the vial 20 at the same time as the argon gas is injected, the argon gas may be filled in the headspace of the vial 20 without introducing contaminated air.

The insulating oil removal unit 400 may include a vacuum pump 410 , a pump switch 420 , a primary insulating oil removal unit 430 , and a waste oil storage container 440 . In addition, the insulating oil removal unit 400 removes residual insulating oil or foreign substances remaining in the venting needle 320 after the insulating oil discharge is completed through the insulating oil discharge unit 300 .

That is, the insulating oil removal unit 400 absorbs the insulating oil remaining in the discharge needle 320 using the vacuum pump 410 after the insulating oil discharge operation, or when the discharge needle 320 is blocked by a foreign substance, the vacuum pump By removing foreign substances through the pressure of 410, the needle 320 for discharge is opened.

At this time, the pump switch 420 is driven under the control of the user or the control unit 700 to connect the vacuum pump 410 and the insulating oil primary removal unit 430, or the vacuum pump 410 and the needle 320 for discharging. Selectively connect (On) or block (Off).

In addition, the insulating oil primary removal unit 430 is provided between the vacuum pump 410 and the discharge needle 320, and the insulating oil discharged or removed from the discharge needle 320 by the pressure of the vacuum pump 410 is stored. do. That is, it blocks the insulating oil discharged from the discharge needle 320 from flowing into the vacuum pump 410 .

In addition, the waste oil storage container 440 stores the insulating oil discharged from the vial 20 through the insulating oil discharge unit 300 . That is, the discharged insulating oil discharged from the vial 20 at the same time as the injection of argon gas through the argon gas injection unit 200 is stored.

The power supply unit 500 supplies power for driving the gas-in-oil analysis semi-automatic purging system 10 . In addition, the power supply unit 500 is provided with a power switch 510 for supplying or blocking power.

In addition, the semi-automatic purging system 10 for gas-in-oil analysis according to an embodiment of the present invention may further include a vial mounting unit 600 , a control unit 700 , a storage unit 800 , and a main display unit 900 . . The vial mounting unit 600 is equipped with a vial 20 to secure a headspace from the vial 20 filled with insulating oil for gas-in-oil analysis of transformer insulating oil.

In addition, on one side of the vial mounting unit 600, the user manually drives the vial mounting unit 600 to connect the vial 20 to the gas injection needle 240 and the venting needle 320. A handle 610 for doing so is provided.

In addition, the control unit 700 includes an argon gas supply unit 100, an argon gas injection unit 200, an insulating oil discharge unit 300, an insulating oil removal unit 400, a power supply unit so that a predetermined amount of insulating oil is discharged according to a preset discharge insulating flow rate. 500 and the vial mounting unit 600 can be controlled.

In addition, the storage unit 800 may store the pressure data of the argon gas injected into the vial 20 through the argon gas supply unit 100 and the insulating flow rate data discharged from the vial 20 . That is, the storage unit 800 may store the pressure data of the argon gas injected through the argon gas injection unit 200 to correspond to the insulating flow rate discharged from the vial 20 to discharge a preset insulating flow rate.

In addition, the main display unit 900 displays the operating states of the argon gas supply unit 100 , the argon gas injection unit 200 , the insulating oil discharge unit 300 , the insulating oil removal unit 400 , and the power supply unit 500 . In addition, the main display unit 900 displays the insulating flow rate data discharged from each vial (20).

Through this, the semi-automatic purging system 10 for gas-in-oil analysis according to an embodiment of the present invention can accurately control the amount of colorless and odorless argon gas, which is difficult to check the inflow and discharge of the gas when the insulating oil is discharged from the vial 20 .

In addition, after the insulating oil discharging operation, the residual insulating oil remaining in the venting needle 320 is removed, or if the venting needle 320 is blocked by a foreign substance, the foreign material is removed and the discharge needle ( By opening the venting needle) 320, accurate extraction of insulating oil for gas-in-oil analysis performed next can be made. In addition, since the headspace space of the vial 20 is filled only with argon gas without polluted air, the accuracy of gas-in-oil analysis can be increased.

3 is a flowchart illustrating a semi-automatic purging method for gas-in-oil analysis according to an embodiment of the present invention, and FIG. 4 is a view showing in detail the step (S20) of discharging the insulating oil of FIG.

In the semi-automatic purging method for gas-in-oil analysis according to an embodiment of the present invention, the user or the control unit 700 drives the vial mounting unit 600 to insert the vial 20 filled with insulating oil with a gas injection needle 240 and a needle for discharging Step (S10) of connecting to (Venting needle) 320, the control unit 700 injects argon gas into the vial 20 through the gas injection needle 240, based on the injection amount or pressure of the argon gas A step of discharging the insulating oil through the needle 320 for discharging to (S20), and the control unit 700 driving the vacuum pump 410 to remove the insulating oil or foreign substances remaining in the needle 320 for discharging (S30) ) is included.

At this time, the step of discharging the insulating oil through the discharge needle 320 (S20) includes the control unit 700 controlling the regulator 130 to constantly adjust the pressure of the argon gas (S21), and the control unit 700 ) connects the main valve 120 to supply argon gas from the argon gas supply unit 100 to the argon gas injection unit 200 or the vial 20 at a constant pressure (S22).

In addition, the present invention includes a step (S23) of the control unit 700 controlling the flow rate controller 220 to adjust the argon gas injection amount according to the preset exhaust insulation flow rate (S23), and the control unit 700 connecting the gas switch 210 After injecting argon gas into the vial 20 through the gas injection needle 240 and simultaneously discharging the insulating oil from the vial 20 through the discharging needle 320 (S24) and after discharging the insulating oil Separating the vial 20 from the needle 240 for gas injection and the needle 320 for discharging (S25).

At this time, in the step (S23) of controlling the flow rate controller 220, the amount of argon gas flowing into the vial 20 through the flow rate controller 220 is adjusted. In addition, the insulating oil corresponding to the amount of argon gas introduced is pushed out through the needle 320 for discharging from the vial 20 at the same time through the needle 240 for gas injection and discharged.

In addition, in the step (S30) of removing the insulating oil or foreign substances, the control unit 700 controls the vacuum pump 410 to absorb the insulating oil remaining in the discharge needle 320, or the discharge needle 320 to the foreign material. When it is blocked by the vacuum pump 410, foreign substances are removed through the pressure of the vacuum pump 410.

Through this, the present invention can ensure the accuracy in the insulating oil discharge operation for gas-in-oil analysis performed next after the completion of discharging the insulating oil from the vial 20 .

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and can be easily changed by a person skilled in the art from the embodiment of the present invention to equivalent Including all changes to the extent recognized as such.

10: Gas-in-oil analysis semi-automatic purging system
20: vial 100: argon gas supply unit
110: argon high pressure cylinder 120: main valve
130: regulator 200: argon gas injection part
210: gas switch 220: flow regulator
230: flow rate display unit 240: gas injection needle
300: insulating oil discharge unit 310: Euro switch
320: Venting needle
400: insulating oil removal unit 410: vacuum pump
420: pump switch 430: insulating oil primary removal part
440: waste oil storage container 500: power supply
510: power switch 600: vial mounting part
610: handle 700: control unit
800: storage unit 900: main display unit

Claims (7)

In a gas-in-oil analysis semi-automatic purging system that secures a headspace for gas-in-oil analysis of transformer insulating oil,
an argon gas supply unit for supplying or blocking the argon gas at a constant pressure to the argon gas injection unit or the vial through the control of the main valve;
an argon gas injection unit for injecting argon gas into the vial through a gas injection needle by adjusting the amount or time of argon gas supplied from the argon gas supply unit according to a preset discharge insulating flow rate; and
Gas-in-oil analysis semi-automatic purging system comprising a; an insulating oil discharge unit that discharges insulating oil from the vial through a venting needle according to the amount of argon gas injected into the vial.
The method of claim 1,
The argon gas supply unit is an argon gas injection unit or semi-automatic purging system for gas-in-oil analysis, characterized in that it comprises a regulator for maintaining constant by adjusting the pressure of the argon gas supplied to the vial.

The method of claim 1,
The argon gas injection unit semi-automatic purging system for gas-in-oil analysis, characterized in that it comprises a flow controller for controlling the amount of argon gas injected into the vial.
The method of claim 1,
Gas-in-oil analysis semi-automatic purging system, characterized in that it further comprises an insulating oil removal unit for removing residual insulating oil or foreign substances remaining in the venting needle after the discharging of insulating oil is completed through the insulating oil discharging unit.
5. The method of claim 4,
The insulating oil removal unit absorbs the insulating oil remaining in the venting needle using a vacuum pump after the insulating oil discharge operation, or when the venting needle is blocked by a foreign substance, through the pressure of the vacuum pump Gas-in-oil analysis semi-automatic purging system, characterized in that it removes foreign substances.
In the gas-in-oil analysis semi-automatic purging method to secure a headspace for gas-in-oil analysis of transformer insulating oil,
Connecting the vial filled with insulating oil to the gas injection needle and the venting needle by driving the vial mounting unit (S10);
injecting argon gas into the vial through a gas injection needle, and discharging insulating oil through a discharge needle based on the injection amount or pressure of the argon gas (S20); and
Gas-in-oil analysis semi-automatic purging method comprising the step (S30) of driving a vacuum pump to remove insulating oil or foreign substances remaining in the discharge needle.
7. The method of claim 6,
The step of discharging the insulating oil through the discharge needle (S20)
Step (S21) of the controller to control the regulator to constantly adjust the pressure of argon gas;
supplying argon gas at a constant pressure from the argon gas supply unit to the argon gas injection unit or the vial by the control unit connecting the main valve (S22);
Step (S23) of the control unit controlling the flow rate controller to adjust the argon gas injection amount according to the preset discharge insulating flow rate (S23) and
Gas-in-oil analysis, characterized in that the control unit connects the gas switch and injects argon gas into the vial through the gas injection needle, and at the same time discharges the insulating oil from the vial through the discharge needle (S24). Semi-automatic purging method.

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