KR20210012300A - An extracting gas supply line balance maintaining system of transformer oil - Google Patents

Abstract

The present invention relates to a system for maintaining the pressure balance of a supply line of gas in insulating oil of a transformer and, more specifically, to a system for maintaining the pressure balance of a supply line of gas in insulating oil of a transformer which can always maintain a constant pressure of a gas supply flow path by providing a bypass flow path on the gas supply flow path through which gas in oil stored in an extraction gas chamber is transported to increase the accuracy for gas-in-oil analysis. To this end, the system for maintaining the pressure balance of a supply line of gas in insulating oil of a transformer comprises: an extraction device to extract gas in oil from insulating oil of a transformer; an extraction gas chamber to store gas in oil extracted from the extraction device; an analysis device to analyze the concentration of the gas in oil; a gas supply flow path which is installed between the extraction gas chamber and the analysis device, and forms a flow path to transport gas in oil stored in the extraction gas chamber to the analysis device; a pump to apply pressure to transport gas in oil of the extraction gas chamber to the analysis device along the gas supply flow path; and a bypass flow path branching from the gas supply flow path to maintain a constant pressure on the gas supply flow path when the pump operates or the pump stops.

Description

An extracting gas supply line balance maintaining system of transformer oil}

The present invention relates to a system for maintaining a pressure balance in an insulating oil-in-oil gas supply line of a transformer, and more particularly, a transformer in which the pressure in the oil-in-oil gas supply line is always kept constant, thereby increasing the accuracy of analysis of oil-in-oil gas through an analysis device. It relates to an insulating oil-in-oil gas supply line pressure balance maintenance system.

The inflow transformer is one of the main facilities of the power supply system and high reliability is required. Such inflow transformers may cause abnormalities due to deterioration in electrical and mechanical performance due to deterioration during operation. If this phenomenon is not detected in advance and appropriate measures are taken, serious accidents may occur.

If abnormal phenomena such as insulation breakdown or local overheating occur inside the inlet transformer, heat must be generated. Insulation materials such as insulating oil, insulating paper, and press board that have contacted the heat generating source are decomposed by chemical reactions due to the heat effect. Occur. Most of these gases are soluble in insulating oil. Therefore, if the insulating oil of the inlet transformer is extracted and the gas is extracted and analyzed, the type and degree of defects occurring inside can be diagnosed.

The transformer manager sets the standard for concentration management of these dissolved gases, that is, oil-in-oil gas, and monitors them periodically or continuously to detect them in the early stages of an abnormality and take appropriate measures to prevent the progress of unexpected accidents such as transformer explosions. Loss can be prevented.

In order to measure the type and concentration of the gas dissolved in the insulating oil, an extraction device that extracts the gas dissolved in the insulating oil into a gaseous state is required, and the method for extracting the dissolved gas of the insulating oil is a membrane method, There is an extraction device using an air bubbling method and a head space method.

Among them, the diaphragm method or the bubble degassing method has a low extraction rate, a complicated structure, a long extraction time, and a disadvantage that the insulating oil is saturated with air after extraction, so it is not suitable as a method applied to a continuous monitoring device in the field. There is this. The headspace type extraction device is a method that compensates for the above-described disadvantages, and has a simple structure and convenient operation, and thus has been widely used in recent years.

Hereinafter, a process for measuring the type and concentration of gas dissolved in insulating oil using the extraction device described above will be briefly described with reference to FIG. 1.

When a certain amount of insulating oil is stored in the extraction device 10, the operator heats the extraction device 10 by operating a heater (not shown). At this time, the operator can increase the gas extraction efficiency by rotating the stirring blade (not shown). Thereafter, when a sufficient amount of oil-in gas is extracted from the insulating oil, the operator opens the gas transfer pipe 20 to transfer the oil-in gas to the extraction gas chamber 30.

Thereafter, the oil-in gas introduced into the extraction gas chamber 30 is transferred to the analysis device 60 along the gas supply flow path 50 through the pumping action of the pump 40, and Type, concentration, etc. are analyzed. The analysis device 60 may be provided with a gas sensor, a gas chromatograph, a photoacoustic device (PAS), or the like.

When the oil-in-gas analysis is completed through the analysis device 60, the manager diagnoses the presence or absence of an abnormality in the transformer, and takes follow-up measures suitable for the diagnosis. When the transformer abnormality diagnosis is completed as described above, the inlet pipe (not shown) is opened to recover the insulating oil inside the extraction device 10 to the transformer.

Meanwhile, in order to analyze the gas-in-oil as described above, the pressure in the pipeline must be kept constant before measuring the gas concentration through the analysis device 60 for the extracted gas-in-oil. However, even when the gas supply to the analysis device 60 is completed and the operation of the pump 40 is stopped, as a pressure difference is generated at the front and rear ends of the pump 40, the analysis device 60 and the gas supply pipe 50 There is a problem that the pressure changes.

Accordingly, there is a problem in that it is difficult to increase the reliability of the measured value because the pressure in the analysis device 60 is irregularly changed and a large deviation occurs in the concentration measurement when analyzing the extracted gas-in-oil.

Korean Patent Registration No. 10-1290295

The present invention was conceived to solve the above problems, and an object of the present invention is to form a bypass flow path branched from the gas supply flow path to the extraction gas chamber on the gas supply flow path formed between the extraction gas chamber and the analysis device, It is intended to provide a system for maintaining the pressure balance of the insulating oil-in-oil gas supply line of the transformer so that the pressure can be maintained evenly in the gas supply flow path regardless of the operation of the transformer. will be.

The present invention, in order to achieve the above object, the extraction device for extracting the oil-borne gas from the insulating oil of the transformer; An extraction gas chamber in which the oil-in-oil gas extracted from the extraction device is stored; An analysis device for analyzing the concentration of the gas in oil; A gas supply flow path installed between the extraction gas chamber and the analysis device and forming a flow path so that the petroleum gas stored in the extraction gas chamber can be transferred to the analysis device; A pump that applies pressure so that the oil-in-oil gas of the extraction gas chamber is transferred to the analysis device along the gas supply flow path; And an insulating oil-in-oil gas supply line pressure balance maintenance system of a transformer including a bypass flow path branched from the gas supply flow path so that the pressure on the gas supply flow path can be kept constant when the pump is operated or the pump is stopped. .

In this case, the bypass flow path is preferably connected to the extraction gas chamber.

In addition, it is preferable that the gas supply flow path and the bypass flow path are connected to a branch member branched in three directions.

In the system for maintaining the pressure balance of the insulating oil-in-oil gas supply line of the transformer according to the present invention, a bypass flow path is formed on the gas supply flow path between the pump and the analysis device, so that a constant pressure is always maintained on the gas supply line, so that the gas supply is made stably. In addition, there is an effect of increasing the reliability of the measurement value of the gas concentration through the analysis device.

That is, since the bypass flow path forms a flow path between the gas supply flow path and the extracted gas chamber, it is possible to maintain a uniform pressure in the gas supply flow path while suppressing the occurrence of pressure change in the gas supply flow path due to pump action or pump stop. I made it possible

Accordingly, as the pressure in the gas supply channel is always stably maintained, the pressure of the analysis device can be kept constant, so the system for maintaining the pressure balance of the insulating oil-in-oil gas supply line of the transformer is the reliability of the measurement value of the gas concentration through the analysis device. You can increase it.

1 is a view schematically showing an insulating oil-in-oil gas supply line according to the prior art.
FIG. 2 is a diagram schematically showing an oil-in-oil gas supply line for maintaining a pressure balance in an insulating oil-in-oil gas supply line of a transformer according to a preferred embodiment of the present invention.
3 is a view schematically showing an extraction device of a system for maintaining a pressure balance in an insulating oil-in-oil gas supply line of a transformer according to a preferred embodiment of the present invention.
4 is a graph showing the comparison of analysis values before and after the bypass flow path of the insulating oil-in-oil gas supply line pressure balance maintenance system of a transformer according to a preferred embodiment of the present invention is installed.

Terms and words used in the present specification and claims are not limited to the usual or dictionary meanings, and the inventor is based on the principle that the concept of terms can be appropriately defined in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a system for maintaining a pressure balance in an insulating oil-in-oil gas supply line of a transformer according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 4.

The insulating oil-in-oil gas supply line pressure balance maintenance system of the transformer provides a bypass flow path in the gas supply flow path connected between the extraction gas chamber in which the oil-in-oil gas is stored and the analysis device so that the pressure of the gas supply flow path can always be kept constant.

The insulating oil-in-oil gas supply line pressure balance maintenance system of the transformer, as shown in FIG. 2, includes an extraction device 100, an extraction gas chamber 200, an analysis device 300, a gas supply flow path 400, and It includes a pump 500 and a bypass flow path 600.

The extraction device 100 uses a decompression device (not shown) to decompress or vacuum the inside to maximize the dissolved gas dissolved in the insulating oil, that is, the gas-in-oil extraction rate. According to Henry's law, the solubility of the gas in the liquid increases as the pressure of the gas increases, so the higher the pressure, the more gas molecules are dissolved in the same volume. In order to easily separate the gas, the gas extraction rate can be increased by lowering the pressure inversely to lower the solubility. In a preferred embodiment of the present invention, by applying Henry's law to increase the extraction rate of the dissolved gas by lowering the air pressure in the extraction device 100 containing the insulating oil in which the gas-in-oil is dissolved, a sufficient amount of gas-in-oil extraction can be secured.

The extraction device 100 includes a barrier 110, a water level sensor 120, and a stirrer 130, as shown in FIG. 3.

When the insulating oil is stirred by the stirrer 130, the barrier 110 serves to prevent the water level at the edge of the insulating oil from excessively rising due to the centrifugal force and flowing out to various pipes installed in the extraction device 100. The barrier 110 is formed to protrude toward the extraction space from the inner surface of the extraction device 100 as shown in FIG. 3. Due to the configuration of the barrier 110, even when the agitator 130 rotates at high speed, the insulating oil does not overflow beyond a specific water level.

The water level sensor 120 controls an excessive rise in the water level of the insulating oil, detects the amount of insulating oil inflow from the transformer to the extraction device 100, and detects the rise in the insulating oil level due to high-speed rotation of the stirrer 130, and a control unit (not shown) Allows to control the rotation speed of the stirrer 130.

The stirrer 130 serves to more actively extract oil-in-oil gas from the insulating oil. The stirrer 130 may be composed of a rotating blade 131 and a magnetic force part 132. The rotation blade 131 is made of a metal to which magnetic force acts, and a separate rotation shaft is omitted. The movement of the rotary blade 131 is controlled by the magnetic force unit 132, and the rotary blade 131 is located inside the extraction device 100. The magnetic portion 132 is installed to be rotated, and may be provided as a permanent magnet or an electromagnet. The magnetic force unit 132 is installed outside the extraction device 100, and provides magnetic force to the rotary blade 131, so that the rotary blade 131 may be interlocked according to the rotation of the magnetic force unit 132. In detail, the magnetic portion 132 is preferably provided as an electromagnet, and is preferably installed under the extraction device 100 as shown in FIG. 3.

With this configuration, the rotating blade 131 is interlocked by the magnetic force of the electromagnet 132, and since the rotating blade 131 can be rotated by the electromagnet 132, the rotating blade 131 is an extraction device ( 100) It can exert rotational power inside. Since the configuration of the rotating shaft can be omitted, the configuration for maintaining airtightness according to the installation of the rotating shaft can be omitted and the configuration can be simplified.

The extraction gas chamber 200 is a configuration in which the oil-in-oil gas extracted from the extraction device 100 is stored before being transferred to the analysis device 300. A gas transfer pipe 140 is installed between the extraction gas chamber 200 and the extraction device 100. It is preferable that a filter (not shown) is installed in the gas transfer pipe 140 to filter oil vapor contained in the oil-in-oil gas.

The analysis device 300 serves to analyze the type and concentration of gas in oil. As the analysis device 300, a gas sensor, a gas chromatograph, a photoacoustic device (PAS), or the like may be provided. When the oil-in-gas analysis is completed through the analysis device 300, the manager diagnoses the presence or absence of an abnormality in the transformer and can take follow-up measures appropriate for the diagnosis.

The gas supply flow path 400 provides a flow path through which the oil-in-oil gas of the extracted gas chamber 200 is transferred to the analysis device 300, and is installed between the extracted gas chamber 200 and the analysis device 300. The diameter of the gas supply passage 400 is not limited.

The pump 500 serves to pump the oil-in-oil gas in the extraction gas chamber 100 and transfer the oil-in-oil gas to the analysis device 300 along the gas supply flow path 400.

The bypass flow path 600 serves to maintain a constant pressure in the gas supply flow path 400 and the analysis device 300 at all times. As the pressure in the gas supply passage 400 through which the oil-in-oil gas is transported is always kept constant, the pressure in the analysis device 300 is also kept constant, and thus the analysis device 300 can increase the accuracy of the oil-in gas analysis. . The bypass flow path 600 is installed between the gas supply flow path 400 and the extraction gas chamber 200 and prevents overpressure from occurring in the gas supply flow path 400 so that the pressure in the gas supply flow path 400 is always It can be kept constant. The bypass flow path 600 is branched from the gas supply flow path 400, and the inner diameter of the bypass flow path 600 is also not limited.

A branch member 700 may be installed between the bypass flow path 600 and the gas supply flow path 400. That is, it is possible to connect the gas supply flow path 400 and the bypass flow path 600 through the branch bonsai 700. The branch member 700 is preferably provided as a three-way valve forming a pipe in three directions.

As described above, by configuring the bypass flow path 600 to bypass the extraction gas chamber 200 in the gas supply flow path 400, the pressure in the gas supply flow path 400 can always be kept constant. Accordingly, it is possible to increase the accuracy of the analysis of oil-in-oil gas through the analysis device 600, which can be understood through the graph shown in FIG. 4.

4 is a result of a comparison test according to the presence or absence of the bypass flow path 600 when gas analysis is performed by applying the same temperature and the same analysis sequence to the insulating oil sample contained in the gas-in-oil.

The blue graph is the result of measuring the reference value of the gas in the air, and the orange graph is the measurement result of the insulating oil sample containing the gas in oil, and the measured value of the insulating oil sample before installation of the bypass flow path 600 is lower than the reference value measured in the air. Although an error occurred, it can be confirmed from the experimental results that the accuracy of the gas-in-oil analysis is improved as the measured value of the insulating oil sample is kept constant in a state measured higher than the reference value in the air after the bypass flow path 600 is installed. .

Therefore, the system for maintaining the pressure balance of the insulating oil-in-oil gas supply line of the transformer according to the present invention enables accurate and repetitive gas analysis and measurement compared to the conventional technology through the configuration of the bypass flow path, and as a result, increases the hit rate of transformer abnormality diagnosis to prevent accidental accidents. Can expect a great effect on

In the above, the present invention has been described in detail with respect to the described embodiments, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications fall within the scope of the appended claims.

100: extraction device 110: barrier
120: water level sensor 130: stirrer
131: rotating member 132: magnetic portion (electromagnet)
140: gas transfer pipe 200: extracted gas chamber
300: analysis device 400: gas supply flow path
500: pump 600: bypass flow path
700: branch member (three-way valve)

Claims (3)

An extraction device for extracting oil-in-oil gas from the insulating oil of the transformer;
An extraction gas chamber in which the oil-in-oil gas extracted from the extraction device is stored;
An analysis device for analyzing the concentration of the gas in oil;
A gas supply flow path installed between the extraction gas chamber and the analysis device and forming a flow path so that the oil-in-oil gas stored in the extraction gas chamber can be transferred to the analysis device;
A pump that applies pressure so that the oil-in-oil gas of the extraction gas chamber is transferred to the analysis device along the gas supply flow path; And
Insulating oil-in-oil gas supply line pressure balance maintenance system of a transformer including a bypass flow path branched from the gas supply flow path so that the pressure on the gas supply flow path can be kept constant when the pump is operated or the pump is stopped. The method of claim 1,
The bypass flow path is an insulating oil-in-oil gas supply line pressure balance maintenance system of a transformer, characterized in that connected to the extraction gas chamber. The method according to claim 1 or 2,
The gas supply flow path and the bypass flow path are connected to a branch member branched in three directions.

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