KR0161833B1 - Compressed air supply device for phase separation busbar in power plants - Google Patents

Abstract

The present invention relates to an apparatus for supplying compressed air into a phase separation bus to prevent dust or moisture from occurring in the insulation inside an isolated phase bus (IPB) of a power plant and to maintain insulation performance. The furnace is designed to detect and automatically control the air pressure inside the phase separation bus to maintain a constant pressure.

To this end, the present invention in order to install the first, second pressure reducer 12, 13 to sequentially decompress the air drawn from the outside through the inlet pipe 11 to the panel 10, the second pressure reducer (13) To the inside of the outer shell (1) of the phase separation busbar and the pipeline (9), the bypass pipe (14) between the inlet pipe (11) and the pipeline (9) and the phase separation busbar on the other side of the panel (10) The pressure switch (15) and (16) for detecting the pressure inside is connected to the shell (1) by the connecting pipe (17).

Description

Compressed air supply device for phase separation bus in power plant

1 is a front view showing a conventional device.

2 is a layout view of the present invention.

3 is a side view of FIG.

4 is a pipeline connection diagram showing an embodiment of the present invention.

5 is a panel configuration diagram of a compressed air supply device applied to the present invention.

6 is a side view of FIG.

Figure 7 is a pipeline connection diagram showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: jacket 9: pipeline

10 panel 11: inlet pipe

12, 13: 1st, 2nd pressure reducer 14: bypass pipe

15, 16: pressure switch 17: connector

18: Merometa 19: Tube

The present invention relates to an apparatus for supplying compressed air into a phase separation bus to prevent dust or moisture from occurring in the insulation inside an isolated phase bus (IPB) of a power plant and to maintain insulation performance. The furnace is designed to detect and automatically control the air pressure inside the phase separation bus to maintain a constant pressure.

In general, the phase-separated bus is a large-capacity three-phase separated conductor that transmits the current generated from the turbine generator of the power plant to the peripheral pressure, and its configuration is composed of the outer shell 1 and the conductor 2 as shown in FIG. Because of the large capacity, when moisture is generated inside the outer shell (1) and condensation occurs, insulation breakdown and arc occur, causing great damage to the generator and ambient pressure. Must be provided.

Conventionally, the shell 1 is passed through the hole 3a formed in the building wall 3 to prevent moisture from condensing inside the shell due to the temperature difference between the inner shell of the phase separation bus and the ambient air. The shielding plate 4 and the bushing 5 divide the seal and the inside and outside to prevent air from flowing.

In addition, the dew sensor (6) is installed on the surface of the shell (1) to detect the dew point (Dew Point) inside the outer shell 1 due to the temperature difference when the moisture begins to condense inside the shell (1) the dew sensor detects this By operating the heater (not shown) and the breath (Breather) (7), the foreign air, such as dust is filtered in the filter (not shown) installed in the breath (7) is introduced into the outside air is heated in the heater It is intended to be blown into the inside of the shell 1.

The external air heated as described above removes moisture condensed in the outer shell 1, and when the moisture in the outer shell is completely removed, the dew sensor 6 detects this to stop the operation of the heater and the breathing tube 7.

At this time, the controller 8 fixed to the building wall 3 is connected to the dew sensor 6 to manage the system.

However, this conventional apparatus has the following problems.

First, it is necessary to keep the outside air blown into the inside of the shell clean at all times, so it is necessary to periodically check and replace the filter mounted in the tank.

Second, the breathing tank and the motor for operating the breathing should be kept in a state that can always be operated, as well as a lot of energy is consumed in their operation, and a spare breathing box should be installed in case of emergency.

Third, the filter built into the breathing tank only filters foreign substances such as dust contained in the air, and if the corrosion component of the conductor or hydrogen, which is an explosive component, is leaked from the generator, it cannot be filtered. There is concern.

Fourth, since there are many places where heaters and breathers are installed, there is a fear that inflow of polluted air and condensation may occur if they are not operated even in one place.

Fifth, the drain plug installed at the bottom of the shell should be opened regularly to remove any water that may have accumulated in the shell.

The present invention has been made to solve such a problem in the prior art, by using the air supplied from the power plant to blow the compressed air higher than atmospheric pressure inside the shell to prevent the moisture of the shell condensation.

According to the aspect of the present invention for achieving the above object, through the inlet pipe of the panel to install the first and second pressure reducers to reduce the air drawn from the outside in order to the second reducer to the inner shell and the pipeline of the phase separation bus Connect the bypass pipe between the inlet pipe and the pipeline. On the other side of the panel, the compressed air supply device for the phase separation bus in the power plant is installed by connecting a pressure switch that senses the pressure in the phase separation bus to the outer shell with a connecting pipe. Is provided.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 2 through 6 of the accompanying drawings.

2 and 3 are layout views of the present invention, FIG. 4 is a pipeline connection diagram showing an embodiment of the present invention, and FIG. 5 is a panel configuration diagram of a compressed air supply device applied to the present invention. Three shells 1 pass through the holes 3a formed in the building wall 3 and are shielded by the shielding plate 4, and the lower portion of the shell wall 3 passes through the inside of the shell 1. The panel 10 in which the pipeline 9 is installed is fixed.

The panel 10 is fixed to the first and second pressure reducers 12 and 13 which sequentially supply pressure to the skin by depressurizing the air drawn from the outside (power plant) to the required pressure through the inlet pipe 11 and the second The pressure reducer 13 is connected to the pipeline 9 passing through the inside of the shell 1 of the phase separation busbar.

In addition, the bypass pipe 14 is connected between the inlet pipe 11 and the pipeline 9, and the other side of the panel 10 senses the pressure in the phase separation bus, so that the pressure of the compressed air is low or high. Pressure switch (15) and (16) for detecting and using a separate alarm means to generate an alarm is connected to the outer shell (1) by the connecting pipe 17, the pressure of the air supplied into the outer shell on the front of the panel (10) A manometer 18 for measuring the pressure is provided.

The pressure of the air supplied into the shell is set to 5 to 15 mbar. When the air pressure is less than 5 mbar, external air enters through the shell (1) and condenses moisture in the shell. Ancillary equipment such as an airtight device is required, so an air pressure of 5 to 15 mbar is appropriate.

As shown in FIG. 4 showing the configuration of connecting the pipeline 9 to the inside of the shell 1, the three shells 1 are connected to each other through the pipe 19 as shown in FIG. Next, the inlet pipe line 9a is connected to one of the outer shells, and the outlet pipe line 9b is connected to the outer skin of the other side. However, the present invention is not necessarily limited thereto, as shown in FIG. The inlet pipe line 9a and the outlet pipe line 9b may be connected to the three shells 1, respectively.

Referring to the operation and effects of the present invention configured as described above are as follows.

First, the air supplied from the power plant is the instrument air, which is the cleanest air, and the supply pressure is more than 7 bar although it varies from plant to plant.

As described above, when the air supplied from the power plant is supplied to the inlet pipe 11 fixed to the panel 10, the supplied air is decompressed to 2 bar while passing through the first decompressor 12 fixed to the panel 10. Subsequently, the pressure was reduced to 5 to 15 mbar while passing through the second pressure reducer 13 and then supplied to the inside of the shell 1, which is a phase separation busbar, through the inlet pipe line 9a.

In this way, the pressure of air supplied to the shell 1 by being decompressed to 5 to 15 mbar is often checked by the worker through the manometer 18 installed on the front surface of the panel 10.

As described above, when the outside air is decompressed to 5 to 15 mbar by the first and second decompressors 12 and 13 and supplied to the inside of the shell 1, the air pressure in the shell is higher than the outside of the shell. No moisture is condensed inside the shell.

In the above operation, if the pressure inside the outer shell 1, which is a phase separation busbar, is excessively increased to exceed the dangerous pressure of 35 mbar, the high pressure switch 15 connected to the outer shell 1 and the connecting pipe 17 detects this. Since the alarm is generated through the alarm means connected to the panel 10, the worker will quickly replace it.

On the contrary, when the pressure of the supplied air leaks from the shell 1 and the pressure in the shell 1 falls below the set value, the low pressure switch 16 detects this and generates an alarm through the alarm means as described above. do.

As described above, the present invention has the following advantages.

First, air containing moisture or mixed with foreign substances such as dust is prevented from entering the inside of the shell.

Second, since the parts of the prior art, such as bushings, heaters, breathers, etc. are not required, installation and maintenance are simplified.

Third, even when hydrogen is leaked from the generator, the leaked hydrogen is prevented from being introduced into the shell in advance, thereby preventing an explosion accident due to the leakage of hydrogen.

Fourth, since the moisture is not condensed at the lower end of the outer shell it is not necessary to remove the moisture periodically.

Claims (4)

The first and second decompressors 12 and 13 which depressurize the instrument air supplied from the power plant through the inlet pipe 11 to the panel 10 are sequentially replaced with the shell of the phase-separated busbar. 1) Connect the inside and the pipeline (9) and connect the bypass pipe (14) between the inlet pipe (11) and the pipeline (9), the pressure to sense the pressure in the phase separation bus to the other side of the panel (10) Compressed air supply device for a phase separation bus in a power plant by installing the switch (15) and (16) to be connected to the shell (1) by a connecting pipe (17). 2. The compressed air supply device for a phase separation bus in a power plant according to claim 1, wherein a manometer (18) for measuring the pressure of air supplied into the shell (1) is provided on the front surface of the panel (10). The compressed air supply device for a phase separation bus in a power plant according to claim 1, wherein the three shells (1) are connected to each other by pipes (19). 2. The compressed air supply device for a phase separation bus in a power plant according to claim 1, wherein the inlet pipe line (9a) and the outlet pipe line (9b) are respectively connected to three outer shells (1).