KR102365773B1 - Apparatus for testing heater capacity of air cleaning unit in nuclear power plant and method for testing heater capacity of air cleaning unit in nuclear power plant - Google Patents

Abstract

A heater capacity testing apparatus of an air cleaning unit of a nuclear power plant includes a first temperature sensor unit located in front of a heater, a second temperature sensor unit located at a rear side of the heater, and directly between a heater bank and a fan bank including the heater It includes a bypass duct for connecting, and a small fan connected to the bypass duct.

Description

BACKGROUND OF THE INVENTION Field of the Invention PLANT}

The present disclosure relates to a heater capacity testing apparatus of an air cleaning unit of a nuclear power plant and a heater capacity testing method of an air cleaning unit of a nuclear power plant.

In general, in order to maintain safety-related functions such as habitability of the main control room of a nuclear power plant, an air cleaning unit that filters radioactive materials of air flowing in from the outside of the main control room is connected to the main control room.

The air cleaning unit includes a heater for maintaining the relative humidity inside the air cleaning unit at approximately 70% to maintain the efficiency of the activated carbon filter.

Conventionally, the heater capacity test of the air cleaning unit is performed every set period (eg, 18 months).

However, in order to test the heater capacity of the air cleaning unit, the entire air cleaning unit must be driven. At this time, filters including a HEPA filter and an activated carbon filter included in the air cleaning unit are used, so that the replacement cycle of the filters is shortened. There is a problem in that the maintenance cost of the unit increases.

An embodiment provides a heater capacity testing apparatus for an air cleaning unit of a nuclear power plant that reduces maintenance costs of the air cleaning unit by testing the heater capacity of the air cleaning unit without using filters included in the air cleaning unit of the nuclear power plant, and An object of the present invention is to provide a method for testing the heater capacity of an air cleaning unit in a nuclear power plant.

One side is a heater bank including a heater for heating the air introduced from the outside, a plurality of filter banks connected to the rear of the heater bank to filter the air, and the plurality of filter banks connected to the rear of the air In the heater capacity testing apparatus of the air cleaning unit of a nuclear power plant for testing the capacity of the heater of the air cleaning unit including a fan bank for supplying , a second temperature sensor located at the rear of the heater, a bypass duct directly connecting between the heater bank and the fan bank, and a small fan connected to the bypass duct. Air cleaning unit of a nuclear power plant of heater capacity testing equipment.

A control unit connected to the first temperature sensor unit and the second temperature sensor unit and further comprising a control unit configured to check whether a temperature difference between the air sensed by each of the first temperature sensor unit and the second temperature sensor unit satisfies a set value can do.

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It may further include a small activated carbon filter unit mounted inside the bypass duct unit.

The plurality of filter banks are connected to the rear side of the heater bank and include a pre-filter bank including a pre-filter, a first HEPA filter bank connected to the rear side of the pre-filter bank and including a first HEPA filter, the first and an activated carbon filter bank connected to a rear side of the HEPA filter bank, the activated carbon filter bank including an activated carbon filter, and a second HEPA filter bank connected to the rear side of the activated carbon filter bank and including a second HEPA filter, wherein the fan bank includes the second It may be connected to the rear side of the HEPA filter bank.

In addition, one side is connected to a heater bank including a heater for heating the air flowing in from the outside, a plurality of filter banks connected to the rear of the heater bank to filter the air, and the rear of the plurality of filter banks, In the heater capacity testing method of an air cleaning unit of a nuclear power plant for testing the capacity of the heater of an air cleaning unit including a fan bank for supplying the air to the main control room of the nuclear power plant, Directly connecting to the pass duct, driving a small fan connected to the bypass duct, and a first temperature sensor located in front of the heater and a second temperature sensor located in the rear of the heater, respectively It provides a method for testing the capacity of a heater of an air cleaning unit of a nuclear power plant, comprising the step of verifying whether a temperature difference of sensed air satisfies a set value.

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According to an embodiment, the heater capacity testing apparatus of an air cleaning unit of a nuclear power plant reduces the maintenance cost of the air cleaning unit by testing the heater capacity of the air cleaning unit without using filters included in the air cleaning unit of the nuclear power plant and a heater capacity test method of an air cleaning unit of a nuclear power plant.

1 is a view showing a heater capacity testing apparatus of an air cleaning unit of a nuclear power plant according to an embodiment installed in the air cleaning unit of a nuclear power plant.
2 is a flowchart illustrating a method for testing a heater capacity of an air cleaning unit of a nuclear power plant according to another embodiment.

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. The present invention may be embodied in several different forms and is not limited to the embodiments described herein.

In addition, throughout the specification, when a part "includes" a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

Hereinafter, a heater capacity testing apparatus of an air cleaning unit of a nuclear power plant according to an embodiment will be described with reference to FIG. 1 .

1 is a view showing a heater capacity testing apparatus of an air cleaning unit of a nuclear power plant according to an embodiment installed in the air cleaning unit of a nuclear power plant.

Referring to FIG. 1 , an apparatus 1000 for testing a heater capacity of an air cleaning unit of a nuclear power plant according to an embodiment is installed in an air cleaning unit 90 and includes a capacity of a heater 21 included in the air cleaning unit 90 . test

The air cleaning unit 90 is connected to the main control room of the nuclear power plant, and filters radioactive materials of air flowing in from the outside of the main control room in order to maintain safety-related functions such as habitability of the main control room and supplies it to the main control room. The air cleaning unit 90 may be operated when an accident occurs in a nuclear power plant, but is not limited thereto.

The air cleaning unit 90 includes a moisture separator bank 10 including a moisture separator 11 , a heater bank 20 including a heater 21 , a prefilter bank 30 including a prefilter 31 , A first HEPA filter bank 40 including a first HEPA filter 41, an activated carbon filter bank 50 including an activated carbon filter 51, and a second HEPA filter bank including a second HEPA filter 61 ( 60 ), and a fan bank 70 including a fan 71 . The pre-filter bank 30 , the first HEPA filter bank 40 , the activated carbon filter bank 50 , and the second HEPA filter bank 60 may constitute a plurality of filter banks, but is not limited thereto. A plurality of filter banks are connected to the rear side of the heater bank 20 to filter the air.

Here, the bank (bank) may mean a compartment, but is not limited thereto.

The moisture separator bank 10 is connected to the front side of the heater bank 20 and includes a moisture separator 11 that separates moisture from the air introduced from the outside.

The heater bank 20 connects between the moisture separator bank 10 and the pre-filter bank 30 and includes a heater 21 that heats the air that has passed through the moisture separator bank 10 from the outside.

The pre-filter bank 30 is connected to the rear side of the heater bank 20 and includes a pre-filter 31 for filtering dust, etc. included in the air that has passed through the heater bank 20 .

The first HEPA filter bank 40 is connected to the rear side of the pre-filter bank 30 , and includes a first HEPA filter 41 that filters radioactive particles of air that has passed through the pre-filter bank 30 .

The activated carbon filter bank 50 is connected to the rear side of the first HEPA filter bank 40 and includes an activated carbon filter 51 that absorbs and filters radioactive ultrafine particles of air that has passed through the first HEPA filter bank 40 .

The second HEPA filter bank 60 is connected to the rear side of the activated carbon filter bank 50 , and includes a second HEPA filter 61 that filters radioactive particles of the air that has passed through the activated carbon filter bank 50 again.

The fan bank 70 is connected to the rear side of the second HEPA filter bank 60, and external air is transferred from the moisture separator bank 10 to the heater bank 20, the pre-filter bank 30, and the first HEPA filter bank ( 40), the activated carbon filter bank 50, and a fan 71 for supplying air by moving the activated carbon filter bank 50 and the second HEPA filter bank 60 to the main control room.

The heater capacity testing apparatus 1000 of an air cleaning unit of a nuclear power plant according to an embodiment for testing the capacity of the heater 21 of the air cleaning unit 90 described above is selectively attached to and detached from the air cleaning unit 90 . and a first temperature sensor unit 100 , a second temperature sensor unit 200 , a control unit 300 , a bypass duct unit 400 , a small fan unit 500 , and a small activated carbon filter unit 600 .

The first temperature sensor unit 100 is positioned in front of the heater 21 to sense the temperature of the air to pass through the heater 21 . The first temperature sensor unit 100 may be located in the moisture separator bank 10 , but is not limited thereto.

The second temperature sensor unit 200 is positioned at the rear side of the heater 21 to sense the temperature of the air that has passed through the heater 21 . The second temperature sensor unit 200 may be located in the heater bank 20 , but is not limited thereto.

The control unit 300 is connected to the first temperature sensor unit 100 and the second temperature sensor unit 200, and the temperature of the air sensed by the first temperature sensor unit 100 and the second temperature sensor unit 200, respectively. Check whether the difference satisfies the set value.

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The bypass duct part 400 bypasses and directly connects between the heater bank 20 and the fan bank 70 . The bypass duct unit 400 is flexible and may include various flexible materials if it can directly connect the heater bank 20 and the fan bank 70 . The bypass duct unit 400 may connect between the heater bank 20 and the fan bank 70 through the respective entrances and exits of the heater bank 20 and the fan bank 70 through which the worker enters and exits.

The small fan unit 500 is connected to the bypass duct unit 400, and the air that has passed through the heater 21 of the heater bank 20 passes from the heater bank 20 through the bypass duct unit 400 to the fan bank ( 70) is moved.

The small activated carbon filter unit 600 is mounted inside the bypass duct unit 400 to adsorb and filter radioactive ultrafine particles of air passing through the bypass duct unit 400 from the heater bank 20 . The small activated carbon filter unit 600 has a smaller area than the activated carbon filter 51 included in the activated carbon filter bank 50 .

In addition, the heater capacity testing apparatus 1000 of the air cleaning unit of a nuclear power plant may further include a blocking plate for blocking between the heater bank 20 and the pre-filter bank 30 . By the blocking plate blocking between the heater bank 20 and the pre-filter bank 30 , the air through the heater 21 of the heater bank 20 is blocked from moving to the pre-filter bank 30 .

As such, the heater capacity testing apparatus 1000 of the air cleaning unit of a nuclear power plant according to an embodiment includes a bypass duct part 400 that bypasses and directly connects between the heater bank 20 and the fan bank 70 . By doing so, the air passing through the heater 21 of the heater bank 20 from the outside is transferred to the pre-filter bank 30, the first HEPA filter bank 40, the activated carbon filter bank 50, and the second HEPA filter bank 60. By testing the capacity of the heater 21 by bypassing it to the fan bank 70 through the bypass duct 400 without passing through, the pre-filter 31 and the first HEPA filter included in the air cleaning unit 90 are (41), since it is possible to maintain the replacement cycle of the filters by testing the capacity of the heater 21 of the air cleaning unit 90 without using filters including the activated carbon filter 51 and the second HEPA filter 61, The maintenance cost of the air cleaning unit 90 is reduced.

That is, by testing the capacity of the heater 21 of the air cleaning unit 90 without using filters included in the air cleaning unit 90 of the nuclear power plant, the maintenance cost of the air cleaning unit 90 is reduced. A heater capacity testing apparatus 1000 of an air cleaning unit is provided.

In addition, the heater capacity testing apparatus 1000 of an air cleaning unit of a nuclear power plant according to an embodiment includes a first temperature sensor unit 100 and a second temperature sensor unit 200 positioned on the front and rear sides of the heater 21 , respectively. ), since the capacity of the heater 21 is tested using the temperature difference of the air sensed by each of the first temperature sensor unit 100 and the second temperature sensor unit 200, filter banks and fan banks ( 70), it is possible to test the capacity of the heater 21 more accurately than to test the capacity of the heater 21 by locating the temperature sensor.

In addition, in the heater capacity testing apparatus 1000 of the air cleaning unit of a nuclear power plant according to an embodiment, a temperature difference of air sensed by each of the first temperature sensor unit 100 and the second temperature sensor unit 200 is set. By including the control unit 300 and the small fan unit 500 to check whether the conditions are satisfied, the capacity of the heater 21 can be tested by sensing only the temperature difference between the front and rear sides of the heater 21, respectively.

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In addition, in the heater capacity testing apparatus 1000 of the air cleaning unit of a nuclear power plant according to an embodiment, the bypass duct part 400 that bypasses and directly connects between the heater bank 20 and the fan bank 70 is flexible. , since the bypass duct 400 can be easily and directly connected between the heater bank 20 and the fan bank 70 of the air cleaning unit 90 having various structures, various structures can be provided depending on the type of nuclear power plant. The eggplant can easily test the capacity of the heater 21 of the air cleaning unit 90 .

Hereinafter, a method for testing the heater capacity of an air cleaning unit of a nuclear power plant according to another exemplary embodiment will be described with reference to FIGS. 1 and 2 .

The method for testing the heater capacity of an air cleaning unit of a nuclear power plant according to another embodiment may be performed using the apparatus for testing a heater capacity of an air cleaning unit of a nuclear power plant according to the above-described embodiment, but is not limited thereto.

Referring to FIG. 1 , in the method for testing the heater capacity of an air cleaning unit of a nuclear power plant according to another embodiment, first, a bypass duct 400 is directly connected between the heater bank 20 and the fan bank 70 . At this time, it is possible to block between the heater bank 20 and the pre-filter bank 30 with a blocking plate.

Next, the air passing through the heater 21 of the heater bank 20 from the outside by driving the small fan unit 500 connected to the bypass duct unit 400 through the bypass duct unit 400 through the fan bank 70 move to

Next, the temperature difference of the air sensed by each of the first temperature sensor unit 100 positioned at the front of the heater 21 and the second temperature sensor unit 200 positioned at the rear of the heater 21 satisfies a set value make sure you do

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Hereinafter, an example of a heater capacity test method of an air cleaning unit of a nuclear power plant will be described with reference to FIG. 2 .

2 is a flowchart illustrating a method for testing a heater capacity of an air cleaning unit of a nuclear power plant according to another embodiment.

Referring to FIG. 2 , first, the capacity of the heater is input, the flow rate of the small fan is calculated, and the test success standard temperature difference is calculated.

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Next, the bypass duct part is directly connected by bypassing between the heater bank and the fan bank, and the small activated carbon filter part and the small fan part are connected to the bypass duct part.

The bypass duct forming the test flow path is flexible and installed to surround the entrances and exits of the heater bank and the fan bank, respectively, and may be installed so that there is no leakage.

A small activated carbon filter unit is installed inside the bypass duct for purifying radioactive iodine particles.

The small fan unit is configured in a small size that can be moved, and the flow rate of the small fan unit is determined in response to the heater test, and after calculating the capacity of the small fan unit, it may be installed in the bypass duct unit.

Next, drive the small fan unit, measure the flow rate of the small fan unit, and check if it is stabilized. The section in which the flow rate of the small fan unit is stabilized may be within ±10% of the rated flow rate, but is not limited thereto.

Next, measure the heater inlet and outlet temperatures, which are the front and rear sides of the heater, and check whether the test success criterion temperature difference is achieved. The heater capacity test is terminated when the measured heater inlet and outlet temperature difference achieves the test success criterion temperature difference.

As such, in the method for testing the heater capacity of the air cleaning unit of a nuclear power plant according to another embodiment, the heater bank 20 and the fan bank 70 are bypassed and directly connected to the bypass duct part 400, so that the heater from the outside Air passing through the heater 21 of the bank 20 is bypassed without passing through the pre-filter bank 30, the first HEPA filter bank 40, the activated carbon filter bank 50, and the second HEPA filter bank 60 By bypassing the fan bank 70 through the pass duct part 400 to test the capacity of the heater 21, the pre-filter 31, the first HEPA filter 41, and the activated carbon included in the air cleaning unit 90 are bypassed. Since the replacement cycle of the filters can be maintained by testing the capacity of the heater 21 of the air cleaning unit 90 without using filters including the filter 51 and the second HEPA filter 61, the air cleaning unit 90 ) to reduce maintenance costs.

That is, by testing the capacity of the heater 21 of the air cleaning unit 90 without using filters included in the air cleaning unit 90 of the nuclear power plant, the maintenance cost of the air cleaning unit 90 is reduced. A method for testing the heater capacity of an air cleaning unit is provided.

In addition, in the heater capacity test method of the air cleaning unit of a nuclear power plant according to another embodiment, each of the first temperature sensor unit 100 and the second temperature sensor unit 200 positioned on the front and rear sides of the heater 21 is Since the capacity of the heater 21 is tested using the temperature difference of the sensed air, the heater 21 is more accurately compared to testing the capacity of the heater 21 by placing a temperature sensor in the filter banks and the fan bank 70 . ) can be tested.

In addition, the heater capacity test method of the air cleaning unit of a nuclear power plant according to another embodiment simply checks the temperature difference between the air sensed by each of the first temperature sensor unit 100 and the second temperature sensor unit 200 to obtain a heater ( 21) can be tested.

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In addition, in the method for testing the heater capacity of the air cleaning unit of a nuclear power plant according to another embodiment, the bypass duct part 400 that bypasses and directly connects between the heater bank 20 and the fan bank 70 is flexible, so the bypass Since the duct part 400 can be easily and directly connected between the heater bank 20 and the fan bank 70 of the air cleaning unit 90 having various structures, air cleaning having various structures according to the type of nuclear power plant The capacity of the heater 21 of the unit 90 can be easily tested.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

Air cleaning unit 90 , heater 21 , heater bank 20 , first temperature sensor unit 100 , second temperature sensor unit 200 , bypass duct unit 400 , small fan unit 500 .

Claims (6)

A heater bank including a heater for heating air introduced from the outside, a plurality of filter banks connected to the rear side of the heater bank to filter the air, and a plurality of filter banks connected to the rear side of the plurality of filter banks to convert the air into a nuclear power plant In the heater capacity testing apparatus of the air cleaning unit of a nuclear power plant for testing the capacity of the heater of the air cleaning unit including a fan bank supplied to the main control room of
a first temperature sensor located in front of the heater;
a second temperature sensor unit located at the rear side of the heater;
a bypass duct part directly connecting the heater bank and the fan bank; and
A small fan unit connected to the bypass duct unit
A heater capacity test device of an air cleaning unit of a nuclear power plant comprising a. In claim 1,
A control unit connected to the first temperature sensor unit and the second temperature sensor unit and further comprising a control unit configured to check whether a temperature difference of air sensed by each of the first temperature sensor unit and the second temperature sensor unit satisfies a set value A heater capacity test device of an air cleaning unit of a nuclear power plant. In claim 1,
The heater capacity testing apparatus of an air cleaning unit of a nuclear power plant further comprising a small activated carbon filter unit mounted inside the bypass duct unit. In claim 1,
The plurality of filter banks,
a pre-filter bank connected to the rear side of the heater bank and including a pre-filter;
a first HEPA filter bank connected to the rear side of the pre-filter bank and including a first HEPA filter;
an activated carbon filter bank connected to a rear side of the first HEPA filter bank and including an activated carbon filter; and
A second HEPA filter bank connected to the rear side of the activated carbon filter bank and including a second HEPA filter
includes,
The fan bank is a heater capacity testing device of an air cleaning unit of a nuclear power plant connected to the rear side of the second HEPA filter bank. A heater bank including a heater for heating air introduced from the outside, a plurality of filter banks connected to the rear side of the heater bank to filter the air, and a plurality of filter banks connected to the rear side of the plurality of filter banks to convert the air into a nuclear power plant In the heater capacity test method of the air cleaning unit of a nuclear power plant for testing the capacity of the heater of the air cleaning unit including a fan bank that supplies the main control room of
direct connection between the heater bank and the fan bank with a bypass duct;
driving a small fan connected to the bypass duct; and
Checking whether the temperature difference of the air sensed by each of the first temperature sensor unit positioned at the front of the heater and the second temperature sensor unit positioned at the rear of the heater satisfies a set value
A heater capacity test method of an air cleaning unit of a nuclear power plant comprising a. delete

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