KR102065064B1 - Apparatus for purging remaining gas in pipe and method thereof - Google Patents

Abstract

Disclosed are a system and a method for removing remaining gas in a pipe. According to the embodiment of the present invention, the system for removing remaining gas in a pipe includes: a nitrogen supply valve connected to a gas pipe and supplying nitrogen into the gas pipe; a nitrogen control valve installed in a rear end of the nitrogen supply valve and controlling a flow rate of the nitrogen supplied; a steam supply valve connected to the gas pipe and supplying steam; a steam control valve installed at a rear end of the steam supply valve and controlling the flow rate of the steam supplied; and a fuzzy control center. The fuzzy control center performs a nitrogen fuzzy work by controlling the flow rate of the nitrogen supplied to the nitrogen control valve in order for a gas pressure value in the gas pipe to follow a first pressure threshold while a fixed amount of the nitrogen is supplied by opening the nitrogen supply valve in accordance with an automatic mode. After then, the fuzzy control center performs a steam fuzzy work by controlling the flow rate of the steam supplied to the steam control valve in order for the gas pressure value in the gas pipe to follow a second pressure threshold while a fixed amount of steam is supplied by opening the steam supply valve.

Description

Apparatus and method for removing residual gas in pipe {APPARATUS FOR PURGING REMAINING GAS IN PIPE AND METHOD THEREOF}

The embodiment relates to a method for removing residual gas, and more particularly, to an apparatus and a method for automatically removing residual gas in a pipe by controlling a gas pressure value in the gas pipe.

In general, by-product gases such as Blast Furnace Gas (BFG), Coke Oven Gas (COG), and Linz Donawitz Gas (LDG), which are generated during operation at steel mills, are used as fuel for power plants. .

1 is a view showing the overall power flow of the power plant using the by-product gas as fuel, Figure 2 is a screen for monitoring the state in which the by-product gas recovered from the power plant is burned.

Referring to FIG. 1, by-product gas generated during steel mill operation is recovered and used as a power plant fuel, and an output, that is, electricity is produced through a steam turbine and a generator.

Referring to FIG. 2, a by-product gas is recovered through a transfer pipe of each of BFG, COG, and LDG in a power plant, and a state in which the recovered by-product gas is burned is monitored through a screen.

At this time, in the case of boiler maintenance work or the maintenance or inspection work of the pipe, the gas is shut off using the water at the waterside and the remaining gas in the gas pipe is purged with nitrogen (N2) gas, and then carbon monoxide (CO). When the gas is detected and below 30ppm, the final blowing operation is performed using steam.

3 is a view for explaining the process of removing the residual gas in the pipe according to the prior art, Figure 4 is a view showing a control screen of the nitrogen purge operation according to the prior art.

3 to 4, under the direction of the driver, the field operator operates the manual dissipation valve 16a to form an appropriate purge pressure necessary for the purge operation, wherein a gas which is fatal to the human body is discharged to the outside through the dissipation pipe. The problem of leaking and inhaling the on-site worker, and initially discharging a large amount of gas outside the measuring range of the portable detector is repeated every time the nitrogen purge operation is carried out. The seal pot is destroyed and a large amount of gas is leaked out.

After the purge of nitrogen is completed, steam (approximately 10kg / cm2, 220 ℃) is used to remove the gas remaining in the gas pipe.However, when the manual steam supply valve 19 is operated, the steam of high temperature and high pressure steam and gas ( Residues, such as tar), are ejected together with steam and are scattered to workers, causing burns and gas poisoning to exist, and there are difficulties in safety work due to collisions, falls and poor power distribution in narrow working spaces.

Patent Application Publication No. 10-1825693

Embodiments can provide an apparatus and method for automatically removing residual gas in a pipe by controlling a gas pressure value in the gas pipe.

A system for removing residual gas in a pipe according to an embodiment of the present invention is connected to the gas pipe, the nitrogen supply valve for supplying nitrogen into the gas pipe; A nitrogen control valve disposed at a rear end of the nitrogen supply valve to control a flow rate of the supplied nitrogen; A steam supply valve connected to the gas pipe and supplying steam; A steam control valve disposed at a rear end of the steam supply valve and controlling a flow rate of the supplied steam; And controlling the flow rate of the nitrogen supplied to the nitrogen control valve so that the gas pressure value in the gas pipe follows the first pressure threshold in a state in which the nitrogen supply valve is opened and the nitrogen supply valve is supplied according to the automatic mode. After performing the purge operation, the steam supply valve is opened to control the flow rate of the steam supplied to the steam control valve so that the gas pressure value in the gas pipe follows the second pressure threshold in a state where a predetermined amount of steam is supplied. It may include a purge control center for controlling to perform the steam purge operation.

The nitrogen supply valve may be opened according to the automatic mode to supply nitrogen into the gas pipe, and may be shut off when the nitrogen purge operation is completed.

The system for removing residual gas in the pipe further includes a pressure detector for detecting a gas pressure value in the gas pipe to which the nitrogen is supplied periodically for a first predetermined working time, and the purge control center includes the detected gas. The nitrogen control valve may be controlled such that the gas pressure value follows the first pressure threshold by comparing the pressure value with the first pressure threshold.

The purge control center may shut off the nitrogen control valve when the detected gas pressure value is greater than or equal to a preset abnormal threshold value.

The system for removing residual gas in the pipe further includes a gas detector for detecting the concentration of carbon monoxide in the gas pipe to which the nitrogen is supplied, wherein the purge control center has a detected concentration of carbon monoxide below a predetermined concentration threshold. When the first working time has elapsed, the nitrogen supply valve and the nitrogen control valve may be blocked.

The system for removing residual gas in the pipe further includes three gas detectors installed at the front end, the middle part, and the end of the gas pipe to which the nitrogen is supplied to detect the concentration of carbon monoxide in the gas pipe. The purge control center may shut off the nitrogen supply valve and the nitrogen control valve when the concentration of carbon monoxide detected from each of the three gas detectors is at least two gas detectors below a predetermined concentration threshold and the first working time has elapsed. Can be.

The steam supply valve may be opened when the nitrogen purge operation is completed to supply the steam, and shut off when the steam purge operation is completed.

The system for removing residual gas in the pipe further includes a pressure detector that periodically detects a gas pressure value in the gas pipe during a second predetermined working time, and the purge control center includes the detected gas pressure value and the The steam control valve may be controlled such that the gas pressure value follows the second pressure threshold by comparing a second pressure threshold.

The gas pipe includes a main gas pipe connected to a lower end of a water seal side, an extended steam pipe part connected to a first side of the main gas pipe, and an input steam pipe part and an output steam pipe part branched from both ends of the extended steam pipe part. And a steam pipe, wherein the steam supply valve and the steam control valve are disposed in the input steam pipe, and a steam dissipation valve may be disposed in the output steam pipe.

The gas pipe includes a main gas pipe connected to a lower end of the water seal side and a nitrogen pipe connected to a second side part spaced apart from the first side of the main gas pipe by a predetermined distance, wherein the nitrogen supply valve and the nitrogen control are connected to the nitrogen pipe. The valve may be disposed, and the nitrogen dissipation valve may be disposed at the distal end of the gas pipe.

According to another embodiment of the present invention, there is provided a method for removing residual gas in a pipe in which a gas pressure value in the gas pipe is set in a state in which a nitrogen supply valve connected to the gas pipe is opened to supply a predetermined amount of nitrogen. Performing a nitrogen purge operation by controlling a flow rate of the supplied nitrogen to a nitrogen control valve disposed at a rear end of the nitrogen supply valve to follow a pressure threshold; When the nitrogen purge operation is completed, the nitrogen supply valve and the nitrogen control valve are shut off, and a steam supply valve connected to the gas pipe is opened to supply a predetermined amount of steam to supply a gas pressure value to the second pressure. Performing a steam purge operation by controlling a flow rate of the supplied steam to a steam control valve disposed at a rear end of the steam supply valve to follow a threshold value; And shutting off the steam supply valve and the steam control valve when the steam purge operation is completed.

In the performing of the nitrogen purge operation, the gas pressure value in the gas pipe to which the nitrogen is supplied is periodically detected for a first predetermined working time, and the detected gas pressure value is compared with the first pressure threshold value. Control the nitrogen control valve so that the pressure value follows the first pressure threshold, detect the concentration of carbon monoxide in the gas pipe to which the nitrogen is supplied, and wherein the detected concentration of carbon monoxide is equal to or less than a predetermined concentration threshold; When the working time has elapsed, the nitrogen supply valve and the nitrogen control valve may be shut off.

In the performing of the steam purge operation, a gas pressure value in the gas pipe is periodically detected for a second predetermined working time, and the gas pressure value is determined by comparing the detected gas pressure value with the second pressure threshold. The steam control valve may be controlled to follow a second pressure threshold, and the steam supply valve and the steam control valve may be shut off when the steam purge operation is completed after the second operation time has elapsed.

According to the embodiment, the nitrogen supply valve is opened in an automatic mode to control the flow rate of nitrogen supplied to the nitrogen control valve so that the gas pressure value in the gas pipe follows the first pressure threshold in a state where a predetermined amount of nitrogen is supplied. After the purge operation is performed, the steam supply valve is opened to control the flow rate of steam supplied to the steam control valve so that the gas pressure value in the gas pipe follows the second pressure threshold in a state where a predetermined amount of steam is supplied. By carrying out, it is possible to automatically remove the remaining gas in the gas pipe.

According to the embodiment, since the remaining gas in the gas pipe is automatically removed, it is possible to minimize the miscalculation and misoperation of the operator compared to the conventional manual purge operation.

According to the embodiment, since the remaining gas in the gas pipe is automatically removed, the gas poisoning accident due to the manual operation of the gas pipe, a burn disaster due to high temperature and high pressure steam, a collision in a narrow space, a fall, a poor power distribution, and the like Safety accidents can be prevented.

1 is a view showing the overall power flow of a power plant using by-product gas as fuel.
2 is a screen for monitoring a state in which the by-product gas recovered from the power plant is burned.
3 is a view for explaining the process of removing the residual gas in the gas pipe according to the prior art.
4 is a view showing a control screen of the nitrogen purge operation according to the prior art.
5 is a view showing a residual gas removal system according to an embodiment of the present invention.
6 is a view for explaining the position of the valve installed in the gas pipe shown in FIG.
7A to 7B are views for explaining the nitrogen purge operation and the steam purge operation.
FIG. 8 is a diagram illustrating a detailed configuration of the purge control center shown in FIG. 5.
9 is a diagram illustrating a control screen for performing a purge operation according to an embodiment of the present invention.
10 is a view showing a residual gas removing method according to an embodiment of the present invention.
11A to 11D are diagrams for describing a valve control principle according to gas pressure.

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

However, the technical idea of the present invention is not limited to some embodiments described, but may be implemented in various forms, and within the technical idea of the present invention, one or more of the components may be selectively selected between the embodiments. Can be combined and substituted.

In addition, the terms (including technical and scientific terms) used in the embodiments of the present invention may be generally understood by those skilled in the art to which the present invention pertains, unless specifically defined and described. The terms commonly used, such as terms defined in advance, may be interpreted as meanings in consideration of the contextual meaning of the related art.

In addition, the terms used in the embodiments of the present invention are intended to describe the embodiments and are not intended to limit the present invention.

In this specification, the singular may also include the plural unless specifically stated in the text, and may be combined into A, B, and C when described as “at least one (or more than one) of A and B and C”. It can include one or more of all possible combinations.

In addition, in describing the components of the embodiments of the present disclosure, terms such as first, second, A, B, (a), and (b) may be used.

These terms are only to distinguish the components from other components, and the terms are not limited to the nature, order, order, or the like of the components.

And when a component is described as being 'connected', 'coupled' or 'connected' to another component, the component is not only connected, coupled or connected directly to the other component, It may also include the case of 'connected', 'coupled' or 'connected' due to another component between the other components.

In addition, when described as being formed or disposed on the "top" or "bottom" of each component, the top (bottom) or the bottom (bottom) is not only when two components are in direct contact with each other, It also includes a case where the above-described further components are formed or disposed between two components. In addition, when expressed as "up (up) or down (down)" may include the meaning of the down direction as well as the up direction based on one component.

In an embodiment, the nitrogen purge is controlled by controlling the flow rate of nitrogen supplied to the nitrogen control valve so that the gas pressure value in the gas pipe follows the first pressure threshold in a state in which the nitrogen supply valve is opened and the nitrogen supply valve is supplied according to the automatic mode. The steam purge operation is performed by controlling the flow rate of steam supplied to the steam control valve so that the gas pressure value in the gas pipe follows the second pressure threshold while the steam supply valve is opened to supply a predetermined amount of steam after the operation. Suggest new ways to do this.

5 is a view showing a residual gas removal system according to an embodiment of the present invention.

Referring to FIG. 5, a system for removing residual gas according to an embodiment of the present invention includes a steam supply valve 11, a steam control valve 12, a steam dissipation valve 13, a nitrogen supply valve 14, It may include a nitrogen control valve 15, a gas dissipation valve 16, a gas detector 17, a pressure detector 18, and a purge control center 20.

The steam supply valve 11 is connected to the gas pipe 1 and can continuously supply a certain amount of steam. Since the steam supply valve 11 is an automatic steam supply valve driven by a control signal from the outside, a manual steam supply valve 11a may be further provided.

The steam control valve 12 may be disposed at the rear end of the steam supply valve 11 and control the flow rate of steam supplied through the steam supply valve 11. The steam control valve 12 may control the flow rate of steam according to the measured pressure so that the proper pressure in the gas pipe can be maintained.

The steam control valve 12 may increase or decrease the flow rate of steam according to the comparison result by comparing the gas pressure value measured in the gas pipe with a preset second pressure threshold.

The steam dissipation valve 13 may discharge steam supplied from the steam supply valve 11 to the outside. Since the steam dissipation valve 13 is an automatic steam dissipation valve driven by a control signal from the outside, a manual steam dissipation valve 13a may be further provided.

The nitrogen supply valve 14 is connected to the gas pipe 1 and can continuously supply a certain amount of nitrogen into the gas pipe. Since the nitrogen supply valve 14 is an automatic nitrogen supply valve driven by a control signal from the outside, a manual nitrogen supply valve 14a may be further provided.

The nitrogen control valve 15 is disposed at the rear end of the nitrogen supply valve 14, and can control the flow rate of nitrogen supplied through the nitrogen supply valve 14. The nitrogen control valve 15 may control the flow rate of nitrogen according to the measured pressure so that the proper pressure in the gas pipe can be maintained.

The nitrogen control valve 15 may increase or decrease the flow rate of nitrogen according to the comparison result by comparing the gas pressure value measured in the gas pipe with a preset first pressure threshold.

The gas dissipation valve 16 may be connected to the end of the gas pipe to discharge the gas in the gas pipe. Since the gas dissipation valve 16 is an automatic gas dissipation valve driven by a control signal from the outside, a manual gas dissipation valve 16a may be further provided.

The gas detector 17 is disposed in the gas pipe, and can detect the concentration of carbon monoxide in the gas pipe. The gas detector 17 may be disposed in the middle portion of the front end portion, the middle portion, and the end portion of the gas pipe, but is not limited thereto, and may vary as necessary.

The pressure detector 18 is arranged in the gas pipe 1, and can detect the gas pressure in the gas pipe 1. In this case, a plurality of pressure detectors 18 may be provided, for example, the first pressure detector 18a disposed at the front end of the gas pipe 1 and the second pressure disposed at the middle part of the gas pipe 1. The detector 18b may include a third pressure detector 18c disposed at the distal end of the gas pipe 1.

The purge control center 20 supplies the nitrogen control valve 15 so that the gas pressure value in the gas pipe follows the first pressure threshold in a state in which the nitrogen supply valve 14 is opened and a predetermined amount of nitrogen is supplied according to the automatic mode. After the nitrogen purge operation is performed by controlling the flow rate of nitrogen, the steam supply valve 11 is opened to the steam control valve so that the gas pressure value in the gas pipe follows the second pressure threshold in a state where a predetermined amount of steam is supplied. It may be controlled to perform the steam purge operation by controlling the flow rate of the supplied steam.

6 is a view for explaining the position of the valve installed in the gas pipe shown in FIG.

Referring to FIG. 6, the gas pipe 1 is connected to one end of the main gas pipe 1a, one end of which is connected to the rear end of the water seal, and the inside of the main gas pipe 1a. It may include a steam pipe (1b) and nitrogen pipe (1c) for removing the gas remaining in the.

The steam pipe 1b outputs an extension steam pipe part 1b_1 connected to the first side of the main gas pipe 1a and an input steam pipe part 1b_2 branched from both ends of the extension steam pipe part 1b_1. It may include a steam pipe (1b_3).

The steam supply valve 11 and the steam control valve 12 are disposed in the input steam pipe 1b_2, and the steam dissipation valve 13 is disposed in the output steam pipe 1b_3. At this time, the steam is discharged through the steam dissipation valve 13 of the output steam pipe 1b_3 through the steam supply valve 11 and the steam control valve 12 of the input steam pipe 1b_2 in sequence.

As such, even if steam passes only the steam pipe 1b without passing through the main gas pipe 1a, the remaining gas in the main gas pipe 1a may be discharged by a siphon phenomenon.

The nitrogen pipe 1c may be connected to the second side spaced a predetermined distance from the first side of the main gas pipe 1a. The nitrogen supply valve 14 and the nitrogen control valve 15 are arranged in the nitrogen pipe 1c. At this time, the nitrogen passes through the nitrogen supply valve 14 and the nitrogen control valve 15 of the nitrogen pipe 1c sequentially through the main gas pipe 1a connected to the other end and is discharged through the gas dissipation valve 16.

7A to 7B are views for explaining the nitrogen purge operation and the steam purge operation.

Referring to FIG. 7A, when the nitrogen purge operation is performed, the nitrogen control valve and the gas dissipation valve are opened, and when the nitrogen supply valve is opened, a certain amount of nitrogen is supplied into the gas pipe through the nitrogen supply valve, and the gas is passed through the gas pipe. It can be discharged to the outside through the discharge valve.

At this time, the nitrogen control valve controls the flow rate of nitrogen supplied so that the gas pressure in the gas pipe follows or maintains the proper pressure for a predetermined time, and when the concentration of carbon monoxide in the gas pipe becomes below the critical concentration, the nitrogen supply valve and the nitrogen control valve Is automatically blocked.

Referring to FIG. 7B, when the steam purge operation is performed, when the steam control valve and the steam dissipation valve are opened and the steam supply valve is opened, a certain amount of steam is supplied into the gas pipe through the steam supply valve, and steam dissipates through the gas pipe. It can be discharged to the outside through the valve.

At this time, the steam control valve controls the flow rate of nitrogen supplied to the gas pressure in the gas pipe to follow or maintain the proper pressure for a predetermined time, and when the gas pressure in the gas pipe is below the appropriate pressure, the steam supply valve and the steam control valve It is automatically shut off.

FIG. 8 is a diagram illustrating a detailed configuration of the purge control center shown in FIG. 5.

Referring to FIG. 8, the fuzzy control center 20 according to the exemplary embodiment of the present invention includes a communication unit 21, an input unit 22, a control unit 23, a display unit 24, and a storage unit 25. Can be.

The communication unit 21 includes a steam supply valve 11, a steam control valve 12, a steam dissipation valve 13, a nitrogen supply valve 14, a nitrogen control valve 15, and a gas dissipation valve installed in the gas pipe 1. Numerous information can be transmitted / received by interlocking wirelessly with the gas detector 17 and the pressure detector 18.

The input unit 22 may receive information by a menu or key manipulation from the user.

The controller 23 performs the nitrogen purge operation using the nitrogen supply valve, the nitrogen control valve, and the gas dissipation valve according to the automatic mode, and then performs the steam purge operation using the steam supply valve, the steam control valve, and the steam dissipation valve. Can be controlled. The nitrogen purge operation and the steam purge operation can remove residual gas in the gas pipe.

The display unit 24 may provide a control screen for performing the nitrogen purge operation and the steam purge operation, and display the result of performing the nitrogen purge operation and the steam purge operation on the control screen.

The storage unit 25 may include information for performing a nitrogen purge operation and a steam purge operation, for example, a time for performing a nitrogen purge operation, a time for performing a steam purge operation, an appropriate pressure in a gas pipe, that is, a pressure threshold, an abnormal pressure threshold, and the like. Carbon monoxide concentration and the like.

9 is a diagram illustrating a control screen for performing a purge operation according to an embodiment of the present invention.

9, a purge control center according to an embodiment of the present invention may provide a control screen for automatically performing a nitrogen purge operation and a steam purge operation. On this control screen, the items for operating in the automatic mode for automatically performing the purge operation and the manual mode for performing the purge operation manually, nitrogen supply valve, gas dissipation valve, nitrogen control valve, steam supply valve, steam control valve The item for operating the, and the item for showing the gas pressure value and carbon monoxide concentration may be displayed.

10 is a view showing a residual gas removing method according to an embodiment of the present invention.

Referring to FIG. 10, the residual gas removal system according to an embodiment of the present invention may perform a nitrogen purge operation according to the selection of the automatic mode (S10). That is, the residual gas removal system opens the nitrogen control valve (S21), opens the gas dissipation valve (S22), and then opens the nitrogen supply valve (S23) to perform a nitrogen purge operation. Can supply

Next, the residual gas removal system periodically detects the gas pressure value in the gas pipe (S24), compares the detected gas pressure value with a preset first pressure threshold value, and compares the gas pressure value in the gas pipe according to the result of the comparison. The flow rate of nitrogen supplied to the nitrogen control valve can be controlled to follow the preset first pressure threshold (S26).

At this time, the residual gas removal system drives the timer (S25) to control the nitrogen control valve for a predetermined first working time, for example, 1 hour or more, so that the gas pressure value in the gas pipe follows the gas threshold.

Next, the residual gas removal system may detect the carbon monoxide concentration in the gas pipe (S27), and determine whether the measured carbon monoxide concentration is less than or equal to a preset concentration threshold (S28).

Next, if the residual gas removal system is below the concentration threshold, the first operation time is checked (S29). When the first operation time is exceeded, it is determined that the nitrogen purge operation is completed, and the nitrogen supply valve is shut off (S30). ) Nitrogen control valve can be shut off (S31).

At this time, the residual gas removal system may measure the carbon monoxide concentration in each of the front end, the middle part, and the end of the gas pipe, and determine whether the carbon monoxide concentration measured in at least two sections is less than or equal to a preset concentration threshold.

Next, when it is determined that the nitrogen purge operation is completed, the residual gas removal system may perform the steam purge operation. That is, the residual gas removal system may supply a predetermined amount of steam by opening the steam control valve (S32), opening the steam dissipation valve (S33), and opening the steam supply valve (S34) to perform a steam purge operation.

In this case, the steam may be discharged to the outside via the steam pipe connected to the main gas pipe without being supplied to the main gas pipe of the gas pipe.

Next, the residual gas removal system periodically detects the gas pressure value in the gas pipe (S35), compares the measured gas pressure value with a preset second pressure threshold, and compares the gas pressure value in the gas pipe according to the result of the comparison. The flow rate of the steam supplied to the steam control valve can be controlled to follow the second pressure threshold (S37).

At this time, the residual gas removal system may drive a timer (S36) to control the steam control valve for a second predetermined working time, for example, two hours or more, to perform a process of following the gas pressure value in the gas pipe.

Next, the residual gas removal system checks whether the second operation time is exceeded (S38), and when the second operation time is exceeded, determines that the steam purge operation is completed, closes the steam supply valve (S39), and closes the steam control valve. Shut off (S40), the steam dissipation valve and the gas dissipation valve may be driven to open automatically.

11A to 11D are diagrams for describing a valve control principle according to gas pressure.

Referring to FIG. 11A, in a nitrogen purge operation, the purge control center may request a pressure detector to detect a gas pressure value in a gas pipe to receive a gas pressure value detected from the pressure detector.

Next, the purge control center may compare the gas pressure value detected from the pressure detector with the preset first pressure threshold. In this case, the preset first pressure threshold may be 200 mmH ₂ O. In this case, the first pressure threshold may have a predetermined range based on 200 mmH ₂ O.

Next, the purge control center may control the nitrogen control valve so that the gas pressure in the gas pipe follows the preset first pressure threshold according to the comparison result.

Referring to FIG. 11B, in the nitrogen purge operation, the purge control center may request the pressure detector to detect the gas pressure value in the gas pipe to receive the detected gas pressure value from the pressure detector.

Next, the purge control center may compare the gas pressure value detected from the pressure detector with a preset abnormal pressure threshold. In this case, the preset abnormal pressure threshold may be 500 mmH ₂ O.

Next, the purge control center may control the nitrogen control valve so that the gas pressure in the gas pipe follows the preset first pressure threshold according to the comparison result.

At this time, the purge control center judges that when the gas pressure value exceeds the preset pressure threshold as a result of the comparison, it has reached the necessary pressure, that is, the breakdown pressure of the seal port, by some factor, and the nitrogen supply through the nitrogen supply valve is turned off. Can be blocked.

Referring to FIG. 11C, in a steam purge operation, the purge control center may request a pressure detector to detect a gas pressure value in a gas pipe to receive a gas pressure value detected from the pressure detector.

Next, the purge control center may compare the gas pressure value detected from the pressure detector with a preset pressure threshold. In this case, the preset second threshold may be −50 mmH ₂ O. At this time, the second pressure threshold may have a predetermined range based on -50 mmH ₂ O.

Next, the purge control center may control the steam control valve so that the gas pressure in the gas pipe follows the preset second pressure threshold according to the comparison result.

Referring to FIG. 11D, in the nitrogen purge operation, the purge control center may request the plurality of gas detectors to detect the carbon monoxide concentration in the gas pipe and receive the carbon monoxide concentration detected from each of the plurality of gas detectors.

Next, the purge control center may compare the carbon monoxide concentration detected from each of the plurality of gas detectors with a preset concentration threshold. In this case, the preset concentration threshold may be 30 ppm.

Next, the purge control center may control the nitrogen control valve so that the gas pressure in the gas pipe follows the preset first pressure threshold according to the comparison result.

At this time, the purge control center may determine that the nitrogen purge operation is completed when the two or more gas detectors having a concentration of 30 ppm or less carbon monoxide detected as a result of the comparison may shut off the nitrogen supply valve.

The term '~ part' used in the present embodiment refers to software or a hardware component such as a field-programmable gate array (FPGA) or an ASIC, and '~ part' plays a role. However, '~' is not meant to be limited to software or hardware. '~ Portion' may be configured to be in an addressable storage medium or may be configured to play one or more processors. Thus, as an example, '~' means components such as software components, object-oriented software components, class components, and task components, and processes, functions, properties, procedures, and the like. Subroutines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables. The functionality provided within the components and the '~' may be combined into a smaller number of components and the '~' or further separated into additional components and the '~'. In addition, the components and '~' may be implemented to play one or more CPUs in the device or secure multimedia card.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

11: steam supply valve
12: steam control valve
13: steam dissipation valve
14: nitrogen supply valve
15: nitrogen control valve
16: gas dissipation valve
17: gas detector
18: pressure detector
20: Fuzzy Control Center

Claims (13)

A nitrogen supply valve connected to a gas pipe and supplying nitrogen into the gas pipe;
A nitrogen control valve disposed at a rear end of the nitrogen supply valve to control a flow rate of the supplied nitrogen;
A pressure detector for detecting a gas pressure value in the gas pipe to which the nitrogen is supplied;
A gas detector for detecting a concentration of carbon monoxide in the gas pipe to which the nitrogen is supplied;
A steam supply valve connected to the gas pipe and supplying steam;
A steam control valve disposed at a rear end of the steam supply valve and controlling a flow rate of the supplied steam; And
The nitrogen purge by controlling the flow rate of the nitrogen supplied to the nitrogen control valve so that the gas pressure value in the gas pipe follows the first pressure threshold in a state in which the nitrogen supply valve is opened and the nitrogen supply valve is supplied according to the automatic mode. After performing the operation, by opening the steam supply valve to control the flow rate of the steam supplied to the steam control valve so that the gas pressure value in the gas pipe follows the second pressure threshold in a state where a predetermined amount of steam is supplied A purge control center for controlling steam purge operations;
The purge control center
When the nitrogen purge operation is performed, the nitrogen control valve is configured to compare the gas pressure value periodically detected during the first predetermined working time with the first pressure threshold so that the gas pressure value follows the first pressure threshold. Control,
When the concentration of carbon monoxide detected from the gas detector is equal to or less than a predetermined concentration threshold and the first working time has elapsed, the nitrogen purge operation is completed to shut off the nitrogen supply valve and the nitrogen control valve,
When performing the steam purge operation, the steam control valve may be configured to compare the gas pressure value periodically detected during the second predetermined working time period with the second pressure threshold so that the gas pressure value follows the second pressure threshold. Control,
And the steam purge operation is completed when the second operation time has elapsed to shut off the steam supply valve and the steam control valve. delete delete delete delete The method of claim 1,
The gas detector includes three gas detectors respectively installed at the front end, the middle part, and the end of the gas pipe to which the nitrogen is supplied.
The purge control center shuts off the nitrogen supply valve and the nitrogen control valve when the concentration of carbon monoxide detected from each of the three gas detectors is at least two gas detectors below a predetermined concentration threshold and the first working time has elapsed. To remove residual gas in the piping. delete delete The method of claim 1,
The gas pipe includes a main gas pipe connected to a lower end of a water seal side, an extended steam pipe part connected to a first side of the main gas pipe, and an input steam pipe part and an output steam pipe part branched from both ends of the extended steam pipe part. Including steam piping,
The steam supply valve and the steam control valve is disposed in the input steam pipe,
And a steam dissipation valve is disposed in the output steam pipe. The method of claim 1,
The gas pipe includes a main gas pipe connected to a lower end of the water seal side and a nitrogen pipe connected to a second side part spaced apart from the first side of the main gas pipe by a predetermined distance.
The nitrogen supply valve and the nitrogen control valve is disposed in the nitrogen pipe,
And a nitrogen dissipation valve disposed at the distal end of the gas pipe. Opening the nitrogen supply valve connected to the gas pipe in the automatic mode to the nitrogen control valve disposed at the rear of the nitrogen supply valve so that the gas pressure value in the gas pipe follows the first pressure threshold in a state where a certain amount of nitrogen is supplied Performing a nitrogen purge operation by controlling a flow rate of nitrogen supplied; And
When the nitrogen purge operation is completed, the nitrogen supply valve and the nitrogen control valve are shut off, and a steam supply valve connected to the gas pipe is opened to supply a predetermined amount of steam to supply a gas pressure value to the second pressure. Performing a steam purge operation by controlling a flow rate of the supplied steam to a steam control valve disposed at a rear end of the steam supply valve to follow a threshold value;
In the step of performing the nitrogen purge operation,
Detects a gas pressure value in the gas pipe to which the nitrogen is supplied periodically for a first predetermined working time, compares the detected gas pressure value with the first pressure threshold to determine the gas pressure value as the first pressure threshold. Control the nitrogen control valve to follow,
Detecting a concentration of carbon monoxide in the gas pipe to which nitrogen is supplied, and shutting off the nitrogen supply valve and the nitrogen control valve when the detected concentration of carbon monoxide is equal to or less than a predetermined concentration threshold and the first working time has elapsed,
In the step of performing the steam purge operation,
The gas pressure value in the gas pipe is periodically detected during a second predetermined working time, and the detected gas pressure value and the second pressure threshold are compared so that the gas pressure value follows the second pressure threshold. Control the control valve,
And the steam purge operation is completed when the second operation time has elapsed to shut off the steam supply valve and the steam control valve. delete delete

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