KR102592750B1 - Evaporator for discharging gas-based fire extinguishing agents and fire extinguishing system - Google Patents

Abstract

An evaporator installed in a gaseous fire extinguishing agent spray nozzle according to an embodiment of the present invention includes a housing portion in which a flow pipe for the fire extinguishing agent is installed; A heater unit that performs a heating operation to vaporize the fire extinguishing agent; a fan unit that generates a flow of air so that heat emitted from the heating plate unit is directed toward the housing unit; and a power control unit for transmitting a control command signal by supplying power to the heating plate unit and the fan unit.

Description

Evaporator and fire extinguishing system for discharging gaseous fire extinguishing agents {EVAPORATOR FOR DISCHARGING GAS-BASED FIRE EXTINGUISHING AGENTS AND FIRE EXTINGUISHING SYSTEM}

The present invention relates to an evaporation device installed in front of a fire extinguishing agent discharge nozzle and a fire extinguishing system using the same. More specifically, the present invention relates to the release of a gaseous fire extinguishing agent to minimize the delay in the release of the fire extinguishing agent by promoting evaporation when the gaseous fire extinguishing agent is discharged. It relates to an evaporator and a fire extinguishing system using the same.

Typically, fire prevention areas such as emergency diesel generator rooms and safety-related cable rooms in nuclear power plants are equipped with low-pressure gas-based fire extinguishing equipment to extinguish fires. At this time, carbon dioxide (CO ₂ ) is the final oxide of carbon and can no longer undergo combustion reactions. Because it does not cause fire, it is widely used as a gas-based fire extinguishing agent along with refractory gases such as nitrogen, water vapor, and argon halon.

Figure 1 is a diagram conceptually showing a conventional low-pressure gas-based fire extinguishing system.

Typically, low-pressure gas-based fire extinguishing equipment is configured to spray carbon dioxide from the storage tank (a) through the pipe (c) into the protected area (A) through the nozzle 30 seconds after the fire alarm occurs.

To be more specific, when a fire in the protected area (A) is detected through a fire detector, the fire extinguishing equipment detects a fire signal automatically or manually by a person who recognizes the fire by pressing the button of the operating device, The sole of the gas-based fire extinguishing agent storage container valve (b) opens the fire extinguishing agent storage container valve (b). The fire extinguishing agent released from the storage container (a) passes through the pipe (c) and is sprayed to the fire occurrence area through the nozzle (d) installed on the ceiling of the protected area (A).

At this time, the gas-based fire extinguishing agent may be a fire extinguishing agent containing carbon dioxide (CO ₂ ), as described above. Carbon dioxide is a gas at room temperature, but liquefies when pressure is applied, so it is liquefied and stored in a storage container as a high-pressure gas. When released, it flows in the pipe as a liquid, but is vaporized and sprayed at the injection head.

However, in the conventional low-pressure gas fire extinguishing system described above, the temperature and pressure of the low-pressure CO ₂ gas storage tank are around -18°C and 2.1 MPa, respectively, and when a fire is detected, CO ₂ is automatically vaporized through the pipe. As this happens, the temperature at the end of the spinning nozzle usually drops to -78°C, causing a problem of delayed early release of CO ₂ due to cooling of the lower part of the nozzle.

Republic of Korea Patent Publication No. 10-1695196 (2016.05.02)

The problem to be solved by the present invention is to provide an evaporator integrated with an evaporator, a heat transfer plate, and a blower fan, and a fire extinguishing system including the same, in order to suppress the fire early by minimizing the delay in chemical discharge that occurs in the existing CO2 gas nozzle. will be.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The evaporator installed in the gaseous fire extinguishing agent injection nozzle according to an embodiment of the present invention for solving the above problems includes a housing portion in which a flow pipe for the fire extinguishing agent is installed; A heater unit that performs a heating operation to vaporize the fire extinguishing agent; a fan unit that generates a flow of air so that heat emitted from the heater unit is directed toward the housing unit; and a power control unit that supplies power to the heater unit and the fan unit to transmit a control command signal, and includes an evaporator for discharging a gaseous fire extinguishing agent.

In one embodiment, the gas-based fire extinguishing agent may be a fire extinguishing agent containing carbon dioxide (CO ₂ ).

In one embodiment, the heater unit may include a heat transfer plate on which a wiring structure for generating heat is installed at the bottom, and the heat transfer plate may be arranged to face the housing unit.

In one embodiment, the heat transfer plate may perform a heating operation in a temperature range of 50°C to 60°C.

In one embodiment, it may further include a sensor unit that detects one or more information values of the temperature or internal pressure of the flow pipe and the vaporization rate of the fire extinguishing agent flowing inside.

In one embodiment, the power control unit may transmit a control command signal to increase the heating temperature of the heater unit when the information value detected by the sensor unit is below a preset reference value.

In one embodiment, the housing portion may be installed by repeatedly bending at an angle so that the flow pipe of the fire extinguishing agent forms an 'ㄹ' shape.

A fire extinguishing system that sprays a gas-based fire extinguishing agent according to another embodiment of the present invention for solving the above problem includes one or more spray nozzles each installed to spray the gas-based fire extinguishing agent to a plurality of separated zones. Equipped with a fire extinguishing spray unit; A storage container unit openably connected to a pipe heading toward the spray nozzle; A selection valve unit that determines the flow direction of the gaseous fire extinguishing agent; An evaporator unit installed on a pipe connected to the spray nozzle; and a processing unit including a receiver unit that receives a signal that detects whether a fire has occurred in a specific protection area, and a controller unit that generates a control command for the fire extinguishing system according to the received signal.

In one embodiment, it includes an alarm unit that operates to notify an alarm signal indicating the occurrence of a fire, and the alarm unit may perform an operation of emitting a warning light or transmitting a warning sound.

In one embodiment, the processing unit may generate a control command so that the alarm unit operates to notify an alarm signal for more than 30 seconds.

Other specific details of the invention are included in the detailed description and drawings.

According to embodiments of the present invention, there are at least the following effects.

By installing a heat-generating evaporator, the vaporization of the gaseous fire extinguishing agent flowing along the pipe is promoted, thereby minimizing the agent discharge delay that occurs in the existing gaseous fire extinguishing agent injection nozzle, thereby improving the efficiency of fire extinguishing work.

As a result, it is possible to minimize human casualties, economic costs, and other losses due to fire by reaching the standard concentration of gaseous fire extinguishing agents required within the fire protection zone early.

The effects according to the present invention are not limited to the contents exemplified above, and further various effects are included in the present specification.

Figure 1 is a diagram conceptually showing a low-pressure gas-based fire extinguishing system.
Figure 2 is an enlarged view showing the structure of an evaporator for discharging a gaseous fire extinguishing agent according to an embodiment of the present invention.
Figure 3 is a diagram showing the structure of a fire extinguishing system using an evaporator for discharging the gaseous fire extinguishing agent of Figure 2.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Additionally, embodiments described in this specification will be described with reference to cross-sectional views and/or schematic diagrams that are ideal illustrations of the present invention. Accordingly, the form of the illustration may be modified depending on manufacturing technology and/or tolerance. Additionally, in each drawing shown in the present invention, each component may be shown somewhat enlarged or reduced in consideration of convenience of explanation. Like reference numerals refer to like elements throughout the specification.

The gaseous fire extinguishing agent to which the evaporator 1 for discharging the gaseous fire extinguishing agent and the fire extinguishing system using the same according to an embodiment of the present invention described below includes carbon dioxide (CO ₂ ), nitrogen, The explanation will be based on the fact that it may contain one or more of the inert gases such as water vapor, argon, and halon. However, this is only for convenience of explanation, and it should be understood that various other types of gas-based fire extinguishing agents are applied to various embodiments of the present invention.

First, the evaporator 1 for discharging a gaseous fire extinguishing agent according to an embodiment of the present invention will be described in detail with reference to FIG. 2. Figure 2 is an enlarged view of the structure of the evaporator 1 for discharging a gaseous fire extinguishing agent according to an embodiment of the present invention.

As shown, the evaporator 1 for discharging a gaseous fire extinguishing agent according to an embodiment of the present invention is an evaporator 1 installed in the gaseous fire extinguishing agent injection nozzle 2, and is a flow pipe of the fire extinguishing agent ( A housing portion 100 in which 120) is installed; A heater unit 200 that performs a heating operation to vaporize the fire extinguishing agent; a fan unit 300 that generates a flow of air so that the heat emitted from the heater unit 200 is directed toward the housing unit 100; And a power control unit 400 that supplies power to the heater unit 200 and the fan unit 300 to transmit a control command signal may be included as a component forming the basic structure of the invention.

The housing portion 100 is installed at the front of the head of the gaseous fire extinguishing agent spray nozzle (2) and is configured to provide a flow pipe through which the introduced fire extinguishing agent receives heat, vaporizes, and flows out. The flow pipe is connected to the housing. It may be installed built into the frame 110 forming the body of the unit 100. One end of the flow pipe may be connected to a pipe connected from a fire extinguishing agent storage tank, and the other end of the flow pipe may be connected to the spray nozzle 2 of the gaseous fire extinguishing agent.

The gaseous fire extinguishing agent released in a liquid state flows into the flow pipe through a pipe at one end connected to the fire extinguishing agent storage tank. Afterwards, the flow pipe receives the heat generated by the heater unit 200, as will be described later, and raises the temperature of the gaseous fire extinguishing agent flowing inside, causing a vaporization effect. A gaseous fire extinguishing agent spray nozzle head (2) is connected to the other end of the flow pipe, and the gaseous fire extinguishing agent that was introduced in a liquid state flows out in a vaporized state.

The housing unit 100 according to an embodiment of the present invention may be installed by repeatedly bending the built-in flow pipe at an angle to form an 'ㄹ' shape. Preferably, the flow pipe may be installed so that one surface forming a predetermined area by repeatedly bending at an angle in a 'L' shape faces the heater unit 200. Through this type of installation, the area and time for receiving heat generated from the heater unit 200 can be increased.

The power control unit 400 is a means for transmitting a control command signal by supplying power to the heater unit 200 and/or the fan unit 300 as the spraying system of the gas-based fire extinguishing agent is started due to a fire occurring in the protected area. . For example, the power control unit 400 according to the present invention may directly receive a fire signal from a fire receiver that is separately connected to the outside, and as another example, the storage container for the gas-based fire extinguishing agent is opened to release the gas-based fire extinguishing agent. It may be receiving a signal.

The heater unit 200 is installed close to the housing unit 100 and is a means of generating heat to vaporize the fire extinguishing agent flowing inside the flow pipe 120 in a liquid state.

The heater unit 200 according to an embodiment of the present invention may be provided with a heat transfer plate 210 that receives power and generates heat using the heating action of current. The heat transfer plate 210 may have a wiring structure in which nichrome wire or another type of alloy is wound in a spiral manner to generate heat and is installed at the bottom of a flat plate.

At this time, the heat transfer plate 210 is preferably installed so that the plate surface faces the housing portion 100. In other words, it should be installed so that heat generated when power is supplied to the wiring structure installed under the plate is more efficiently transferred to the flow pipe 120 built into the housing portion 100. The plate surface of the heat transfer plate 210 may be installed in contact with the housing portion 100 and face it, or may be installed at a close distance and spaced apart.

In addition, the housing portion 100 according to an embodiment of the present invention may have one side open toward the direction in which the frame 110 forming the body faces the heat transfer plate 210. That is, the flow conduit 120 built into one side of the frame 110 may be drilled to be exposed toward the heat transfer plate 210.

The heat transfer plate 210 according to an embodiment of the present invention may perform a heating operation in a temperature range of 50°C to 60°C. The low-pressure CO ₂ gas storage tank stores CO ₂ in liquid form by maintaining a temperature of -18°C and a pressure of 2.1 MPa. When the pipe is opened, the pressure decreases and CO ₂ is vaporized into the spray nozzle (2). It must be sprayed through the head. However, there is a problem in that the temperature at the end of the nozzle drops to -78°C, causing cooling of CO ₂ . Accordingly, in the present invention, the heat transfer plate 210 installed in the heater unit 200 automatically operates in a temperature range of 50°C to 60°C, thereby promoting the vaporization of CO ₂ in the capillary tube in front of the nozzle.

The fan unit 300 includes a drive motor 320 that receives power to generate rotational force and a blade 310 rotatably installed on one side of the drive motor 320, and is installed at the rear of the heater unit 200. It is configured to generate a flow of air toward the housing portion 100. That is, the fan unit 300 can increase the heat transfer efficiency of the heater unit 200 by generating a flow of air so that the heat emitted from the heating plate unit is directed toward the housing unit 100.

The evaporator 1 for discharging a gaseous fire extinguishing agent according to an embodiment of the present invention may further include a sensor unit 500 that detects information on the state of the flowing fire extinguishing agent. In more detail, the sensor unit 500 may be provided with a sensor device for checking the vaporization state of the fire extinguishing agent flowing along the inside of the flow pipe 120 built into the housing unit 100.

At this time, the sensor unit 500 may be built into software in a sensor device installed on one side of the interior or exterior of the housing unit 100, or may constitute a separate, independent terminal device connected to communication with the sensor device. It may be. In addition, the sensor device is installed on the flow conduit 120, and it is desirable to install it closer to the outlet of the flow conduit 120 than the inlet.

The sensor unit 500 according to an embodiment of the present invention includes a sensor device that detects information values about temperature and/or pressure on the flow pipe 120, and based on the detected temperature and/or pressure information values. This may be to diagnose the vaporization state of the gaseous fire extinguishing agent entering the injection nozzle (2) head.

The sensor unit 500 according to another embodiment of the present invention may include a sensor device that detects the vaporization rate of the gaseous fire extinguishing agent flowing inside the flow pipe 120. For example, the sensor device is a sensor that detects changes in the electrochemical reaction of the flowing fire extinguishing agent or detects physical characteristic values in an optical manner, so that the gas-based fire extinguishing agent entering the head of the spray nozzle (2) is applied. The vaporization state may be diagnosed by detecting the gas concentration, etc.

Meanwhile, the sensor unit 500 according to the above-described embodiment of the present invention is not limited to a sensor device of a specific detection method, and various types of sensor devices capable of detecting the vaporization state of a liquid phase may be applied without limitation.

The sensor unit 500 can be connected to communication with the power control unit 400, and state information obtained by the sensor unit 500 is measured to diagnose the vaporization state of the gaseous fire extinguishing agent entering the head of the spray nozzle (2). The value is transmitted to the power control unit 400. Accordingly, when the power control unit 400 diagnoses that there is an abnormality in the vaporization state of the gaseous fire extinguishing agent entering the nozzle head, the power control unit 400 performs a heating operation by adjusting the power supplied to the heater unit 200 and the fan unit 300. takes control.

That is, the power control unit 400 according to an embodiment of the present invention has a preset reference value for diagnosing the vaporization state of the gas-based fire extinguishing agent, and when the information value detected by the sensor unit 500 is less than the preset reference value, , there may be a systemized algorithm that generates and transmits a control command to increase the heating temperature of the heater unit 200 and/or a control command to increase the rotational force to the fan unit 300.

For example, when the detection information value for the temperature on the flow pipe 120 detected from the sensor unit 500 is lower than the reference value for the preset temperature, or the flow pipe detected from the sensor unit 500 ( 120) If the detection information value for the internal pressure is higher than the preset reference value for the internal pressure, it can be indirectly diagnosed that there is an abnormality in the vaporization state of the gaseous fire extinguishing agent entering the head of the injection nozzle (2).

Alternatively, if the detection information value of the vaporization rate of the internally flowing fire extinguishing agent directly detected by the sensor unit 500 is lower than the preset reference value, the power control unit 400 similarly operates the gas system entering the head of the injection nozzle (2). It can be diagnosed that there is something wrong with the vaporization state of the fire extinguishing agent.

In this way, the power control unit 400, which detects an abnormality in the vaporization state of the gaseous fire extinguishing agent entering the head of the spray nozzle 2, issues a control command to increase the heating temperature of the heater unit 200 and/or the fan unit 300. A control command is generated and transmitted to increase the rotational force.

Accordingly, the power control unit 400 according to an embodiment of the present invention maintains the vaporization rate of the gaseous fire extinguishing agent delivered to the nozzle head at a desired level, thereby increasing the reliability of the protective action of the fire extinguishing system. At this time, the user can adjust the reliability and sensitivity of the vaporization condition diagnosis by increasing or lowering the preset reference value for diagnosing the condition.

Hereinafter, a fire extinguishing system for spraying a gas-based fire extinguishing agent according to an embodiment of the present invention described above will be described in detail with reference to FIG. 3. FIG. 3 is a diagram showing a fire extinguishing system using the evaporator 1 for discharging the gaseous fire extinguishing agent of FIG. 2.

As shown, the fire extinguishing system for spraying a gas-based fire extinguishing agent according to an embodiment of the present invention includes one or more spray nozzles (2) each installed to spray the gas-based fire extinguishing agent to a plurality of separated zones. A fire extinguishing spray unit (20) equipped with a; An evaporator unit (10) installed on a pipe connected to the spray nozzle (2); A storage container unit (30) connected to the pipe facing the spray nozzle (2) in an openable manner; A selection valve unit (40) that determines the flow direction of the gas-based fire extinguishing agent; And a processing unit 50 including a receiver unit 51 that receives a signal to detect whether a fire has occurred in a specific protection area, and a controller unit 52 that generates a control command for the fire extinguishing system according to the received signal. It can be included as a component that forms the basic structure of the system.

The fire extinguishing spray unit 20 consists of a group of one or more spray nozzles 2 installed to perform fire extinguishing operations in a plurality of separate areas such as the emergency diesel generator room and the safety-related power cable room of the nuclear power plant. Each spray nozzle 2 is preferably installed at a predetermined distance on the ceiling for proper fire extinguishing action in the protected area.

The evaporator unit 10 is installed on a pipe in a position close to the spray nozzle 2, and may be comprised of a plurality of evaporators 1, each installed in the head of one or more spray nozzles 2. At this time, the evaporator 1 constituting the evaporator unit 10 according to an embodiment of the present invention may be any one of the evaporators 1 for discharging the gaseous fire extinguishing agent according to the various embodiments described above.

The storage container unit 30 is a storage tank in which a gaseous fire extinguishing agent is stored, and is connected to the fire extinguishing spray unit 20 through a pipe connected so that one side can be opened and closed. For example, an on-off valve may be installed and connected to the end of the pipe on one side of the storage container unit 30.

The storage container unit 30 according to an embodiment of the invention is a low-pressure CO ₂ gas storage tank that stores CO ₂ in liquid form by maintaining a temperature of -18°C and a pressure of 2.1 MPa, and when opened to the pipe, CO ₂ is released. At this time, the released CO ₂ moves along the pipe and evaporates as the pressure decreases.

The selection valve unit 40 is installed on the pipe while connecting the fire extinguishing spray unit 20 and the storage container unit 30 so that the gas-based fire extinguishing agent flows, and directs the gas system toward the protected area where the fire of the gas-based fire extinguishing agent occurs. It is a valve configuration that controls the flow direction so that the fire extinguishing agent is sprayed.

The processing unit 50 is configured to control the fire extinguishing system, such as starting the discharge and spraying of the gaseous fire extinguishing agent upon detection of a fire, and may be configured to include a receiver unit 51 and a controller unit 52, respectively.

The receiver unit 51 receives a signal that detects whether a fire has occurred in a specific protection zone and recognizes the zone where the fire occurred. The receiver unit 51 is installed separately in each divided zone and includes an automatic fire detector 51a that automatically detects the occurrence of a fire and/or a manual fire detector 51b that can be input by a worker who recognizes whether a fire has occurred. ) may be connected to each other.

The control unit 52 generates and transmits a control command for the fire extinguishing system according to the received fire signal. That is, when a fire in a specific protection zone is recognized through the receiver unit 51, a control command is generated to spray a gas-based fire extinguishing agent into the corresponding protection zone. More specifically, the controller unit 52 provides a control command to open the on/off valve to release the gas-based fire extinguishing agent in the storage container unit 30, and the gas-based fire extinguishing agent released into the selection valve unit 40 causes the fire. It may be to generate and transmit a control command to adjust the direction to flow to the protected area where a fire occurs or a control command to perform a heating operation on the gaseous fire extinguishing agent flowing along the pipe to the evaporator unit 10. In addition, the controller unit 52 may generate and transmit a control command to perform an operation to notify an alarm signal to the alarm unit 60, which will be described later.

A fire extinguishing system that sprays a gas-based fire extinguishing agent according to an embodiment of the present invention may further include an alarm unit 60 that operates to notify an alarm signal indicating the occurrence of a fire.

The alarm unit 60 is installed in a plurality of separate areas such as the emergency diesel generator room and the safety-related power cable room of the nuclear power plant, and performs an operation to notify internal workers of an alarm signal to recognize the occurrence of a fire. For example, the alarm unit 60 emits a warning light or emits a warning sound, allowing workers to quickly respond to a fire or evacuate.

In addition, the operation of notifying the alarm signal of the alarm unit 60 described above may be performed by receiving a control command generated by the controller 52.

Meanwhile, in the case of fire extinguishing using a normal CO ₂ gas-based fire extinguishing agent spraying system, the gas-based fire extinguishing agent is sprayed 30 seconds after recognizing the fire signal, and the CO ₂ concentration in the protected area reaches 32% within 1 minute. This is taken as the performance standard for fire extinguishing equipment.

Accordingly, the controller unit 52 according to an embodiment of the present invention may generate a control command so that the alarm unit 60 operates to notify an alarm signal for more than 30 seconds. This minimizes casualties to workers located inside the protected area prior to fire extinguishing action by spraying gas-based fire extinguishing agents, and also increases the efficiency of fire extinguishing work by allowing workers to take initial action.

The evaporator (1) for discharging the gaseous fire extinguishing agent of the present invention according to the various embodiments described above and the fire extinguishing system using the same promote the vaporization of the gaseous fire extinguishing agent flowing along the pipe by installing the heat-generating evaporator (1). The efficiency of fire extinguishing work can be improved by minimizing the delay in chemical discharge occurring from the gas-based fire extinguishing agent injection nozzle (2).

As a result, it is possible to minimize human casualties, economic costs, and other losses due to fire by reaching the standard concentration of gaseous fire extinguishing agents required within the fire protection zone early.

Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

A: Protected area
1: Evaporator
2: Spray nozzle
10: Evaporator unit
20: Fire extinguishing spray unit
30: Storage container unit
40: Select valve unit
50: processing unit
51: receiver unit
51a: Automatic fire detector
51b: Manual fire detector
52: Controlled donation
60: Alarm unit
100: Housing part
110: frame
120: Flow pipe
200: Heater unit
210: electric heating plate
300: Fan section
310: blade
320: Drive motor
400: Power control unit
500: sensor unit

Claims (10)

In the evaporator installed in the gaseous fire extinguishing agent spray nozzle,
A housing portion in which a flow pipe for a fire extinguishing agent is installed;
A heater unit that performs a heating operation to vaporize the fire extinguishing agent;
a fan unit that generates a flow of air so that heat emitted from the heater unit is directed toward the housing unit; and
It includes a power control unit that supplies power to the heater unit and the fan unit and transmits a control command signal,
The gas-based fire extinguishing agent is,
It is a fire extinguishing agent containing carbon dioxide (CO2),
The housing part,
It includes a frame in which the flow pipe is installed,
The frame is,
One side is open toward the direction facing the heater unit,
The heater unit,
Forming a heating space in which the flowing air is heated,
In the heating space
A heating plate on which a wiring structure for generating heat is installed is provided,
The heating plate is,
disposed adjacently to face one open side of the frame,
The housing unit, the heater unit, and the fan unit,
An evaporator for discharging a gaseous fire extinguishing agent, characterized in that it is arranged in a straight line. delete delete According to paragraph 1,
The heat transfer plate is an evaporator for discharging a gaseous fire extinguishing agent, which generates heat in a temperature range of 50°C to 60°C. According to paragraph 1,
An evaporator for discharging a gaseous fire extinguishing agent, further comprising a sensor unit that detects one or more information values of the temperature or internal pressure of the flow pipe and the vaporization rate of the fire extinguishing agent flowing inside. According to clause 5,
The power control unit transmits a control command signal to increase the heating temperature of the heater unit when the information value detected by the sensor unit is below a preset reference value. According to paragraph 1,
An evaporator for discharging a gas-based fire extinguishing agent, wherein the housing portion is installed by repeatedly bending at an angle so that the flow pipe of the fire extinguishing agent forms an 'L' shape. In a fire extinguishing system that sprays a gas-based fire extinguishing agent,
A fire extinguishing spray unit having one or more spray nozzles each installed to spray a gaseous fire extinguishing agent to a plurality of separated zones;
A storage container unit openably connected to a pipe heading toward the spray nozzle;
A selection valve unit that determines the flow direction of the gaseous fire extinguishing agent;
An evaporator unit installed on a pipe connected to the spray nozzle; and
It includes a processing unit including a receiving unit that receives a signal that detects whether a fire has occurred in a specific protection area, and a control unit that generates a control command for the fire extinguishing system according to the received signal,
A fire extinguishing system for spraying a gas-based fire extinguishing agent, wherein the evaporator unit includes an evaporator for discharging the gas-based fire extinguishing agent according to any one of claims 1 and 4 to 7. According to clause 8,
It includes an alarm unit that operates to signal an alarm signal indicating the occurrence of a fire,
The alarm unit is a fire extinguishing system that sprays a gas-based fire extinguishing agent and performs a warning light emission operation or a warning sound transmission operation. In paragraph 9
The control unit is a fire extinguishing system that sprays a gas-based fire extinguishing agent, generating a control command so that the alarm unit operates to notify an alarm signal for more than 30 seconds.

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