KR20190046297A - Secure fire extinguishing system using carbon dioxide - Google Patents

Abstract

Disclosed is a safe fire extinguishing system using carbon dioxide. The safe first extinguishing system using carbon dioxide comprises: a fire detector; an injection nozzle; a concentration meter; a door lock; a control unit; a device detecting damage to a human body; and a human body access detector. The safe fire extinguishing system using the carbon dioxide may prevent indiscriminate injection of the carbon dioxide.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a safety fire extinguishing system using carbon dioxide,

The present invention relates to a safety fire extinguishing system using carbon dioxide. More specifically, in a fire extinguishing system for suppressing a fire by injecting carbon dioxide, even if a fire sensor detects a fire, it detects double occupancy of the inside of the fire extinguisher, This is a safety fire extinguishing system using carbon dioxide to prevent smokers' accidents by measuring the amount of remaining carbon dioxide in real time in case of subsequent fire suppression or restoration of fire Invention.

Fire extinguishing facilities in buildings emit fire water through a sprinkler or spray nozzle in response to signals sensed by a sensing sensor configured to sense heat, smoke, and the like during a fire. However, in the indoor space where important equipments such as computer room, electric room, and control room and special purpose high-priced equipments are installed, in order to prevent damage to equipments and articles by fire water, instead of liquid type fire water, And it is generally used in case of fire.

Among the extinguishing agents sprayed through the injection nozzle, halon gas has an excellent digestion performance and does not generate spray residues. Therefore, it is mainly used in a space where high-priced equipment such as a computer room, an electric room, This halon gas is very harmful to both the human body and the environment and has been restricted in its use due to its inclusion in policy-regulated substances under the Montreal Protocol. Recently, carbon dioxide (CO) has been used as a gaseous extinguishing agent. ₂ ) are mainly used.

However, in the case of carbon dioxide fire extinguishing facilities, it is necessary to take sufficient safety measures to prevent the choking accident caused by the injection of carbon dioxide gas, and accordingly, the carbon dioxide extinguishing facility installed in the electric room, the generator room, In case of fire, manual operation can be carried out manually through the on-site manual operation. In addition, after a sufficient time has elapsed for the remnants to evacuate by activating the timer while sounding an alarm or siren in the target compartment A method in which carbon dioxide is injected by performing an automatic start is generally used.

However, if this method is used, unconditionally delayed time may occur until the actual carbon dioxide gas is injected after the fire is detected by the fire detector even if the person is not in the protected area, and unnecessary fire damage may occur.

Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for detecting a fire in a fire detector, It is intended to provide a carbon dioxide safe fire extinguishing system that can prevent a person from being suffocated by a fire due to subsequent fire suppression or carbon dioxide remaining after restoration of a fire site even after the carbon dioxide is sprayed, or to prevent personal injuries.

The technical problems of the present invention are not limited to the above-mentioned technical problems, and other technical problems which are not mentioned can be understood by those skilled in the art from the following description.

According to another aspect of the present invention, there is provided a fire extinguishing system for a fire extinguishing system, the fire extinguishing system comprising: A smoke detector; An injection nozzle installed in the protection zone and configured to inject carbon dioxide; A carbon dioxide sensor installed in the protection zone and measuring a concentration of carbon dioxide remaining in the protection zone and delivering a signal corresponding to the measured carbon dioxide concentration, and a sensor installed in the protection zone to measure the concentration of oxygen remaining in the protection zone And an oxygen sensor for transmitting a signal corresponding to the measured concentration; A door lock installed on a door of the protection zone to lock or unlock the door; The control unit controls the door to be locked so that carbon dioxide is sprayed through the spray nozzle and the door lock is operated by determining whether or not a fire occurs in the protection zone based on a signal received from the fire sensor, When the concentration of carbon dioxide remaining in the protection zone exceeds a predetermined safety concentration of 2% based on a signal received from the concentration meter, the door of the protection zone is kept in a locked state. On the other hand, A control unit for controlling the door lock so as to release the door of the protection zone from the locked state when the concentration of carbon dioxide remaining in the zone is equal to or less than the predetermined safety concentration of 2%; A human body sensor for detecting a human body in the protection zone and transmitting the signal to the control unit; And a human body exit sensor configured to detect a human body entering and exiting the protection zone and deliver the signal to the control unit, wherein the control unit determines that a fire has occurred in the protection zone based on a signal from the fire detector It is possible to delay the injection of carbon dioxide through the injection nozzle when receiving a human body detection signal from the human body room detector or when a signal from at least one human body entering the protection area is received from the human body detection sensor, As shown in FIG.

According to the carbon dioxide safety fire extinguishing system according to an embodiment of the present invention, even if a fire detector detects a fire, it is possible to detect whether a passenger is present in the space inside or outside the room, thereby preventing unintentional injection of carbon dioxide, It is possible to prevent the occurrence of a choking accident.

In addition, according to the carbon dioxide safety fire extinguishing system according to an embodiment of the present invention, even after the carbon dioxide is sprayed, the fire extinguishment or the carbon dioxide remaining at the time of the fire site restoration can prevent the on- have.

BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the drawings recited in the detailed description of the invention below, a brief description of each drawing is provided.
1 is a schematic view for explaining a method of extinguishing by a carbon dioxide safe fire extinguishing system according to an embodiment of the present invention.
FIG. 2A is a conceptual view showing a carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention, and FIG. 2B is a detailed view of the integrated control module 300 shown in FIG. 2A.
3 is a schematic block diagram of a carbon dioxide safe extinguishing system 1000 in accordance with an embodiment of the present invention.
FIG. 4 is a schematic flowchart illustrating a method for safely extinguishing carbon dioxide by the carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention.
FIG. 5 is a schematic flowchart of a carbon dioxide safe extinguishing method by the carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described with reference to the accompanying drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive. In addition, embodiments of the present invention will be described below, but the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "indirectly connected" . Throughout the specification, when an element is referred to as " comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements.

1 is a schematic view for explaining a method of extinguishing by a carbon dioxide safe fire extinguishing system according to an embodiment of the present invention.

As shown in FIG. 1, the fire extinguishing method using the carbon dioxide safe fire extinguishing system according to an embodiment of the present invention is not limited to simply spraying carbon dioxide, which is a fire extinguishing gas, It is possible to judge the stability of fire by using dual human body detection, measurement of remaining carbon dioxide concentration, and detection of air escape from the body through detection of human body room and detection of human body entrance outside the protection area, It is possible to securely ensure the safety of field personnel or personnel performing fire suppression or field repair as well as occupants in protected areas in all situations.

Hereinafter, a fire extinguishing method using a carbon dioxide extinguishing system according to an embodiment of the present invention will be described in more detail.

FIG. 2A is a conceptual view schematically showing a carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention, and FIG. 2B is a detailed view of the integrated control module 300 shown in FIG. 2A.

2A, a carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention includes a fire detector 110, human body detectors 120 and 190, a concentration meter 130, a spray nozzle A door 160, a door lock 161, an air respiratory case 170, a carbon dioxide extinguishing liquid 180, and a P type second class A composite receiver 200, and an integrated control module 300. [ For reference, the integrated control module 300 may be implemented in the form of a panel, and may include a control unit 390 configured to integrally control the overall operation of the carbon dioxide safe fire extinguishing system 1000 .

In the present invention, the human body detectors (120, 190) double sensing the occupant to prevent indiscriminate injection of carbon dioxide, and even after the carbon dioxide is injected, the concentration sensor 130, the door lock 161, And the escape sensor 171 installed in the storage area 170 of the storage room 171, etc. to prevent the suffocation of the on-site personnel and the officials due to the carbon dioxide remaining in the protection area.

Hereinafter, a carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention will be described in detail with reference to the components of the carbon dioxide safe fire extinguishing system 1000 shown in FIG. 2A.

The fire detector 110 is installed in a building protection zone (for example, a ceiling of a protection zone) to detect the occurrence of a fire and transmit the sensed signal to the control unit 390. The smoke detector 110 may include at least one of a heat sensor 111 and a smoke detector 112 and is used extensively in a building, office, room, or the like in a building and operates when ambient temperature exceeds a predetermined rate of rise A differential-type spot-type sensor, or a warm-temperature-type spot-type sensor triggered when the ambient temperature becomes a predetermined temperature, or the like.

In addition, a photoelectric sensor suitable for the electric room can also be implemented as a fire detector 110. Depending on the characteristics of the protection zone, a differential type distribution type, a constant temperature sensing type, an ionization type, a compensation type six port type, It may be implemented as any one of various types of detectors such as a single alarm type, an ultraviolet type, an infrared type, and a flame detector.

The human body detectors 120 and 190 are configured to detect a human body present in the protection zone and transmit the result to the controller 390. [ The human body detectors 120 and 190 may include a human body detecting sensor 120 and a human body detecting sensor 190.

The human body room detector 120 may be implemented as a motion sensor installed on a wall inside a protection area and sensing a change in infrared radiation to detect a temperature difference using a surrounding temperature when a person is moving. With such a human room detector 120, it is possible to easily confirm whether or not there is a room occupant in the protection area. Accordingly, even if the fire detector 110 detects fire in the protection zone, if the human room detector 120 detects a human body present in the protection zone and transmits the signal to the controller 390, the control unit 390 It is possible to prevent the suffocation of the occupant by the carbon dioxide by delaying the injection of the carbon dioxide by judging that the occupant is present in the protection zone.

In some cases, even if at least one occupant is physically present in the enclosure, the occupant may not move, or the occupant may not be detected by the detector 120 due to certain obstacles in the enclosure, When the fire detector 110 detects a fire in the protection zone, when the controller 120 can not normally detect the change of the infrared radiation, the control unit 390 detects the presence of the occupant in the protection zone from the human room detector 120 It does not receive a signal that it exists, so it immediately carries out the injection of carbon dioxide, which leads to a serious and lethal phylactic accident to the actual survivors in the protected area.

In order to solve such a problem, the carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention may further include a human body access sensor 190 for detecting a human body entering and exiting the protection area. 2A, the human body access sensor 190 is disposed on the upper side of the door 160 outside the protection zone, detects a person (human body) entering and exiting through the door 160, and outputs the result To the control unit 390. Fig.

For example, the human body access sensor 190 not only detects the presence of a human body but also detects the moving direction of the human body. When the human body senses that the sensed human body has moved from outside to inside of the protection area, It is determined that a person has entered the protected area and the result is transmitted to the control unit 390. Similarly, if it is detected that the detected human body has moved outside from the inside of the protected area, it is determined that the person has left the protected area And transmit the result to the control unit 390.

Accordingly, even though the fire detector 110 detects that a fire has occurred in the protected area and receives a signal indicating that there is no occupant in the protected area by the human room detector 120, the controller 390 controls the human body detector 190 It is possible to reliably and fundamentally block the suffocating accidents caused by the injection of carbon dioxide.

The concentration meter 130 may be configured to be installed in the protection zone to measure the concentration of the gas (e.g., carbon dioxide or oxygen) in the protection zone and transmit the result to the control unit 390. The concentration meter 130 may include at least one of a carbon dioxide sensor 131 configured to measure the concentration of carbon dioxide in the protected area and an oxygen sensor 132 configured to measure the concentration of oxygen in the protected area.

In this regard, the present invention is characterized by preventing the smokers of the field personnel by measuring the residual amount of carbon dioxide remaining after the injection of carbon dioxide. Therefore, It is also possible to implement the system 1000.

According to another embodiment of the present invention, only the oxygen sensor 132 may be provided as the concentration meter 130 and the oxygen sensor 132 may be provided in the oxygen sensor 132. However, It will also be possible to implement the system 1000 to replace the oxygen concentration measured by the carbon dioxide concentration with the carbon dioxide concentration.

Further, according to a further embodiment of the present invention, by providing both the carbon dioxide sensor 131 and the oxygen sensor 132 as the concentration measuring instrument 130, it is possible to double the concentration of carbon dioxide in the protection zone, It becomes possible to acquire data on the concentration.

For reference, as the carbon dioxide sensor 131, an infrared-based carbon dioxide sensor configured to measure the amount of carbon dioxide based on a change in voltage generated when infrared rays are absorbed by carbon dioxide may be used. Such a concentration meter 130 can be used to easily determine whether the carbon dioxide concentration has fallen to a safe reference value for people (e.g., safety personnel, etc.) after being sprayed into the protected area.

Therefore, when the concentration of the remaining carbon dioxide in the protection zone obtained through the concentration meter 130 after the completion of the injection of the carbon dioxide exceeds the preset safety concentration of 2%, the control unit 390 controls the door The concentration of the remaining carbon dioxide in the protected area obtained through the concentration measuring device 130 after the completion of the injection of the carbon dioxide falls below the preset safety concentration of 2% The controller 390 can control the door lock mechanism 161 to release the door 160 from the locked state.

The spray nozzle 140 may be configured to spray carbon dioxide, which is a fire extinguishing gas, under the control of the control unit 390, installed in a protected area (for example, a ceiling of a protected area). The injection nozzle 140 is connected to the carbon dioxide extinguishing liquid 180 as shown in FIG. 2A and the carbon dioxide stored in the carbon dioxide extinguishing liquid 180 is guided through the spray nozzle 140 Area.

The control unit 390 is provided in the integrated control module 300 for integrally managing the present carbon dioxide safety fire extinguishing system 1000 and the control unit 390 is connected to the fire sensor 110, the human body room detector 120, And receives the sensing signal or the measurement signal from the sensor 190, the concentration meter 130 and the departure sensor 171 and controls the injection nozzle 140, the door lock 161 and the like based on the received signal.

Accordingly, the control unit 390 determines whether or not a fire has occurred in the protection zone based on the signal received from the fire sensor 110, and causes the carbon dioxide to be sprayed through the injection nozzle 140, After the completion of the injection of the carbon dioxide, the concentration of the carbon dioxide remaining in the protection zone is set to a predetermined safety concentration of 2% based on the signal received from the concentration meter 130 The door 160 of the protection zone is maintained in the locked state. On the contrary, if the concentration of the carbon dioxide remaining in the protection zone is less than the predetermined safety concentration of 2%, the door 160 of the protection zone is released from the locked state The door lock 161 can be controlled.

The door lock 161 may be installed on the door 160 to forcibly lock and unlock the door 160 of the guard area. The door lock 161 can be controlled by the controller 390 and can be set to the forced lock state in which the door 160 can not be opened from the outside. Thus, when the concentration of the remaining carbon dioxide sprayed into the protection zone does not fall below the predetermined safety concentration of 2%, the entrance and exit of the door 160 can be forcibly controlled for safety.

The air respiratory chamber 170 is installed outside the protection zone, and at least one air respirator may be installed therein. The escape sensor 171 is installed inside the air respiratory case 170 to sense the escape of the air respirator installed therein, and may be implemented as a mechanical push switch, an infrared sensor, or the like. According to the configuration of the air purifier box 170 including the departure sensor 171, when the user leaves the installed air purifier, the departure sensor 171 senses it and transfers it to the controller 390. Accordingly, when the concentration of the carbon dioxide remaining in the protection zone exceeds the preset safety concentration of 2%, the control unit 390 notifies the user that the air-ventilator has been removed from the air-ventilator box 170 by the release sensor 171, The door 160 of the protection zone can be released from the locked state by controlling the door lock 161 by determining that the air conditioner is in a safe state. Therefore, field personnel or fire officials can be put into the fire protection area prematurely so that subsequent fire suppression and field recovery can be carried out smoothly.

The opening and closing door 151 and the discharge fan 152 may be installed in a ventilation hole formed in the wall of the protection area. The opening and closing door 151 and the discharge fan 152 can operate under the control of the controller 390. The opening / closing door 151 is operated to close the ventilation hole when the carbon dioxide is injected, so that the fire extinguishing effect can be enhanced, and when the fire is suppressed due to the injection of the carbon dioxide, the ventilation opening is opened. Further, the exhaust fan 152 is configured to be operated after the injection of carbon dioxide is completed and the fire is suppressed, so that the carbon dioxide is rapidly discharged to the outside.

In addition, according to a further embodiment of the present invention, in addition to components of the carbon dioxide safe extinguishing system 1000 shown in FIG. 2A, a manual operation box, an RF transmitter, and an RF receiver may be further installed.

The manual operation box is installed outside the protection zone and operates to inject carbon dioxide into the protection zone by manual operation. In this case, even if carbon dioxide is injected by the operation of the manual operation box to ensure safety of the occupant, when the human body is detected by the human body detectors 120 and 190, the control unit 390 delays the injection of the carbon dioxide for a predetermined time .

The RF transmitter and the RF receiver are connected to the control unit 390 of the integrated control module 300 installed outside the protection zone based on the signals generated by the fire detector 110 and the human body detectors 120 and 190, . ≪ / RTI > Here, according to a further embodiment of the present invention, the radio transmission scheme of such a signal is performed in parallel with the wired transmission scheme, thereby improving the reliability of signal transmission.

The carbon dioxide safe fire extinguishing system 1000 shown in FIG. 2A is installed on the outer wall of the protection area and is installed adjacent to the door 160, for example, to integrate the overall operation, function, and operation of the system 1000 The integrated control module 300 may include a control unit 390 in the form of a chip for example and the integrated control module 300 may be provided in the integrated control module 300. [ 300 are preferably constructed as a panel type so that they can be easily installed on the outer wall of the protection zone and an exemplary configuration of the integrated control module 300 implemented in the form of a panel is shown in FIG. Will be described in more detail.

Additionally, as shown in FIG. 2A, various signals (e.g., signals from thermal sensor 111, signals from smoke detector 112, signals from the smoke detector 112, A signal from the sensor 120, a signal from the carbon dioxide sensor 131, a signal from the oxygen sensor 132, a signal from the release sensor 171, a signal from the human body access sensor 190, etc.) The present system 1000 can be implemented to be transmitted to the integrated control module 300 through the second-class compound receiver 200. [

For reference, the P type class 2 complex receiver 200 corresponds to a mechanism for directly receiving and transmitting a fire signal output from a detector or a receiving operation box or a signal output from a manual operation, and a high performance and high precision micro- Processor, and is configured to implement a stable system in the circuit configuration of a semiconductor / relay, as well as to immediately switch to a standby power source (e.g., a Ni-Cd battery) upon shutdown of the AC power source.

Referring to FIG. 2B, a schematic diagram of an integrated control module 300 configured as a panel type for comprehensively controlling the carbon dioxide-based extinguishing operation of the carbon dioxide safe fire extinguishing system 1000 is shown. The integrated control module 300 is provided with a controller 390 for controlling the temperature sensor 111, the smoke sensor 112, the human body sensor 120, the carbon dioxide sensor 131, the oxygen sensor 132, Means for receiving various signals related to detection or measurement from the sensor 171, human body sensor 190 and the like, means for visually displaying a value corresponding to the received signal to the user, 1000, etc.) may be provided on the surface of the integrated control module 300.

In the integrated control module 300, fire related sensing, detection, and measurement data may be stored in a storage unit (not shown), and the data may be stored in a thermal sensor 111, a smoke detector 112, And may include various data related to detection or measurement from the oxygen sensor 120, the carbon dioxide sensor 131, the oxygen sensor 132, the deviation sensor 171, the human body sensor 190, and the like.

Here, the storage unit may be a hard disk drive (HDD), a read only memory (ROM), a random access memory (RAM), an electrically erasable and programmable read only memory (EEPROM) a memory card, a compact flash (CF) card, a secure digital (SD) card, a smart media (SM) card, a multimedia card or a memory stick. .

The status indicator 310 indicates a design concentration calculation formula of CO ₂ (%) = (21 -) for the standard NFPA 12 (NFPA 12) and NFSC 106 (fire safety standard for carbon dioxide fire extinguishing equipment) in accordance with the _{O 2/21) × 100 (} %) ' corresponds to the means for visual indication of the degree of risk of the protected area on the basis of carbon dioxide concentration value inside the protected area. For example, the control unit 390 may control the concentration of carbon dioxide and / or the concentration of carbon dioxide displaced from the oxygen concentration from the concentration meter 130, for example, the carbon dioxide sensor 131 and / It is possible to activate (for example, turn on illumination) any one of the safety lamp 311, the warning lamp 312 and the hazard lamp 313 based on the state in the protection zone.

For example, when the concentration of carbon dioxide in the protection zone is less than 2% (oxygen concentration 20.58% or more), the control unit 390 determines that the protection zone is in a safe state, If the concentration of carbon dioxide in the protection zone is 4% or more (oxygen concentration is less than 20.16%), it is determined that the protection zone is a warning condition, and accordingly, the warning light 312, (For example, yellow light emission), and if the concentration of carbon dioxide in the protected area is more than 8% (oxygen concentration less than 19.32%), the protection zone is determined as a dangerous state, (For example, red light emission). Therefore, even outside the protected area, it is possible to clearly recognize the internal state, that is, the dangerous state depending on the carbon dioxide concentration, and accordingly, it is possible to appropriately cope with it.

The control unit 390 notifies the integrated control module 300 whether power is being supplied to the integrated control module 300 through the power indicator 321 and whether the emergency power is temporarily supplied to the integrated control module 300. [ And the like (322).

The control unit 390 can also display the carbon dioxide concentration in the protection zone received from the carbon dioxide sensor 131 in the carbon dioxide concentration display 331 and likewise the control unit 390 can display the carbon dioxide concentration in the protection zone The oxygen concentration can be displayed on the coral concentration display 332 or replaced with the carbon dioxide concentration from the received oxygen concentration and displayed on the carbon dioxide sensor 131. [

In addition, the controller 390 can visually express the thermal sensation by receiving a thermal sensation result in the sanitary area from the thermal sensor 111 and activating the thermal sensor indicator 351 when the thermal sensation is within the sanitary area. Likewise, the control unit 390 can visually express the smoke detection result in the protection zone from the smoke detector 112 and activate the smoke detector indicator 352 when smoke is detected within the protection zone, When a signal indicating that a human body is sensed in the protection zone is received from the human body sensor detector 120, the human body sensor indicator 353 can be visually displayed. In addition, the control unit 390 can activate the ventilator attaching indicator 354 based on whether the ventilator is disengaged by the escape sensor 171 or not.

In addition, the controller 390 may be located on the upper side of the door 160 outside the protected area to count occupant information in the protected area based on a signal from the human body detector 190 that detects the entry / exit of the human body, The result can be displayed on the attendance counter 341. The occupant counter 341 can display the number of persons in the protection area as Arabic numerals, thereby enabling the presence or absence of the occupant and the number of persons inside the protection area to be easily confirmed.

In this regard, according to various embodiments of the present invention, means for automatically or manually switching the operating mode for counting occupant outfits, for example occupant counting mode switcher 342, may be further provided.

For example, in the case of the occupant counting automatic mode, a person who enters or departs from the protection zone based on the operation of the human body access detector 190 and the control unit 390 is automatically detected and counted, (341). In this case, the control unit 390 preferably controls the manual occupant counting operation unit 343 to be deactivated.

In the case of the occupant counting manual mode, the person entering the protection zone presses the " + " button of the manual occupant counting operation unit 343, - " button, and the control unit 390 is configured to manually count occupants in the protected area based on such user button depression operation. In this case, the control unit 390 controls the human body access detector 190 to be inactivated or activates the detection by the human body access sensor 190, and determines the value of the occupant counting by the sensing operation and the value of the occupant counting by the manual operation By comparison, the data accuracy with respect to the number of occupants can be further improved.

Further, according to a further embodiment of the present invention, there is a case where the opening of the door 160 is switched from the open mode to the manual mode, or conversely from the manual mode to the automatic mode, (360) may be additionally provided in the integrated control module (300). When the door is opened in the automatic mode, the opening and closing of the door 160 can be controlled only by the control of the controller 390, and it is impossible to open and close the door by a person. In addition, when the door opening is implemented in the passive mode, opening and closing of the door 160 can be controlled by manual operation of a person. Here, information on whether the door 160 is opened or closed can be visually displayed outside through the door open / close indicator 380.

In addition, according to a further embodiment of the present invention, a recovery button 370 for resetting the fire related data, etc., may be additionally provided in the integrated control module 300.

3 is a schematic block diagram of a carbon dioxide safe extinguishing system 1000 in accordance with an embodiment of the present invention.

The CO ₂ / O ₂ sensor, the CO ₂ / O ₂ sensor, the A / D converter circuit, the pump, the pump power source, the power source, the battery 24V, The integrated control module 300 is capable of driving the integrated control module 300 and the P type class 2 complex receiver 200 by supporting components such as a CO ₂ concentration lamp (Hazard), CO ₂ concentration lamp (warning), CO ₂ concentration lamp (safety), door lock, CO ₂ emission delay, heat sensor lamp, smoke detector lamp, respirator detachment lamp, A smoke sensor signal, a respirator detachment signal, a human body detection signal, a human body detection signal, an automatic / manual signal, an automatic recovery signal, a door lock signal, And the like.

The concentration of carbon dioxide in the protection zone is transferred to the control unit 390 of the integrated control module 300 by the carbon dioxide sensor 131 or the oxygen concentration in the protection zone by the oxygen sensor 132, ) Or the oxygen concentration display 332, respectively.

Information on a person entering or exiting the protection zone by the human body access detector 190 may be transmitted to the control unit 390 of the integrated control module 300 and displayed through the occupant counter 341.

The method for safely extinguishing carbon dioxide using the carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention will now be described in more detail with reference to the accompanying drawings. FIG. 4 is a schematic flowchart for explaining a carbon dioxide safe fire extinguishing method by the carbon dioxide safe fire extinguishing system 1000 according to an embodiment of the present invention. FIG. 5 is a schematic view illustrating a carbon dioxide safe extinguishing system 1000 ) Is a schematic flowchart of a safe carbon dioxide extinguishing method.

4, the method for safely extinguishing carbon dioxide according to an embodiment of the present invention includes a fire occurrence sensing step S410, a human body room sensing and human body access confirmation step S420, a carbon dioxide injection step S430, (Step S440), a residual carbon dioxide concentration measurement step S450, an air-respiratory separation detection step S460, and a door lock release step S470. For reference, it is apparent that each of the steps shown in Fig. 4 is merely exemplary steps for explaining the present carbon dioxide safety extinguishing method, and that additional steps other than the steps shown can be performed.

In the fire detection step S410, it is detected whether a fire has occurred in the protection zone by the fire detector 110 installed in the building, for example, the heat sensor 111 and / or the smoke sensor 112 And transmits it to the control unit 390. [

The human body room detection and human body accessing step S420 is a step of checking whether the human body is reattached by the human body room detector 120 installed in the protection area and the human body room detector 190 installed on the door 160 outside the protection area The presence or absence of the occupant and the occupant information of the occupant are transmitted to the controller 390, respectively. When it is determined from the human body room detector 120 that there is an occupant in the protective area, the controller 390 does not proceed directly to the carbon dioxide injection step, which is the next step, while the human body room detector 120 alerts the user Delay the injection of carbon dioxide for a certain time until it can not be detected.

In addition, if at least one person is detected to enter the protected area from the human body access detector 190, even though the presence of the occupant is not detected in the protected area from the human occupancy detector 120, the controller 390 also detects the presence of a fire alarm And the carbon dioxide injection is delayed for a certain time. Thereby, if the occupant is not moving, or if the occupant is not detected by the sensor 120 by the shield in the protection zone, or if the change of infrared radiation due to high temperature and smoke can not be detected properly, the ignorant injection of carbon dioxide It is possible to prevent the victim's suffocation by accident.

The carbon dioxide injection step S430 is performed only when it is detected that a fire has occurred in the inside of the protection zone and no human body inside is detected and there is no person entering the protection zone, The starting device is operated to start the carbon dioxide extinguishing liquid 180 so that carbon dioxide is injected into the protection zone through the injection nozzle 140.

When a signal for injecting carbon dioxide is delivered to the controller 390 from the outside of the protected area through the manual operation box, the human body detector 120 or the human body detector 190 detects that the human body is not present inside the controller If the human body sensor 120 detects the occupant present inside the human body detector or if the human body sensor 190 indicates that at least one person enters the protection area, After delaying the injection of carbon dioxide for a certain period of time through the delay device, the starter can be operated to inject carbon dioxide. Thereby, the occupant (s) present in the protected area can secure sufficient time for evacuation.

The door lock step S440 may be performed simultaneously with the carbon dioxide injection step or may be performed in advance. In this step, the controller 390 controls the door lock 161 to forcibly lock the door 160 of the protection zone. Thus, when carbon dioxide starts to be sprayed, safety can be maximized by preventing the air from being exterminated from the outside through the protection door 160, except when the air respirator is detached.

In addition, the opening and closing door 151 installed in the ventilation opening of the protection zone is operated to close the ventilation opening, thereby enhancing the fire extinguishing effect on the protection area. However, after the carbon dioxide is injected and the fire suppression is performed, the opening and closing door 151 is re-operated to open the ventilation hole and operate the exhaust fan 152 to quickly discharge the remaining carbon dioxide to the outside.

In the remaining carbon dioxide concentration measuring step (S450), the concentration of carbon dioxide present in the protection zone is measured after the injection of carbon dioxide is completed. To this end, the carbon dioxide sensor 131 installed in the protection zone measures the concentration of carbon dioxide and transmits the result to the control unit 390, or the oxygen sensor 132 installed in the protection zone measures the oxygen concentration, To the control unit 390, the control unit can replace the received oxygen concentration with the carbon dioxide concentration.

The control unit 390 maintains the door 160 of the protection zone in the locked state by the door lock 161 when the concentration of the carbon dioxide remaining in the protection zone exceeds the predetermined safety concentration of 2% On the contrary, when the concentration of carbon dioxide remaining in the protection zone is less than the preset safety concentration of 2%, the door 160 of the protection zone is released from the locked state by the door lock 161, To enter the protected area.

In step S460, the escape sensor 171 provided in the air-respiratory case 170 senses the escape of the air-respirator installed in the air-respiratory case 170 and outputs a signal to the control unit 390 . In this case, the door lock releasing step as the next step can proceed immediately.

In the door unlocking step S470, when the escape of the air respirator is detected through the previous step, it is determined that the person (s) wears the air respirator. Even if the concentration of the carbon dioxide remaining in the protection area exceeds the set reference value, Can be released from the locked state. The control unit 390 receives the signal from the release sensor 171 installed in the air respirator box 1760 and controls the door lock 161 to release the door 160 of the protection zone from the locked state.

As described above, according to the carbon dioxide safe fire extinguishing system according to the embodiment of the present invention, even if a fire sensor detects a fire, it is possible to detect whether a passenger is present inside the space by doubly detecting the inside or the outside of the space, It is possible to prevent the suffocating accident caused by the carbon dioxide of the occupant.

In addition, according to the carbon dioxide safety fire extinguishing system according to an embodiment of the present invention, even after the carbon dioxide is sprayed, the fire extinguishment or the carbon dioxide remaining at the time of the fire site restoration can prevent the on- have.

Meanwhile, the various embodiments described herein may be implemented by hardware, middleware, microcode, software, and / or a combination thereof. For example, various embodiments may include one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays ), Processors, controllers, microcontrollers, microprocessors, other electronic units designed to perform the functions described herein, or a combination thereof.

Also, for example, various embodiments may be stored or encoded in a computer-readable medium including instructions. The instructions stored or encoded in the computer-readable medium may cause a programmable processor or other processor to perform the method, for example, when the instructions are executed. The storage medium may be any available media that can be accessed by a computer. By way of example, and not limitation, such computer-readable media can comprise RAM, ROM, EEPROM, CD-ROM or other optical disk storage media, magnetic disk storage media or other magnetic storage devices, Or any other medium that can be used to carry or store data in the form of data structures.

Such hardware, software, firmware, etc. may be implemented within the same device or within separate devices to support the various operations and functions described herein. Additionally, components, units, modules, components, etc. described in the present invention as " parts " may be implemented separately or together as separate but interoperable logic devices. The description of different features for modules, units, etc. is intended to emphasize different functional embodiments and does not necessarily imply that they must be implemented by individual hardware or software components. Rather, the functionality associated with one or more modules or units may be performed by separate hardware or software components, or may be incorporated within common or separate hardware or software components.

Although acts in a particular order are shown in the figures, it should be understood that these acts are performed in the specific order shown, or in a sequential order, or that all illustrated acts need to be performed to achieve the desired result . In any environment, multitasking and parallel processing may be advantageous. Moreover, the division of various components in the above-described embodiments should not be understood as requiring such a distinction in all embodiments, and the components described may generally be integrated together into a single software product or packaged into multiple software products It should be understood.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: fire detector 111: heat detector
112: Smoke detector 120: Human body detector
130: Concentration meter 131: Carbon dioxide sensor
132: oxygen sensor 140: injection nozzle
151: opening / closing door 152: exhaust fan
160: Door 161: Door lock
170: air respirator box 171: release sensor
180: carbon dioxide extinguishing liquid 190: human body sensor
200: P type Class 2 complex receiver 300: Integrated control module
390:

Claims (1)

As a carbon dioxide safe fire extinguishing system 1000,
A fire detector (110) installed in a protected area within a building and configured to detect a fire occurrence and deliver a signal, the fire detector (110) comprising at least one of a heat sensor (111) and a smoke detector (112);
An injection nozzle (140) installed in the protection zone and configured to inject carbon dioxide;
A carbon dioxide sensor 131 installed in the protection zone and measuring a concentration of carbon dioxide remaining in the protection zone and delivering a signal corresponding to the measured carbon dioxide concentration, and a carbon dioxide sensor 131 installed in the protection zone, And at least one of a carbon dioxide and oxygen sensor (132) for measuring a concentration of oxygen and delivering a signal corresponding to the measured concentration;
A door lock (161) installed on a door (160) of the protection zone to lock or unlock the door (160);
The control unit 160 determines whether or not a fire has occurred in the protection zone based on the signal received from the fire sensor 110 and causes the carbon dioxide to be injected through the injection nozzle 140 and operates the door 160 After the completion of the injection of the carbon dioxide, the concentration of the carbon dioxide remaining in the protection zone exceeds a predetermined safety concentration of 2% based on the signal received from the concentration meter 130 The door 160 of the protection zone is maintained in the locked state and if the concentration of carbon dioxide remaining in the protection zone is equal to or less than the predetermined safety concentration of 2% A control unit (390) for controlling the door lock (161) to release the door lock (161);
A human body room detector 120 for sensing a human body inside the protection area and transmitting the signal to the controller 390; And
A human body access sensor 190 configured to detect a human body entering and exiting the protection zone and transmitting the signal to the control unit 390,
Lt; / RTI >
The control unit 390,
Even if it is determined that a fire has occurred in the protection zone based on a signal from the fire detector 110, when a human body detection signal is received from the human body room detector 120, Further comprising means for delaying the injection of carbon dioxide through the injection nozzle (140) when a signal is received indicating that at least one inside chamber is present,
Carbon dioxide safety extinguishing system (1000).

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