JP2006122378A - Low oxygen concentration fire prevention system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the fire-preventive properties and safety of a target space by immediately adjusting the oxygen concentration in the target space. <P>SOLUTION: The subject low oxygen concentration fire prevention system is for preventing a fire in the target space 1 by lowering the oxygen concentration in the target space 1. The system comprises a nitrogen gas supply line 130 for feeding nitrogen-enriched gas to the target space 1, an oxygen supply line 140 for feeding oxygen-enriched gas to the target space 1, and a nitrogen-enriched gas tank 131, an oxygen-enriched gas tank 142 and storage tanks 125 and 126, and the like for storing nitrogen-enriched gas or oxygen-enriched gas mounted on at least either the nitrogen gas supply line 130 or the oxygen supply line 140. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a system for adjusting the oxygen concentration of a target space, and more particularly to a low oxygen concentration fire prevention system that performs fire prevention of a target space by adjusting the oxygen concentration to a low oxygen concentration.

  2. Description of the Related Art Conventionally, a low oxygen concentration fire prevention system has been proposed that can prevent a fire in this space by reducing the oxygen concentration in a space where humans do not enter and exit. Such a conventional low oxygen concentration fire prevention system is configured to include, for example, an inert gas supply device that supplies an inert gas to the target space, and an outside air supply device that supplies outside air to the target space. (For example, refer to Patent Document 1).

  When the human is absent, the target space is filled with an inert gas by using the inert gas supply device to make the target space an incombustible atmosphere. When the human is in the room, the external space is used to supply the target space. By supplying outside air, the target space was made to have an oxygen concentration that allows humans to survive. According to such a system, when an incombustible atmosphere is used, a fire can be prevented from occurring in the target space. When the oxygen concentration is such that humans can survive, there is no health problem even if a human enters the target space. There is an advantage that it does not occur.

JP 2003-102858 A

  However, in the conventional low oxygen concentration fire prevention system, the inert gas supplied from the inert gas supply device and the outside air supplied from the outside air supply device are simply introduced directly into the target space. There was a bug. For example, in a conventional low oxygen concentration fire prevention system, when it is desired to switch the oxygen concentration in a target space from a normal oxygen concentration to a low oxygen concentration, an inert gas supply device is started, and the inert gas supply device starts from oxygen. The separated inert gas such as nitrogen was sent to the target space. However, when the inert gas supply device is started or the generation or delivery of inert gas is started after the situation where it is desired to switch to a low oxygen concentration, it takes time to start or generate the oxygen. The density adjustment time is relatively long. Conversely, when it is desired to return from a low oxygen concentration to a normal oxygen concentration, it takes a long time to start the external air supply device, generate oxygen, etc., and therefore the oxygen concentration adjustment time is relatively long. .

  Thus, when the adjustment time of oxygen concentration becomes long, the time which can hold | maintain object space by required concentration for this adjustment time becomes short. Therefore, since the time that can be maintained at a low oxygen concentration is shortened, the oxygen concentration can be reduced to a level that is safe for the human body if the fire prevention environment cannot be secured sufficiently or if a person enters the low oxygen concentration space. Since it takes a long time to return, there is a possibility that sufficient safety cannot be ensured. In addition, as the oxygen concentration adjustment time becomes longer, the operation time of various devices such as a compressor for supplying air also becomes longer, so there is a problem that the running cost of the various devices increases.

  The present invention has been made in view of the above, and by making it possible to quickly adjust the oxygen concentration, it is possible to improve fire resistance and safety, reduce the running cost of the apparatus, and the like. An object of the present invention is to provide a low oxygen concentration fire prevention system.

  In order to solve the above-described problems and achieve the object, the low oxygen concentration fire prevention system according to claim 1 is a low oxygen concentration which performs fire prevention of the target space by reducing the oxygen concentration of the target space. A fire prevention system, an inert gas supply line for supplying an inert gas to the target space, an oxygen supply line for supplying oxygen to the target space, and the inert gas supply line or the oxygen supply It is provided in at least one of the lines, and has a storage means for storing the inert gas or the oxygen.

  The low oxygen concentration fire prevention system according to claim 2 is the low oxygen concentration fire prevention system according to claim 1, wherein the storage means is at least one of a ceiling portion, a floor portion, or a wall surface portion of the target space. It is characterized by being arranged in one.

  Moreover, the low oxygen concentration fire prevention system of Claim 3 WHEREIN: The low oxygen concentration fire prevention system of Claim 1 or 2 WHEREIN: The said storage means has been arrange | positioned in the front chamber provided adjacent to the said object space. It is characterized by that.

  A low oxygen concentration fire prevention system according to claim 4 is the low oxygen concentration fire prevention system according to any one of claims 1 to 3, wherein at least a part of the inert gas supply line and the oxygen supply line. The storage means is provided as the storage means.

  Moreover, the low oxygen concentration fire prevention system according to claim 5 is the low oxygen concentration fire prevention system according to any one of claims 1 to 4, further comprising a humidity adjusting means for adjusting the humidity of the target space. It is characterized by that.

  The low oxygen concentration fire prevention system according to claim 6 is the low oxygen concentration fire prevention system according to claim 5, wherein the inert gas, the oxygen, or the air for generating the inert gas or oxygen is used. A pressurizing unit that pressurizes the water, the pressurizing unit is connected to the humidity adjusting unit, and the condensed water generated during pressurization in the pressurizing unit can be introduced as humidifying water in the humidity adjusting unit. Features.

  According to the low oxygen concentration fire prevention system according to the present invention, it is possible to supply inert gas and oxygen without waiting for the start-up time of various devices necessary for adjusting the oxygen concentration, or inert gas supplied by various devices. By supplying inert gas and oxygen from the storage means in addition to gas and oxygen, the oxygen concentration can be adjusted quickly. Therefore, the effective time during which the oxygen concentration in the target space can be maintained at the required oxygen concentration can be extended, and the fire resistance and safety of the target space can be improved. Moreover, since minute oxygen concentration fluctuations associated with humans entering and leaving the target space can be immediately absorbed, the fire resistance and safety of the target space can be further enhanced. Furthermore, by shortening the density adjustment time, it is possible to shorten the operation time of various apparatuses necessary for the density adjustment, and to reduce the running cost of the apparatus. Also, by providing the storage means, the amount of inert gas and oxygen supplied to the target space can be controlled more accurately than when only various devices such as an inert gas supply device are provided. The concentration can be controlled with higher accuracy than in the past.

  In addition, according to the low oxygen concentration fire prevention system according to the present invention, since inert gas and oxygen can be supplied from the storage means arranged on the ceiling, floor, or wall surface of the target space, the peripheral space of the target space can be reduced. It can be effectively used as a storage space for storage means. In addition, since the inert gas and oxygen can be supplied from the vicinity of the target space, the supply of these inert gas and oxygen can be performed more rapidly.

  Moreover, according to the low oxygen concentration fire prevention system according to the present invention, since the storage means is arranged in the front chamber of the target space, the front chamber can be effectively used as the installation space for the storage means. In addition, since the inert gas and oxygen can be supplied from the vicinity of the target space, the supply of these inert gas and oxygen can be performed more rapidly.

  Further, according to the low oxygen concentration fire prevention system according to the present invention, since the storage means is the storage means of the inert gas supply line or the oxygen supply line, the internal space of the storage means can be effectively used as the storage means.

  In addition, according to the low oxygen concentration fire prevention system according to the present invention, the humidity of the target space can be adjusted by the humidity adjusting means. Therefore, by preventing the target space from being overdried, the combustibility inside the target space is suppressed. , Fire resistance can be improved. Furthermore, the preservability of the stored items managed in the target space can be improved, or the health state of a person entering the target space can be maintained.

  Further, according to the low oxygen concentration fire prevention system according to the present invention, the condensed water generated at the time of pressurization in the pressurizing means is used as the humidifying water in the humidity adjusting means, so the humidifying water for the pressurizing means is supplied separately. Therefore, it is possible to reduce the cost of humidity adjustment.

  Embodiments of a low oxygen concentration fire prevention system according to the present invention will be described below in detail with reference to the accompanying drawings. First, [I] the basic concept of the present invention will be described, then [II] an embodiment of the present invention will be described, and [III] Finally, a modification to the embodiment of the present invention will be described.

[I] Basic concept of the present invention First, the basic concept of the present invention will be described. The present invention relates to a low oxygen concentration fire prevention system that performs fire prevention in a target space by reducing the oxygen concentration in the target space.

  Here, the target space is basically arbitrary, but for example, data centers, museums, museums, cultural property storage facilities, valuables warehouses, etc. where there is a strong demand for avoiding damage due to fire extinguishing in the event of a fire. Or a place where it is difficult to install a normal fire prevention facility such as an electric room of a super high-rise tower, or a facility that stores valuables that want to prevent deterioration by maintaining a low oxygen concentration.

  The low oxygen concentration is a concept that basically includes all oxygen concentrations lower than the oxygen concentration in the general atmosphere (about 21%, hereinafter referred to as “normal oxygen concentration”). In the following embodiments, there are two levels of low oxygen concentration, namely, (1) an oxygen concentration that is capable of human survival and is low in flammability because it is lower than normal oxygen concentration (for example, oxygen concentration) (2) Although it is difficult for humans to survive, the oxygen concentration is lower than the non-combustible viable oxygen concentration, so the combustibility is much lower. An example of switching to an oxygen concentration (for example, an oxygen concentration of 12%, hereinafter referred to as “incombustible oxygen concentration”) will be described.

  In order to adjust the oxygen concentration in this way, in the present invention, various gases are introduced into the target space. Specifically, when reducing the oxygen concentration, an inert gas or a gas containing an inert gas at a high concentration is introduced. Here, although the kind of inert gas is arbitrary, the example using nitrogen gas shall be demonstrated below, nitrogen gas or. A gas containing nitrogen gas at a higher concentration than usual is referred to as “nitrogen-enriched gas”. In addition, when increasing the oxygen concentration, a gas containing outside air, oxygen, or oxygen at a higher concentration than usual, or a gas having an oxygen concentration higher than the oxygen concentration in the target space is introduced. Hereinafter, oxygen or a gas containing oxygen at a high concentration is referred to as “oxygen-enriched gas”. In addition, the inert gas in the claim is a concept including a nitrogen-enriched gas, and the oxygen in the claim is a concept including an oxygen-enriched gas and outside air.

  Here, one of the features of the present invention is that a storage means for storing an inert gas or oxygen is provided. By storing the inert gas or oxygen by this storage means, the inert gas is supplied from the storage means when it is desired to adjust to a low oxygen concentration, and the oxygen is supplied from the storage means when it is desired to return to the normal oxygen concentration. Supply. As a result, the inert gas and oxygen can be supplied without waiting for the start-up time of various devices necessary for adjusting the oxygen concentration, or from the storage means in addition to the inert gas and oxygen supplied by various devices. By supplying an inert gas or oxygen, the oxygen concentration can be adjusted quickly. About the arrangement position and structure of this storage means, various variations according to the situation can be taken as described later.

  Another feature of the present invention is that humidity adjusting means for adjusting the humidity of the target space is provided. By performing humidity adjustment with this humidity adjusting means, it is possible to prevent combustibility and improve fire prevention efficiency by preventing the target space from being overdried.

[II] Embodiment of the Present Invention Hereinafter, an embodiment of a low oxygen concentration fire prevention system according to the present invention will be described. In this embodiment, after describing the overall configuration of the low oxygen concentration fire prevention system and the like, the oxygen concentration adjustment performed by the low oxygen concentration fire prevention system will be described.

(Configuration of low oxygen concentration fire prevention system)
FIG. 1 is a system diagram showing the overall configuration of the low oxygen concentration fire prevention system according to the present embodiment. In FIG. 1, an oxygen concentration adjustment unit 100 and a fire extinguishing unit 200 are disposed in the vicinity of the target space 1.

  Among these, the target space 1 is configured as a closed space surrounded by wall surfaces on the top, bottom, left, and right. A ceiling back space 2 is provided above the target space 1 with a ceiling wall therebetween, and a floor space 3 is provided below the target space 1 with a floor plate therebetween. The ceiling back space 2 and the underfloor space 3 correspond to a ceiling portion and a floor portion in the claims. In the ceiling back space 2 and the underfloor space 3, storage tanks 125 and 126, which will be described later, are respectively disposed.

Further, inside the target space 1, an oxygen sensor for measuring the oxygen concentration inside the target space 1, a carbon monoxide sensor for measuring the carbon monoxide (CO) concentration, carbon dioxide (CO ₂ ). A carbon dioxide sensor for measuring the concentration, a humidity sensor for measuring the humidity, a human sensor for detecting the presence or absence of a human, and a fire detector for detecting the presence or absence of a fire are arranged (note that Hereinafter, these various sensors will be collectively referred to as “sensor 4” as necessary, and the sensors 4 are collectively shown in FIG. 1). Further, inside the target space 1, there are a pressure relief port 5 for partially releasing the pressure when the target space 1 is over-pressurized, and a stirrer 6 for circulating the internal air of the target space 1. Is provided.

  A front chamber 10 adjacent to the target space 1 is provided on one side of the target space 1. The front chamber 10 is a buffer space that relaxes inflow and outflow of gas in the target space 1 when a person or an object enters or leaves the target space 1. The front chamber 10 corresponds to the storage means in the claims. A first door 11 is provided on the outer wall of the front chamber 10, and a second door 12 is provided between the front chamber 10 and the target space 1, and the first door 11 and the second door A person or an object can enter or leave the target space 1 through the door 12. Here, the first door 11 has an oxygen concentration display device 13 for displaying the oxygen concentration inside the target space 1, an entrance management system 14 for managing the presence or absence of a person in the front chamber 10 or the target space 1. A release damper 15 is provided that partially releases the pressure when the front chamber 10 is over-pressurized.

  The oxygen concentration adjusting unit 100 is for adjusting the oxygen concentration of the target space 1 and is configured as a unit in which various devices for adjusting the oxygen concentration are accommodated in one housing 110. . Specifically, the housing 110 is configured to accommodate the common line 120, the nitrogen gas supply line 130, the oxygen supply line 140, the humidity adjustment line 150, and the control device 160.

  Here, the housing 110 functions as a protective structure that protects each part of the oxygen concentration adjusting unit 100, stores oxygen-enriched gas therein, and stores the oxygen-enriched gas in the target space 1 as necessary. It functions as a storage means for supplying to the container. That is, the housing | casing 110 respond | corresponds to the accommodating means and storage means in a claim. The casing 110 is provided with a release damper 111. When the casing 110 is over-pressurized, a part of the pressure is released to the outside through the release damper 111.

  The common line 120 is configured by sequentially arranging a valve V1, a compressor 121, an air tank 122, and an oxygen / nitrogen separation filter 123 in a pipe P1 extending from the outside to the inside of the oxygen concentration adjusting unit 100. Among these, the compressor 121 pressurizes the outside air taken in from the end of the pipe P1, and corresponds to the pressurizing means in the claims. The air tank 122 is a storage unit that stores the outside air pressurized by the compressor 121. By storing the outside air in this way, the outside air can be stably supplied to the subsequent stage. The oxygen / nitrogen separation filter 123 is oxygen / nitrogen separation means that separates oxygen and nitrogen from the outside air supplied from the air tank 122 to generate a nitrogen-enriched gas and an oxygen-enriched gas. The specific configuration of the oxygen / nitrogen separation filter 123 is arbitrary. For example, the oxygen / nitrogen separation filter 123 includes an oxygen-enriched film, and a difference in the rate at which oxygen molecules and nitrogen molecules dissolve in the oxygen-enriched film. To separate oxygen and nitrogen from the outside air. The oxygen concentration in the nitrogen-enriched gas or oxygen-enriched gas thus generated is arbitrary, but in order to adjust the oxygen concentration quickly, it is usually preferable to have a concentration away from the oxygen concentration, for example, nitrogen The oxygen concentration of the enriched gas is preferably about 11%, and the oxygen concentration of the oxygen enriched gas is preferably about 30%.

  A pipe P2 reaching the target space 1 is drawn from between the air tank 122 and the oxygen / nitrogen separation filter 123. In the pipe P2, a valve V2, a valve V3, and a flow meter 124 are sequentially arranged. In addition, a valve V4 and a storage tank 125 are sequentially arranged in the pipe P3 that branches from the pipe P2 and reaches the ceiling space 2 of the target space 1, and the storage tank 125 has an inside of the target space 1. The arranged valve V5 is connected. In addition, a valve V6 is arranged in a pipe P4 that branches from the pipe P2 and reaches the target space 1. Further, a valve V7 and a storage tank 126 are sequentially arranged in the pipe P5 branched from the pipe P2 and reaching the underfloor space 3 of the target space 1, and the storage tank 126 is arranged in the target space 1. Valve V8 is connected. Here, the storage tank 125 and the storage tank 126 correspond to storage means in the claims. A pipe P6 leading to the target space 1 is drawn from between the valve V1 and the compressor 121, and a valve V9 is arranged in the pipe P6.

Moreover, the nitrogen gas supply line 130 reduces the oxygen concentration of the said target space 1 by supplying nitrogen enriched gas to the target space 1, and respond | corresponds to the inert gas supply line in a claim. Specifically, the nitrogen gas supply line 130 is configured to include a nitrogen enriched tank (N ₂ enriched tank in FIG. 1) 131 and a valve V10 at the subsequent stage of the oxygen / nitrogen separation filter 123 in the pipe P1. ing. Here, the nitrogen enrichment tank 131 is for storing the nitrogen enriched gas generated by the oxygen / nitrogen separation filter 123, and corresponds to the storage means in the claims. The nitrogen-enriched gas stored in the nitrogen-enriched tank 131 can be introduced into the above-described pipe P2 through the pipe P7. Further, a pipe P8 is connected to the valve V10, and a valve V12 is connected to the pipe P8. The valve V12 is arranged in a pipe P10 drawn into the front chamber 10 from the outside, and a valve V13 and a blower 132 are further arranged in the pipe P10.

The oxygen supply line 140 increases oxygen concentration in the target space 1 by supplying oxygen to the target space 1. Specifically, the oxygen supply line 140 is drawn from the oxygen / nitrogen separation filter 123 and supplied to the pipe P7. A pressurizing device 141, a valve V14, an oxygen enrichment tank (O ₂ enrichment tank in FIG. 1) 142, and a valve V15 are sequentially arranged on the pipe P11. The pressurizing device 141 is a pressurizing unit that pressurizes the oxygen-enriched gas generated by the oxygen / nitrogen separation filter 123. The oxygen enrichment tank 142 stores the oxygen enriched gas pressurized by the pressurizing device 141, and corresponds to the storage means in the claims. A pipe P12 is drawn out from the valve V14.

  The humidity adjustment line 150 is for adjusting the humidity of the target space 1 and corresponds to the humidity adjusting means in the claims. Specifically, the humidity adjustment line 150 is configured by sequentially arranging a humidity adjustment device 151 and a valve V16 on the pipe P7. The humidity adjusting device 151 adjusts the humidity of the target space 1 by supplying humidified or dehumidified air to the target space 1. Here, a compressor 121 is connected to the humidity adjusting device 151 via a pipe P <b> 13, and condensed water generated when the compressor 121 condenses outside air can be supplied to the humidity adjusting device 151. In the humidity adjustment device 151, humidification is possible using the condensed water supplied from the compressor 121.

  The control device 160 is a control means for controlling each part of the oxygen concentration adjusting unit 100 and the fire extinguishing unit 200, and is electrically connected to these parts (in FIG. 1, the electrical connection is indicated by a dotted line). ). The specific configuration of the control device 160 is arbitrary. For example, the control device 160 includes a transmission / reception interface that transmits and receives signals to and from each unit, a CPU (Central Processing Unit), and a program that operates on the CPU.

  The fire extinguishing unit 200 is for extinguishing a fire that has occurred in the target space 1, and specifically includes a fire extinguishing device 201 and a fire extinguishing device control unit 202. Among these, the fire extinguisher 201 is connected to the target space 1 via the pipe P14 and the valve V17, and discharges a fire extinguishing gas and a fire extinguishing agent into the target space 1. The fire extinguisher control unit 202 is electrically connected to the fire extinguisher 201 and controls the release of fire extinguishing gas and extinguishing agent by the fire extinguishing apparatus 201.

(Oxygen concentration adjustment)
Next, the oxygen concentration adjustment performed using the thus configured low oxygen concentration fire prevention system will be described. This adjustment is mainly performed automatically under the control of the control device 160. In the following description, it is assumed that a device that is not particularly described is in a stopped state, and a valve that is not particularly described is in a closed state. The control of the control device 160 is performed with reference to the oxygen concentration in the target space 1 sensed by the sensor 4. FIG. 2 is a graph showing a change in oxygen concentration in the target space 1, where the horizontal axis indicates time and the vertical axis indicates the oxygen concentration in the target space 1.

  First, the adjustment at the normal time (time T0 to T1 in FIG. 2) will be described. The normal time is, for example, a time zone in which humans are expected to enter or leave the target space 1 and a low necessity for fire prevention. For example, a daytime zone is applicable. In this case, the outside air is circulated in order to adjust the oxygen concentration in the target space 1 to the normal oxygen concentration. Specifically, the control device 160 introduces the outside air into the compressor 121 by opening the valves V1, V2, and V6. In addition, the control device 160 starts the compressor 121, compresses the introduced air, and stores the compressed air in the air tank 122. The outside air stored in this way is introduced into the target space 1 via the pipes P2 and P4. Such external air introduction is performed intermittently or continuously, for example, so that the oxygen concentration detected by the sensor 4 is maintained at the normal oxygen concentration. In this normal time, the control device 160 controls the entrance management system 14 so that the first door 11 can be opened and closed, and allows humans to enter and leave the target space 1.

  Further, the controller 160 stores the nitrogen-enriched gas and the oxygen-enriched gas when possible at this normal time and at other timings. Specifically, the control device 160 opens the valve V1 and introduces outside air into the compressor 121 via the pipe P1. Then, the compressor 121 is started, and the outside air compressed by the compressor 121 is stored in the air tank 122. The air thus stored is introduced into the oxygen / nitrogen separation filter 123, and the nitrogen-enriched gas generated by the oxygen / nitrogen separation filter 123 is introduced into the nitrogen-enriched tank 131 via the pipe P1. Stored. At this time, the nitrogen-enriched gas generated by the oxygen / nitrogen separation filter 123 is pressed into the nitrogen-enriched tank 131 by the pressure when the outside air is pressurized by the compressor 121. If further pressurization is required, a pressurization device may be provided between the oxygen / nitrogen separation filter 123 and the nitrogen enrichment tank 131 or the like. Further, the oxygen-enriched gas generated by the oxygen / nitrogen separation filter 123 is introduced into the pressurizing device 141 through the pipe P11, and after being pressurized by the pressurizing device 141, the oxygen-enriched gas is oxygenated through the valve V14. It is introduced into the enrichment tank 142 and stored. Excess oxygen-enriched gas is discharged to the outside through the valve V14 and the pipe P12.

  Further, the control device 160 stores the oxygen-enriched gas in the housing 110 and the storage tank 125 in the ceiling space 2. Specifically, the control device 160 introduces oxygen-enriched gas from the oxygen-enriched tank 142 to the housing 110 by opening the valve V15. Alternatively, the control device 160 introduces the oxygen-enriched gas from the oxygen-enriched tank 142 to the storage tank 125 by opening the valves V15, V3, and V4. Further, the control device 160 stores the nitrogen-enriched gas in the storage tank 126 in the underfloor space 3. Specifically, the control device 160 introduces nitrogen-enriched gas from the nitrogen-enriched tank 131 to the storage tank 126 by opening the valves V10, V3, and V7.

  Next, adjustment of a time zone (time T1 to T2 in FIG. 2) in which a person needs to go in and out in a time zone where fire prevention is high will be described. In this time zone, while improving fire resistance, in order to create a safe state even if a person enters and exits the target space 1, the oxygen concentration in the target space 1 is adjusted to the incombustible living oxygen concentration. Specifically, when the time T1 in FIG. 2 has arrived, the control device 160 opens the valves V10, V3, and V6, thereby causing the nitrogen-enriched gas stored in the nitrogen-enriched tank 131 to enter the target space 1. Introduce. Then, the control device 160 continues to open the valves V10, V3, and V6 until the oxygen concentration in the target space 1 detected by the sensor 4 reaches a predetermined incombustible viable oxygen concentration, so that the incombustible viable oxygen concentration is obtained. At this point, the valves V10, V3, and V6 are shut off. Further, instead of or together with the introduction of the nitrogen-enriched gas, the control device 160 opens the valve V8 so that the nitrogen-enriched gas stored in the storage tank 126 is removed from the target space 1. To release.

  As described above, the nitrogen-enriched gas generated by the oxygen / nitrogen separation filter 123 is not directly introduced into the target space 1, but is nitrogen-enriched that is stored in the nitrogen-enriched tank 131 or the storage tank 126. By introducing the gas into the target space 1, the supply rate of the nitrogen-enriched gas can be improved and the oxygen concentration can be rapidly reduced. That is, as shown in FIG. 2, the required time Ta from the normal oxygen concentration to the incombustible living oxygen concentration is set as the required time Ta ′ in the conventional system (in FIG. The same can be said for the following (Ta <Ta ′). Therefore, the time (time T2-T1-Ta in FIG. 2) in which the incombustible living oxygen concentration can be maintained can be made longer than before. Further, since the storage tank 126 is arranged in the underfloor space 3, the nitrogen-enriched gas having a specific gravity lower than that of air is released from the storage tank 126, and then rises in the target space 1 and is naturally diffused.

  Further, in this incombustible living oxygen concentration state, since there is a possibility that a person enters and exits the target space 1, the oxygen concentration in the target space 1 will fluctuate inadvertently due to the inflow and outflow of gas accompanying this entry and exit. there is a possibility. For this reason, the control device 160 opens the valves V10 and V12 to introduce the nitrogen-enriched gas stored in the nitrogen-enriched tank 131 into the front chamber 10, and the oxygen concentration in the front chamber 10 is also unsatisfactory. Adjust to the combustion surviving oxygen concentration. Accordingly, the direct flow of outside air directly into the target space 1 is reduced, and the oxygen concentration of the target space 1 is prevented from inadvertently changing.

  Further, in order to maintain the oxygen concentration in the front chamber 10, when the front chamber 10 is opened and the nitrogen-enriched gas flows out, it is preferable to replenish this amount rapidly. For this reason, the control device 160 monitors the open / closed state of the first door 11 via the entrance management system 14, and when the first door 11 is opened, the opening degree of the valve V10 or V12, By controlling the opening time and the like, the amount of nitrogen-enriched gas supplied to the front chamber 10 is increased. In addition, when it is not necessary to make the front chamber 10 into the non-combustion living oxygen concentration, the outside air may be taken into the front chamber 10 by opening the valves V13 and V12 and starting the blower 132.

  Next, adjustment of a time zone (time T2 to T3 in FIG. 2; for example, corresponding to nighttime) in which there is a high necessity for fire prevention and where there is no possibility of humans going in and out will be described. In this time zone, the oxygen concentration in the target space 1 is adjusted to the incombustible oxygen concentration in order to create a state with the highest fire resistance. Specifically, when the time T2 in FIG. 2 has arrived and it has been confirmed that no person has entered the target space 1 via the entry management system 14, the control device 160 performs the above-described non-combustion. Similarly to the adjustment to the living oxygen concentration, the nitrogen-enriched gas stored in the nitrogen-enriched tank 131 or the storage tank 126 is introduced into the target space 1. Therefore, the supply rate of the nitrogen-enriched gas can be improved and the oxygen concentration can be quickly reduced, as in the adjustment to the non-combustion living oxygen concentration. That is, as shown in FIG. 2, the required time Tb from the incombustible living oxygen concentration to the incombustible oxygen concentration can be greatly shortened as compared with the required time Tb ′ in the conventional system (Tb <Tb ′). Therefore, the time during which the unburned oxygen concentration can be maintained (time T3-T2-Tb in FIG. 2) can be made longer than before.

  In this incombustible oxygen concentration state, the control device 160 closes the first door 11 via the entry management system 14 to prevent a person from entering the target space 1 inadvertently. When the nitrogen-enriched gas is oversupplied and the target space 1 is in an overpressurized state, the pressure relief port 5 is automatically opened to partially release the pressure in the target space 1, Overpressurized state is eliminated.

  Here, in such an incombustible oxygen concentration state, when the sensor 4 detects that a person is present in the target space 1 for some reason, the control device 160 does not set the oxygen concentration in the target space 1 to be low. Return as soon as possible to exceed the concentration of viable combustion oxygen to ensure the safety of human life. Specifically, the controller 160 introduces the oxygen-enriched gas stored in the oxygen-enriched tank 142 into the target space 1 by opening the valves V15, V3, and V6. Further, instead of or together with the introduction of such nitrogen-enriched gas, the control device 160 opens the valve V5 so that the oxygen-enriched gas stored in the storage tank 125 is transferred to the target space 1. Release. Further, as necessary, the control device 160 takes in the oxygen-enriched gas stored in the housing 110 from the valve V3 and releases it to the target space 1 through the valve V6. As described above, by increasing the oxygen concentration using the oxygen-enriched tank 142, the storage tank 125, or the oxygen-enriched gas stored in the housing 110, the oxygen concentration can be rapidly increased. Safety can be ensured.

  Next, the adjustment in the time zone in which the necessity of fire prevention is high and the time zone in which humans may go in and out (time T3 to T4 in FIG. 2) will be described. When the time T3 in FIG. 2 arrives, the control device 160 opens the valves V15, V3, and V6 to introduce the oxygen-enriched gas stored in the oxygen-enriched tank 142 into the target space 1. Then, the control device 160 continues to open the valves V15, V3, and V6 until the oxygen concentration in the target space 1 detected by the sensor 4 returns to a predetermined incombustible living oxygen concentration, and the incombustible living oxygen concentration. When returning to, valves V15, V3, and V6 are shut off. Further, instead of or together with the introduction of the oxygen-enriched gas, the control device 160 opens the valve V5 so that the oxygen-enriched gas stored in the storage tank 125 is transferred to the target space 1. Release. Further, as necessary, the control device 160 introduces the oxygen-enriched gas stored in the housing 110 from the valve V3 and releases it to the target space 1 through the valve V6.

  In this way, the oxygen-enriched gas generated by the oxygen / nitrogen separation filter 123 is not directly introduced into the target space 1 but is stored in the oxygen-enriched tank 142, the storage tank 125, or the housing 110. By introducing the oxygen-enriched gas that has been made into the target space 1, the supply speed of the oxygen-enriched gas can be improved, and the oxygen concentration can be rapidly increased. That is, as shown in FIG. 2, the required time Tc from the incombustible oxygen concentration to the incombustible living oxygen concentration can be greatly reduced compared to the required time Tc ′ in the conventional system (Tc <Tc ′). Therefore, the time (time T4-T3-Tc in FIG. 2) during which the non-combustion viable oxygen concentration can be maintained can be made longer than before. In addition, when returning to the non-combustion viable oxygen concentration in this way, the control device 160 controls the entrance management system 14 so that the first door 11 can be opened and closed, and again allows humans to enter and leave the target space 1. .

  Further, the adjustment in the normal time (after time T4 in FIG. 2) will be described. When the time T4 in FIG. 2 arrives, the control device 160 returns the oxygen concentration in the target space 1 to the normal oxygen concentration. Specifically, the control similar to the case of returning to the non-combustion viable oxygen concentration is performed to introduce the oxygen-enriched gas into the target space 1, or the same control as in the time T0 to T1 is performed. Then, by introducing outside air into the target space 1, the oxygen concentration in the target space 1 is returned to the normal oxygen concentration. In particular, when the same control as when returning to the non-combustion viable oxygen concentration is performed, the supply rate of the oxygen-enriched gas can be improved and the oxygen concentration can be increased rapidly. That is, as shown in FIG. 2, the required time Td for returning from the non-combustion surviving oxygen concentration to the normal oxygen concentration can be significantly shortened compared to the required time Td ′ in the conventional system (Td <Td ′).

  In addition, the control apparatus 160 adjusts the humidity of the object space 1 at the time of adjustment in each time slot | zone so far. Specifically, the control device 160 periodically monitors the humidity of the target space 1 via the sensor 4, and when the humidity is equal to or higher than a predetermined humidity or lower than the predetermined humidity, the humidity adjustment device 151 is turned on. While driving, the valves V16, V3, and V6 are opened, and humidified air or dry air is discharged into the target space 1. Here, the generation of the humidified air is performed using the condensed water supplied from the compressor 121. As described above, by using the condensed water as the humidifying water, it is not necessary to supply the humidifying water separately, and the cost of humidity adjustment can be reduced.

  In addition, at the time of adjustment in each time slot | zone so far, the control apparatus 160 makes the oxygen concentration inside the object space 1 uniform by operating the stirrer 6. FIG. Further, when the target space 1 is in an overpressurized state, the pressure avoidance port 5 and when the front chamber 10 is in an overpressurized state, the release damper 15 and the housing 110 are in an overpressurized state. In this case, the release dampers 111 are respectively opened, and the pressure is partially released, so that the overpressurized state is eliminated.

  When a fire occurs in the target space 1 in the normal oxygen concentration state, a fire notification signal is output from the fire detector to the control device 160. The control device 160 that has received this fire notification signal sends out a fire extinguishing signal to the fire extinguishing device control unit 202. Upon receiving this fire extinguishing signal, the fire extinguisher control unit 202 controls the fire extinguishing apparatus 201 and opens the valves V17 and V6 to release the fire extinguishing gas or the extinguishing agent into the target space 1. This will extinguish the fire.

[III] Modifications to Embodiments Although the embodiments of the present invention have been described above, specific configurations and methods of the present invention are within the scope of the technical idea of each invention described in the claims. Any modification and improvement can be made. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved. For example, even if the final fireproofness and safety of the target space 1 are comparable to those of the conventional system, as long as the oxygen concentration of the target space 1 can be adjusted more quickly than the conventional system, the problem of the present application Has been achieved.

(Regarding target space 1)
Regarding the specific configuration of the target space 1 and the mutual configuration of the target space 1 and the oxygen concentration adjustment unit 100, various different configurations other than the configuration shown in the above embodiment can be taken. For example, a plurality of oxygen concentration adjustment units 100 may be arranged for one target space 1, or one oxygen concentration adjustment unit 100 may be arranged for a plurality of target spaces 1. Also, some of the components of the oxygen concentration adjustment unit 100 may be arranged in the target space 1, or some of the components arranged in the target space 1 may be arranged in the oxygen concentration adjustment unit 100. . Moreover, you may abbreviate | omit both the ceiling back space 2 of the object space 1, the under floor space 3, or one side. Or you may make the inside of the side wall part of the object space 1 hollow shape, and provide a storage means in this inside. In addition, a plurality of front chambers 10 may be provided for one target space 1, or the front chamber 10 may be omitted.

(About the oxygen concentration adjustment unit 100)
The oxygen concentration adjustment unit 100 is not necessarily configured as a unit, and may be divided into a plurality of housings 110, for example. Moreover, the piping system and control system of the oxygen concentration adjustment unit 100 can be arbitrarily modified. In addition, each component of the oxygen concentration adjustment unit 100 can be integrated or divided. For example, a plurality of nitrogen enrichment tanks 131 and a plurality of oxygen enrichment tanks 142 may be provided. Further, the oxygen supply line 140 may be omitted and only the outside air may be introduced when the oxygen concentration is improved.

(About storage means)
A part of each storage means shown in the embodiment may be divided or omitted. Further, the type of gas stored in the storage unit may be changed. For example, the nitrogen-enriched gas may be stored in the casing 110 or the storage tank 125 and the oxygen-enriched gas may be stored in the storage tank 126. In addition to the tank structure, various different configurations can be adopted as the specific configuration of the storage means. For example, the storage means can be made to be an elastically expandable / contractible balloon structure, and the storage means can be self-contracted when the nitrogen-enriched gas or the oxygen-enriched gas is not filled, thereby saving space. Further, “arranging the storage means on the ceiling, floor, or wall surface” includes configuring the ceiling, floor, or wall surface itself as the storage means. For example, the ceiling back space 2 and the underfloor space 3 are formed into an airtight structure (or an incomplete airtight structure in which an allowable amount of gas can flow out) by sealing or the like. Nitrogen-enriched gas or oxygen-enriched gas may be stored. Then, a damper that can be freely opened and closed is provided on the ceiling wall or floor plate, and the damper is opened as necessary, so that nitrogen-enriched gas or oxygen-enriched gas can be supplied to the target space 1. In addition, a fan is provided in the vicinity of the damper and other arbitrary positions, and when the damper is opened, the fan is rotated to enrich the nitrogen-enriched gas and oxygen stored in the ceiling space 2 and the underfloor space 3 The gas may be promoted to flow into the target space 1, or the mixing of the nitrogen-enriched gas or oxygen-enriched gas that has entered may be promoted. In this case, since substantially the entire area of the ceiling back space 2 and the underfloor space 3 can be used as a storage space, further space saving can be achieved.

  As described above, the low oxygen concentration fire prevention system according to the present invention is useful for improving the fire resistance and safety of the target space by adjusting the oxygen concentration of the target space.

1 is a system diagram showing an overall configuration of a low oxygen concentration fire prevention system according to an embodiment of the present invention. It is a graph which shows oxygen concentration change of object space.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Target space 2 Ceiling space 3 Underfloor space 4 Sensor 5 Pressure relief port 6 Stirrer 10 Front chamber 11 First door 12 Second door 13 Oxygen concentration display device 14 Entrance management system 15 Release damper 100 Oxygen concentration adjustment unit 110 Enclosure Body 111 Release damper 120 Common line 121 Compressor 122 Air tank 123 Oxygen / nitrogen separation filter 124 Flow meter 125, 126 Storage tank 130 Nitrogen gas supply line 131 Nitrogen enriched tank 132 Blower 140 Oxygen supply line 141 Pressurization device 142 Oxygen enrichment Tank 150 Humidity adjustment line 151 Humidity adjustment device 160 Control device 200 Fire extinguishing unit 201 Fire extinguishing device 202 Fire extinguishing device control part P1-P14 Piping V1-V17 Valve

Claims (6)

A low oxygen concentration fire prevention system that performs fire prevention of the target space by reducing the oxygen concentration of the target space,
An inert gas supply line for supplying an inert gas to the target space;
An oxygen supply line for supplying oxygen to the target space;
A storage means for storing the inert gas or the oxygen provided in at least one of the inert gas supply line or the oxygen supply line;
A low oxygen concentration fire prevention system characterized by comprising: The storage means is disposed on at least one of a ceiling part, a floor part, or a wall surface part of the target space,
The low oxygen concentration fire prevention system according to claim 1. The storage means is disposed in a front chamber provided adjacent to the target space,
The low oxygen concentration fire prevention system according to claim 1 or 2. A housing means for housing at least a part of the inert gas supply line and the oxygen supply line;
The storage means is the storage means;
The low oxygen concentration fire prevention system according to any one of claims 1 to 3. Humidity adjusting means for adjusting the humidity of the target space;
The low oxygen concentration fire prevention system according to any one of claims 1 to 4, further comprising: A pressurizing means for pressurizing the inert gas, the oxygen, or air for generating the inert gas or oxygen;
The pressurizing means is connected to the humidity adjusting means, and the condensed water generated during pressurization in the pressurizing means can be introduced as humidifying water in the humidity adjusting means,
The low oxygen concentration fire prevention system according to claim 5.

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