JP2007185518A - Fire extinguishing gas delivery system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fire extinguishing gas delivery system by which smoke and chemical toxic gas, carbon monoxide and carbon dioxide, generated in a fire are scavenged to secure a visual range, burning can be suppressed in a condition a man can breathe, and extinguishing a fire and securing human life are enabled. <P>SOLUTION: The fire extinguishing gas delivery system comprises a fire extinguishing gas storage facility (1) for storing an inert gas containing nitrogen as the main component in oxygen concentration of 10-15%, a fire extinguishing gas discharging facility (8) placed in a fire-protection object, and a piping facility (3) to connect the fire extinguishing gas storage facility (1) and the fire extinguishing gas discharging facility (8). The system is constructed so that the inert gas containing nitrogen as the main component in oxygen concentration of 10-15% is discharged from the fire extinguishing gas discharging facility (8). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a fire extinguishing gas supply system that is supplied to weaken or extinguish a flame in the event of a fire, and relates to the supply of an inert (inert gas) fire extinguishing gas.

Conventionally, a technique for extinguishing a fire by discharging a fire extinguishing gas is known. And the technique of utilizing nitrogen gas as a fire extinguishing gas is known as shown by Unexamined-Japanese-Patent No. 8-141102. The technique disclosed in Japanese Patent Application Laid-Open No. 8-141102 uses a nitrogen cylinder as a gas supply source. Then, nitrogen gas is supplied at a flame extinguishing concentration or more in the event of a fire.
JP-A-8-141102

  However, when nitrogen gas is supplied using a cylinder, it is necessary to manually replace the cylinder and refill the cylinder, and a large amount of cylinder storage space is required for each object. And requires a lot of effort. In particular, it is difficult to configure storage facilities in old streets and densely populated houses.

  In order to solve the above problems, the present invention has been invented based on the following technical idea. First, an inert fire extinguishing gas such as nitrogen is stored in a large-scale storage facility. Then, the fire extinguishing gas storage facility is connected to a plurality of fire extinguishing facilities by piping or the like. Thereby, a large amount of fire extinguishing gas can be supplied to the fire prevention object. An inert gas used as a fire extinguishing gas is chemically stable and has various uses. In particular, nitrogen gas is abundant in air, is chemically stable, and has low permeability to rubber and the like. For this reason, it is used in the process of welding and injection molding, and as an enclosed gas for packed food. Further, it is used as a gas to be injected into automobile tires. By storing inert gas in the storage facility and making it possible to supply it to various places through piping, it can be used not only as a fire extinguisher gas, but also as a cultural property preserved as a gas to prevent oxidation, and at industrial sites, etc. It can also be used.

  And when using as a fire extinguishing gas used for living space, oxygen is mixed with an inert gas in a fixed ratio. In addition to this, nitrogen gas mixed with oxygen has already been stored, only nitrogen is released and the supply of nitrogen is adjusted by an oxygen concentration sensor, or nitrogen and oxygen are mixed and supplied at the facility. You can also. Carbon monoxide and carbon dioxide during a fire have many effects on the human body. For example, carbon monoxide binds strongly to hemoglobin in the blood and inhibits oxygen supply to the human body by the blood. Hemoglobin takes oxygen into blood when the concentration ratio of oxygen to carbon dioxide is higher than a certain value, and takes carbon dioxide when it is lower. For this reason, even when the oxygen concentration is high, carbon dioxide is taken into the body if the carbon dioxide concentration is higher than that.

  Here, oxygen is mixed into the fire extinguishing gas at a certain ratio, and released in the event of a fire, thereby scavenging carbon monoxide and carbon dioxide and supplying a certain amount of oxygen to the person on the fire. Combustion depends on the absolute oxygen concentration. Therefore, combustion can be suppressed by making the oxygen concentration contained in the fire extinguishing gas lower than the oxygen concentration in the natural state. Furthermore, by supplying the fire extinguishing gas, the amount of heat generated at the fire site is absorbed by the fire extinguishing gas, and the heat is efficiently discharged. Therefore, at the fire site, the incomplete combustion gas, which is the top cause of death that has occurred, can be immediately expelled and replaced with a state in which humans can breathe and can suppress combustion.

That is, the present invention uses the following means.
As described in claim 1, a fire extinguishing gas storage facility for storing an inert fire extinguishing gas mainly containing nitrogen at an oxygen concentration of 10% to 15%, a fire extinguishing gas discharge facility disposed on a fire prevention object, and It is composed of a piping facility that connects the fire extinguishing gas storage facility and the fire extinguishing gas discharge facility, and is configured to release an inert fire extinguishing gas mainly composed of nitrogen at an oxygen concentration of 10% to 15% from the fire extinguishing gas discharge facility. Fire extinguishing gas supply system.

  As described in claim 2, the inert fire extinguishing gas is configured to be used as a pressure source of a fire extinguishing agent discharge facility disposed on a fire prevention object.

Since the present invention is configured as described above, the following effects can be obtained.
As described in claim 1, a fire extinguishing gas storage facility for storing an inert fire extinguishing gas mainly containing nitrogen at an oxygen concentration of 10% to 15%, a fire extinguishing gas discharge facility disposed on a fire prevention object, and Consists of a piping facility connecting the fire extinguishing gas storage facility and the fire extinguishing gas release facility, and configured to release an inert fire extinguishing gas mainly composed of nitrogen at an oxygen concentration of 10% to 15% from the fire extinguishing gas release facility This makes it possible to configure a fire extinguishing gas supply system that has little impact on the human body, scavenging smoke generated during a fire, chemical gases, carbon monoxide, and carbon dioxide to ensure visibility and allow humans to breathe And can suppress combustion. That is, it is possible to configure a fire extinguishing gas supply system that can extinguish a fire and secure a human life.

  As described in claim 2, since the inert fire extinguishing gas is used as a pressure source of the fire extinguisher discharge facility disposed on the fire prevention object, the fire extinguisher discharge facility can be simply configured.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram showing the overall configuration of a fire extinguishing gas supply system. A nitrogen tank 1 for storing nitrogen is connected to a pipe 3 via a vaporizer 2. A branch pipe 5 is connected to the pipe 3, and is connected to a fire extinguishing facility for fire extinguishing purposes (fire prevention object) 4 through the branch pipe 5. By storing nitrogen in a liquid state in the nitrogen tank 1, a large amount of nitrogen can be stored, and nitrogen gas can be supplied not only for fire fighting but also for industrial use. When the consumption of nitrogen gas is small and the capacity of the nitrogen tank 1 is large, the nitrogen gas can be compressed and stored in a gaseous state.

  Next, the configuration of the fire extinguishing equipment will be described. FIG. 2 is a schematic diagram showing a connection configuration of fire extinguishing equipment in the fire extinguishing gas supply system, FIG. 3 is a diagram showing an internal configuration of a common structure and nitrogen gas piping, and FIG. 4 is a diagram showing a configuration of a fire extinguishing gas storage facility. In the configuration shown in FIG. 2, a pipe 3 is connected to the nitrogen tank 1, and nitrogen gas in the nitrogen tank 1 is supplied into the pipe 3. A branch pipe 5 is connected to the pipe 3 and is connected to a fire extinguishing facility. Nitrogen gas is introduced into the nitrogen tank 1 through an oxygen separator 11 and a compressor. The separated oxygen is stored in the oxygen tank 12. The branch pipe 5 is introduced into an office, an office building, a house, etc., and is connected to a fire extinguishing gas discharger 8 which is a fire extinguishing equipment. Thereby, nitrogen gas is discharged from the fire extinguishing gas discharger 8 to extinguish the fire. In addition, it is also possible to connect the water supply tank 6 from the branch pipe 5 to the water storage tank 6 and pressurize the water supplied to the sprinkler head 7 or the indoor fire hydrant.

  Furthermore, as shown in FIG. 3A, the pipe 3 for supplying nitrogen gas can be disposed in the common structure 30 together with a water pipe 31 such as a water and sewage system, an optical fiber cable, an electric wire, and the like. As shown in FIG. 3 (b), it is also possible to arrange the water pipe 31, the electric wire pipe 32, and the optical fiber pipe 33 in the pipe 3 by using the nitrogen gas pipe 3 as a common structure. Since nitrogen gas is flowing in the pipe 3, toxic gas such as carbon monoxide or flammable gas which has an influence on the human body is hard to accumulate and is diluted quickly. In addition, since the oxygen concentration is low, a fire does not easily occur in the pipe 3.

  The configuration of the fire extinguishing gas storage facility will be described with reference to FIG. FIG. 4A is a diagram showing a storage configuration using a tank, and FIG. 4B is a diagram showing a storage configuration using the underground. In the configuration shown in FIG. 4 (a), the fire extinguishing gas is mainly composed of nitrogen gas, and is prepared by reducing oxygen in the air. The oxygen separation device 11 connected to the nitrogen tank 1 via a compressor 11b takes out oxygen in the air and generates a gas having a low oxygen concentration. The oxygen separator 11 is not particularly limited as long as the main component is nitrogen and a gas having a low oxygen concentration can be generated. As an example of the oxygen separator 11, a case where the oxygen separator 11 using an oxygen separation membrane is used will be described. The oxygen separation membrane supplies air to a membrane that is easy to permeate oxygen gas and difficult to permeate nitrogen gas, and separates it into air having a high oxygen concentration and air having a low oxygen concentration. The degree of oxygen separation can be adjusted by the amount of air per unit time supplied to the oxygen separation membrane, and can also be adjusted by the number of times of permeation through the oxygen separation membrane.

  Then, air having a high oxygen concentration can be stored in the oxygen tank 12 and used as a relaxation gas or a gas for supplying oxygen to a drainage septic tank or the like. By generating a fire extinguishing gas having a low oxygen concentration from air, a gas having a high oxygen concentration can be generated at the same time, and both gases can be used effectively. Moreover, it is also possible to store high-pressure inert gas using a huge basement or a deep underground space as an underground storage for nitrogen gas. As shown in FIG. 4B, nitrogen gas is stored using the space of the underground storage 35. The underground storage 35 stores nitrogen gas under a certain pressure, and the nitrogen gas is supplied to the fire prevention object through the pipe 3 connected to the underground storage 35. When the underground storage 35 is configured adjacent to a museum or an art museum that is a fire prevention object, the underground storage 35 can be used as a storage for valuables that require long-term stable storage and cultural materials.

  In this embodiment, the oxygen separator 11 stores a gas of 88% nitrogen and 12% oxygen in the nitrogen tank 1. The oxygen concentration is 15% to 10%. The oxygen concentration that can exist even if a person is 1 hour or more is about 10% or more, and the oxygen concentration that can extinguish a suffocation when there is no oxygen supply from others is about 15% or less. For this reason, the fire extinguishing gas which contributes to fire extinguishing can be comprised, reducing the influence on a person by setting oxygen concentration as 15 to 10%. In addition, by making it a gas that humans can live from the beginning, the risk at the final fire extinguishing destination is reduced. A so-called fool-proof and fail-safe system becomes possible.

  As a storage method in the nitrogen tank 1, a fire extinguishing gas is supplied to the nitrogen tank 1 by a pump or the like, and the storage with the nitrogen tank 1 kept at a constant pressure or a storage with the fire extinguishing gas liquefied is possible. . In the case of liquefaction, oxygen and nitrogen are separated and stored according to the boiling point or the like, and oxygen concentration can be adjusted by mixing liquefied oxygen or air into nitrogen gas at the time of supply. In addition, when the liquefied nitrogen is stored in the nitrogen tank 1 and used as a fire extinguishing gas, it can be mixed with air to adjust the oxygen concentration.

  Next, the configuration of scavenging using a fire extinguishing gas will be described with reference to FIG. FIG. 5 is a diagram showing a scavenging configuration by the fire extinguishing equipment. A fire extinguishing gas is supplied from the pipe 3 via the branch pipe 5 to the fire extinguishing gas dischargers 8, 8. When a fire occurs, harmful gases such as smoke and carbon monoxide are generated in the room as shown in FIG. Here, when the fire extinguishing gas is released by the fire extinguishing gas discharger 8, as shown in FIG. 5B, the room is filled with the fire extinguishing gas, and harmful gases such as smoke are discharged. As described above, the fire extinguishing gas contains oxygen. And since carbon dioxide is discharged | emitted outdoor by discharge | release of fire extinguishing gas, the influence which it has on a human body can be reduced even in the state with little oxygen.

  Next, the structure of the sprinkler facility using fire extinguishing gas will be described. FIG. 6 is a schematic diagram showing the configuration of the sprinkler facility. FIG. 6A is a schematic diagram illustrating a configuration in which a fire extinguishing gas is used as a pressure source, and FIG. 6B is a schematic diagram illustrating a configuration in which water is discharged together with the fire extinguishing gas. First, a configuration using a fire extinguishing gas as a pressure source of the sprinkler will be described. The fire extinguishing gas supplied from the pipe 3 is introduced into the water storage tank 6 through the branch pipe 5. The fire extinguishing gas introduced into the water storage tank 6 applies pressure to the liquid level. Then, the water in the water storage tank 6 is supplied to the sprinkler head 7 and the water is discharged from the sprinkler head 7. Pressure is applied by supplying a fire extinguishing gas to the water storage tank 6, and water is released by opening the sprinkler head 7. Since the pressure is secured by supplying the fire extinguishing gas, a constant pressure can be maintained regardless of the water consumption. And after consuming water, the fire extinguishing gas is discharged, so the fire fighting operation can be continued.

  A configuration for discharging water together with the fire extinguishing gas from the sprinkler head 7 will be described with reference to FIG. The branch pipe 5 connected to the pipe 3 is connected to the sprinkler head 7. One end of a pipe 9 is inserted into the water storage tank 6, and the other end is connected to the sprinkler head 7. In the sprinkler head 7, a fire extinguishing gas supply path is connected to a water supply path from the water storage tank 6, and water is atomized and discharged together with the fire extinguishing gas by the venturi effect at the connecting portion. The supply of water to the sprinkler head 7 is not particularly limited, and the sprinkler head 7 only needs to discharge mist-like water together with the fire extinguishing gas. Thereby, water can be discharged | emitted with fire extinguishing gas, and fire extinguishing can be performed rapidly. That is, the fire extinguishing gas supplied through the piping equipment is used as a part or all of the pressure source of the fire extinguishing agent discharge equipment. Thereby, the discharge | release facility of a fire extinguisher can be comprised simply. In the said structure, water is used as a fire extinguisher. As a fire extinguisher, it is possible to use a general liquid or powder fire extinguisher in addition to water.

  Next, another supply structure of the fire extinguishing gas will be described. FIG. 7 is a diagram showing a fire-extinguishing gas supply configuration using an oxygen separator, FIG. 7 (a) is a diagram showing a configuration in which an oxygen separator is disposed in the middle of a pipe, and FIG. 7 (b) is a pipe connecting portion. FIG. 7C is a diagram showing a configuration in which an oxygen separation device is provided, and FIG. 7C is a diagram showing a configuration example of a fire extinguishing gas discharge unit. First, the structure which arrange | positions an oxygen separation apparatus in the middle part of a piping path | route is demonstrated. In this configuration, an oxygen separation device is provided in the piping path to remove oxygen in the pressurized air supply process and to make a fire extinguishing gas. Thereby, supply of the fire-extinguishing gas to a fire-extinguishing equipment is attained by sending air with the apparatus which pumps air.

  As shown in FIG. 7A, the pipe 3 is provided with an oxygen separation device 11 and is configured to remove oxygen from the air being pumped through the pipe 3. A pipe 12 is connected to the oxygen separator 11, and the atmospheric pressure in the pipe 12 is lower than that of the pipe 3. Oxygen in the air flowing in the pipe 3 is taken out to the pipe 12 due to a pressure difference. Thereby, the oxygen concentration of the air flowing through the pipe 3 is lowered. The air having a low oxygen concentration is supplied as a fire extinguishing gas to the fire extinguishing gas discharger 8 serving as a fire extinguishing facility via the branch pipe 5. Air with a high oxygen concentration taken out by the oxygen separator 11 can be discharged into the atmosphere, and can also be used as an oxygen source for purifying sewage.

  In the configuration shown in FIG. 7B, the fire extinguishing gas is taken out via the oxygen separation device 13. Air is pumped through the pipe 3, and the air is introduced into the oxygen separator 13. A pipe 12 and a branch pipe 5 are connected to the oxygen separator 13. Air having a high oxygen concentration is sent to the pipe 12, and air having a low oxygen concentration is sent to the branch pipe 5. Then, air having a low oxygen concentration is supplied to the fire extinguishing gas discharger 8 as a fire extinguishing gas. In order to ensure a sufficient supply amount of the fire extinguishing gas, a fire extinguishing gas cylinder 14 serving as a fire extinguishing storage unit is provided in the branch pipe 5, and the extinguishing gas can be stored in the fire extinguishing gas cylinder 14. For air with a high oxygen concentration, a cylinder 15 can be similarly arranged to store air with a high oxygen concentration in the cylinder 15. In this case, the fire extinguishing gas can be generated using the pressure-fed air, and the fire extinguishing gas supply system can be simply configured.

  In the configuration shown in FIG. 7 (c), the fire extinguishing gas discharge unit 40 generates a fire extinguishing gas having a nitrogen concentration higher than that of air and supplies it into the house. The fire extinguishing gas unit 40 incorporates a compressor and an oxygen separator, and is configured to operate the compressor to generate a fire extinguishing gas and supply it to the fire extinguishing gas discharger 8. Thereby, piping can be simplified, generation | occurrence | production and supply of fire extinguishing gas can be performed as needed, and a running cost can be reduced. It can be used in areas where piping from the fire extinguishing gas supply source is not in place.

  Next, a fire extinguishing gas supply configuration will be described. FIG. 8 is a schematic diagram illustrating an example of a fire extinguishing gas supply configuration, FIG. 8A is a diagram illustrating a connection configuration with a small-scale storage facility, and FIG. 8B is a fire extinguishing gas from the small-scale storage facility to the fire extinguishing facility. It is a figure which shows a supply structure. In the configuration shown in FIG. 8, a fire extinguishing gas is supplied from a large-scale fire extinguishing gas supply source to a small fire extinguishing gas storage facility, and in the event of a fire, the fire extinguishing gas is supplied from the large-scale fire extinguishing gas supply source and the small fire extinguishing gas storage facility To supply. The nitrogen tank 1 which is a large-scale fire extinguishing gas supply source is connected to a small-scale storage facility 16 via a pipe 3. One nitrogen tank 1 is connected to a plurality of small-scale storage facilities 16, 16... By piping 3, and the small-scale storage facilities 16, 16 are also connected by piping 3. Thereby, even when some piping paths are closed, nitrogen gas can be supplied from the nitrogen tank 1.

  The small-scale storage facility 16 stores fire extinguishing gas supplied through the pipe 3. As shown in FIG. 8 (b), a block piping network 3 b is connected to the small scale storage facility 16, and the fire extinguishing gas stored in the small scale storage facility 16 and the small scale storage facility 16 from the pipe 3 are connected. The supplied fire extinguishing gas is supplied to the block piping network 3b. The block piping network 3b is a piping network connected in a mesh pattern along the arrangement of buildings and the like for each certain area, and a plurality of small-scale storage facilities 16 are connected to one block piping network 3b. Yes. As described above, fire extinguishing equipment is connected to the block piping network 3b, and fire extinguishing gas can be discharged. Thereby, when a fire occurs in the area where the block piping network 3b is disposed, the fire extinguishing gas can be supplied from a plurality of small-scale storage facilities 16, 16, and so on to cope with the fire. .

  In this way, by disposing a plurality of storage devices and connecting them by piping, fire extinguishing gas can be supplied from a plurality of storage devices in the event of a fire. For this reason, it is also possible to reduce the supply amount of the fire extinguishing gas from the nitrogen tank 1 in normal times, and the piping 3 can be constituted by a small-diameter pipe, thereby reducing the cost for installation. In addition, the pipe 3 is configured to have a small diameter, the inner area of the pipe 3 is increased with respect to the amount of gas in the pipe 3, and the pipe 3 is formed of a material capable of oxygen separation while efficiently extracting oxygen in the pipe 3. Fire extinguishing gas can also be supplied.

  Next, a fire extinguishing gas storage configuration in a coastal area will be described. FIG. 9 is a diagram showing a storage configuration in the coastal region, and FIG. 10 is a diagram showing a compression configuration of the fire extinguishing gas in the coastal region. In coastal areas, fire extinguishing gas storage facilities are installed in the sea. A storage tank 20 is disposed in the sea, and a fire extinguishing gas is supplied through the pipe 3. The fire extinguishing gas is stored in the storage tank 20, and the fire extinguishing gas can be supplied to a warehouse or the like through a pipe 22 connected to the storage tank 20. The storage tank 20 is configured to be able to change the storage volume of the fire extinguishing gas, and is configured to apply pressure to the fire extinguishing gas in the storage tank 20 by water pressure. Accordingly, by connecting a pump or the like to the pipe 3 and storing the fire extinguishing gas in the storage tank 20, the fire extinguishing gas can be pumped to the pipe 22 regardless of the amount of the fire extinguishing gas.

  Further, as shown in FIG. 10, by supplying the fire extinguishing gas into the storage tank 20 at low tide, the pressure of the fire extinguishing gas can be increased at high tide. In this way, it is also possible to pressurize and store the fire extinguishing gas using the tide fullness. Furthermore, it is possible to generate fire extinguishing gas by discharging compressed air at the seabed and collecting and storing the air released near the sea surface. Oxygen is more soluble in water than nitrogen. In particular, when the pressure is high such as the seabed, the solubility of oxygen increases. For this reason, by releasing the compressed air at the seabed, oxygen is absorbed by the seawater, and the air with a high nitrogen concentration rises to the sea surface. This makes it possible to supply oxygen at the bottom of the sea, purify the bottom of the sea, and produce fire extinguishing gas.

  Next, a configuration in which a water pipe is used as a fire-extinguishing gas supply pipe will be described with reference to FIG. FIG. 11 is a diagram showing a configuration in which a water pipe is used as a fire-extinguishing gas supply pipe. Tap water and nitrogen gas which is a fire extinguishing gas are introduced into the water pipe 25. And in the water pipe 25, fire extinguishing gas is located in the upper part, and tap water is located in the lower part. A water pipe 26 is connected to the water pipe 25 so that water can be supplied to a house or the like. The intake port of the water supply pipe 26 is located below the water supply pipe 25 and is configured to take in tap water. A fire extinguishing gas take-out section 27 is connected to the upper portion of the water pipe 25, and the fire extinguishing gas branch section 5 is connected to the fire extinguishing gas take-out section 27. A fire extinguishing gas discharger 8, 8,... Is connected to the branch pipe 5 so that the extinguishing gas can be discharged. In addition, the fire extinguishing gas extraction part 27 prevents the inflow of tap water into the branch pipe 5. In the water pipe 25, the fire extinguishing gas is in a pressurized state, and the supply pressure of tap water can be adjusted by the pressure of the fire extinguishing gas. By using the water pipe 25 as a fire extinguishing gas supply pipe, the cost of the pipe can be reduced. Then, by introducing water into the pipe for supplying the fire extinguishing gas, the nitrogen ratio of the fire extinguishing gas can be easily increased by dissolving the oxygen gas.

  Such a fire extinguishing gas supply system is effective for a fire in a sealed space, and has high effectiveness in application to a tunnel, a subway, an underground shopping center, a high-rise building with no windows, or the like. In particular, in a space where carbon dioxide, toxic gas, and the like are likely to accumulate, a fire extinguishing gas having an oxygen concentration of 15% to 10% is used, so that a person can survive and suppress the combustion such as fire and the spread of fire. Furthermore, even when extinguishing gas is stored using a deep underground space, it can be used safely. The underground space is a place where gas such as carbon dioxide accumulates and the oxygen concentration tends to decrease extremely. Since the fire extinguishing gas that can survive and suppress combustion is stored in this place, the safety of the underground space can be maintained, and the fire extinguishing gas can be stored using the underground space. Furthermore, when supplying the fire extinguishing gas from the underground space, the fire extinguishing gas can be easily supplied by a blower or the like.

  Next, the configuration of a fire extinguishing gas supply system that discharges bubbles containing inert fire extinguishing gas will be described. FIG. 12 is a perspective view showing a fire extinguishing gas supply system that emits foam, FIG. 13 is a schematic view showing the smoke exhausting action by the foam containing the fire extinguishing gas, and FIG. 14 is a schematic view showing the action of the foam containing the fire extinguishing gas. is there. First, the configuration of the fire extinguishing gas supply system will be described with reference to FIG. The fire extinguishing gas supply system that discharges bubbles includes a fire extinguishing gas storage unit 50, a drug storage unit 51, a control unit 52, a pipe 53, and a discharge unit 54. The fire extinguishing gas storage unit 50 can use the gas cylinder filled with the fire extinguishing gas, the above-described fire extinguishing gas supply configuration, and the like. The chemical | medical agent storage part 51 is mixed with the fire extinguishing gas, and the chemical | medical agent which produces | generates a bubble is stored. As the medicine to be stored, it is possible to use a liquid or powder. In the case of using a powdered medicine, it can be mixed with water before use and mixed with a fire extinguishing gas.

  The controller 52 controls the supply of fire extinguishing bubbles containing fire extinguishing gas. The control unit 52 is connected to the fire extinguishing gas storage unit 50, the medicine storage unit 51, and the pipe 53, and supplies the fire extinguishing gas and the medicine or the fire extinguishing foam to the pipe 53. The pipe 53 connects the control unit 52 and the discharge unit 54, and through which fire extinguishing bubbles or fire extinguishing gas and chemicals pass. The discharge part 54 discharges the fire-extinguishing foam, and it is also possible to generate the fire-extinguishing foam in the discharge part 54 from the fire-extinguishing foam supplied from the pipe 53 or the fire-extinguishing gas and the chemical.

  For the supply of the fire extinguishing foam, the pressure of the fire extinguishing gas in the fire extinguishing gas storage 51 can be used. For example, a fire extinguishing gas generated by introducing a fire extinguishing gas into the drug storage unit 51 and bubbling the drug can be discharged from the discharge unit 54 by the supply pressure of the fire extinguishing gas. In addition to this, the pressure of the fire extinguishing gas is applied to the chemical solution to supply the chemical solution to the discharge unit 54, the fire extinguishing gas is supplied to the discharge unit 54, the chemical solution and the fire extinguishing gas are mixed in the discharge unit 54, and fire extinguishing bubbles are released. It can be done.

  In addition, an air conditioning duct can be used as a supply path for the fire extinguishing bubbles. By supplying the fire extinguishing bubbles to the air conditioning duct connected to the fire location in the event of a fire, the fire extinguishing gas can be reliably supplied to the fire location. By sealing the fire-extinguishing gas in the foam, the fire-extinguishing gas is surely supplied without being diluted by the convection in the supply path.

  In addition, as a method of generating a fire extinguisher, it is possible to release the chemical with a pressurized fire extinguishing gas and supply the fire extinguishing foam in a mousse form. The fire extinguishing gas and the chemical solution are stirred at atmospheric pressure to extinguish the foam. It is also possible to enlarge the bubbles. By reducing the particle size of the foam, the amount of the chemical solution for the fire extinguishing gas can be increased, and by increasing the particle size, the amount of the chemical solution for the fire extinguishing gas can be reduced. It is also possible to supply a fire extinguishing bubble having a large particle size to a place where a rescuer is likely to exist, and to scavenge toxic gas or smoke and supply a fire extinguishing gas to a rescuer.

  Next, the smoke exhausting action by the fire extinguishing foam will be described with reference to FIG. As shown in FIG. 13A, smoke is generated by the occurrence of a fire and fills the room. The fire is detected by the sensor 55, and as shown in FIG. Since the fire extinguishing gas discharged from the discharge unit 54 is covered with bubbles, the fire extinguishing gas is not easily affected by convection and diffusion of indoor air. Furthermore, since the fire extinguishing gas is supplied from the fire extinguishing gas storage unit 50, the smoke 56 and the toxic gas in the room are discharged to the outside by the supply of the fire extinguishing gas. And as shown in FIG.13 (c), a fire extinguishing bubble covers a combustion location and it extinguishes fire, and exhausts toxic gas and smoke 56. FIG. Since the fire-extinguishing gas is enclosed in the fire-extinguishing foam, combustion is suppressed by the fire-extinguishing gas, and it is possible to effectively extinguish the fire by including a fire extinguishing agent in the fire-extinguishing foam.

  By supplying the fire extinguishing gas in a bubble and supplying it to the fire location, it is possible to suppress the diffusion of the fire extinguishing gas and to prevent the inflow of fresh air into the fire location. Moreover, when extinguishing a fire with the fire extinguishing gas and extinguishing with a component contained in the foam, the amount of the chemical contained in the foam can be reduced. Thereby, it becomes possible to keep a medicine to the minimum necessary. And while the process after a fire extinguishing operation becomes easy, a chemical | medical agent storage part can be comprised compactly.

  Next, the structure which attached the discharge port 70 of the fire-extinguishing bubble to the lower part of the room is demonstrated using FIG. 14 and FIG. FIG. 14 is a view showing an example in which a fire-fighting bubble outlet is attached to the lower part of the room, and FIG. The fire-fighting bubble supply system shown in FIG. 14 has a fire-fighting bubble discharge port disposed in the lower part of the room, and is composed of a fire-extinguishing gas storage unit 50, a drug storage unit 100, a branch pipe 5, a drug supply pipe 101, and a discharge port 70. Has been. A fire extinguishing gas is supplied from the fire extinguishing gas storage unit 50 to generate bubbles at the discharge port 70, and the fire extinguishing bubbles are supplied indoors. The fire extinguishing gas storage unit 50 is connected to the drug storage unit 100 and the discharge port 70 via the branch pipe 5 and the pipe 81. The medicine storage unit 100 is connected to the discharge port 70 by a medicine supply pipe 101. The medicine storage unit 100 is pressurized with a fire extinguishing gas through a pipe 81, and the medicine is supplied to the discharge port 70 through the medicine supply pipe 101. At the discharge port 70, the chemical and the fire extinguishing gas are mixed to generate a fire extinguishing bubble. The fire extinguishing bubbles generated at the discharge port 70 are pushed out from the discharge port 70 by the supply of the fire extinguishing gas and supplied into the room. As the supply source of the fire extinguishing gas, in addition to the one stored in the gas cylinder, the above-described supply method can be used. This fire-extinguishing foam supply system generates fire-extinguishing foam by supplying fire-extinguishing gas, and can control the start of supply of fire-extinguishing foam by controlling the supply of fire-extinguishing gas. Thereby, the fire-extinguishing foam supply system can be configured with an easy configuration. In the configuration shown in FIG. 14, when the chemical solution in the drug storage unit 100 is pushed out to the discharge port 70 by supplying the fire extinguishing gas, the chemical solution is naturally supplied to the discharge port 70 by the siphon effect.

  Next, a process for supplying the fire-extinguishing foam when the fire-extinguishing foam outlet is arranged in the lower part of the room in FIG. 15 will be described. By providing the fire-extinguishing foam outlet 70 in the lower part of the room, it is possible to quickly protect the rescuer 59 who has fallen on the floor from toxic gas or the like. Since the foam containing the fire extinguishing gas is supplied along the floor surface from the lower part, the distance to the rescuer 59 is short and can be quickly protected by the fire extinguishing foam. In FIG. 15 (a), a person falls to the floor and cannot escape on his own, becoming a rescuer 59. Smoke 56 and toxic gas generated by a fire are wound up by an updraft in a place with a flame. However, in some situations, gas that is heavier than the specific gravity of air, such as carbon dioxide, may spread along the floor. In many cases, the rescuer 59 who cannot escape by himself is mainly lying on the floor. For this reason, as shown in FIG.15 (b), the rescuer 59 can be protected rapidly by providing the discharge port 70 in the lower part of the room, and supplying the fire extinguishing foam 57. FIG. As shown in FIG. 15 (c), the volume of foam necessary to protect the rescuer 59 in the vicinity of the floor can be minimized. And the view of evacuees is less likely to be obstructed.

  Next, the configuration of the fire extinguisher foam generator will be described with reference to FIGS. 16 and 17. FIG. 16 is a diagram showing a fire-extinguishing bubble generator using the pressure of the fire-extinguishing gas, and FIG. 17 is a diagram showing a fire-extinguishing bubble generator using bubbling and a fan. The fire extinguisher foam generator shown in FIG. 16 includes a water storage tank 91, a foaming agent tank 92, and a discharge portion 93. A fire extinguishing gas branch pipe 5 is connected to each of the water storage tank 91, the foaming agent tank 92, and the discharge portion 93. The branch pipe 5 connected to the water storage tank 91 and the foaming agent tank 92 applies pressure to the water storage tank 91 and the foaming agent tank 92 to promote the discharge of water and the foaming agent. Pressure is applied to the water storage tank 91 and the foaming agent tank 92 by the fire extinguishing gas, and the water and the foaming agent are sent to the discharge unit 93 by this pressure. A pipe 81 connected to the branch pipe 5 and a pipe 82 connected to the discharge portion 93 are connected to the water storage tank 91. The pipe 81 is connected to the upper part of the water storage tank 91, and one end of the pipe 82 reaches the bottom of the water storage tank 91. A piping 81 connected to the branch pipe 5 and a piping 83 connected to the discharge portion 93 are connected to the foaming agent water tank 92. The pipe 81 is connected to the top of the foaming agent tank 92, and one end of the pipe 83 reaches the bottom of the foaming agent tank 92. Accordingly, when the fire extinguishing gas is supplied via the branch pipe 5, pressure is applied to the water storage tank 91 and the foaming agent tank 92, and water and the foaming agent are supplied to the discharge unit 93. In the discharge part 93, fire-extinguishing gas, water, and a foaming agent are mixed, and fire-extinguishing foam is discharged | emitted from the discharge port 94. FIG. Here, the fire extinguishing gas is used for pressurizing water and the foaming agent, and is also used for discharging the fire extinguishing foam. By comprising in this way, fire extinguishing foam can be easily discharged | emitted by supplying fire extinguishing gas, and fire extinguishing foam can be supplied only by supply of fire extinguishing gas.

  The structure of the other fire-extinguishing foam generator is demonstrated using FIGS. 17-20. FIG. 17A is a diagram showing a configuration of a bubble generator by bubbling, and FIG. 17B is a diagram showing a configuration of a foam generator using a fan. First, the structure of the fire-extinguishing foam generator using bubbling is demonstrated using Fig.17 (a). The fire extinguisher foam generator is constituted by a foaming agent container 60. A scavenging pipe 61, a foaming agent supply pipe 63, and a fire extinguishing gas supply pipe 62 are connected to the foaming agent container 60. A foaming agent is stored in the lower part of the foaming agent container 60. This foaming agent is supplied from a foaming agent supply pipe 63. A fire extinguishing gas supply pipe 62 is connected to the bottom of the foaming agent container 60, and bubbles are generated in the foaming agent by supplying the fire extinguishing gas. The generated foam is discharged from the outlet of the foaming agent container 60 by the fire extinguishing gas supplied from the scavenging pipe 61. A certain amount of foaming agent is kept in the foaming agent container 60, and a fire extinguishing gas is supplied to the foaming agent and foamed and scavenging is performed to quickly generate fire extinguishing foam and discharge the fire extinguishing foam. Depending on the situation, it is possible to stop the discharge of the extinguishing gas, supply only the extinguishing gas from the extinguishing gas supply pipe 62, and exhaust the extinguishing foam.

  18 is a view showing a foam generator using a mesh and a fan, and FIG. 19 is a cross-sectional view and a perspective view of the same. The bubble generator using a mesh and a fan is demonstrated using FIG. 18 and FIG. The foam generator 110 blows air to the mesh 112 and injects a fire extinguishing gas and a foaming agent onto the mesh 112 to generate a fire extinguishing foam. The foam generator 110 includes a cylinder 111, a mesh 112, a fan 116, a motor 117, a power cable 115, a fire extinguishing gas pipe 114, and a foaming agent pipe 113. The fan 116 is driven by the motor 117 to blow air in the direction of the mesh 112, and fire extinguishing bubbles are generated by injecting a fire extinguishing gas and a foaming agent toward the mesh 112. A foaming agent film is formed on the mesh 112 by spraying the foaming agent onto the mesh 112, and bubbles of the foaming agent are generated by air supply. As the fire extinguishing gas supplied to the foam generator 110, it is possible to use the fire extinguishing gas with reduced oxygen concentration as described above, and the gas supplied into the cylinder 111 can be used as the fire extinguishing gas. is there. Moreover, what becomes fire extinguishing gas by mixing with the air sent from the fan 116 can also be utilized. Furthermore, it is also possible to drive the fan 116 by supplying a fire extinguishing gas using the motor 117 as an air motor. In this case, the foam generator can be controlled by supply control of the fire extinguishing gas.

  FIG. 20 is a side sectional view of a foam generator using a mesh and a fire extinguishing gas released. The foam generator 120 generates foam by applying a foaming agent to a mesh and sending a fire extinguishing gas thereto. The foam generator 120 includes a mesh 122, a cylinder 121, a foaming agent pipe 123, and a fire extinguishing gas pipe 124. A mesh 122 is attached to the front of the cylinder 121, and a foaming agent is supplied into the cylinder 121 through a foaming agent pipe 123. The foaming agent is sprayed onto the mesh 122 by a nozzle in the cylinder 121. A fire extinguishing gas pipe 124 is connected to the rear portion of the cylinder 121, and the fire extinguishing gas is supplied into the cylinder 121 through this pipe. By blowing a foaming agent onto the mesh 122 and supplying a fire extinguishing gas, a fire extinguishing foam containing the fire extinguishing gas is generated. A method of supplying the foaming agent by pressurization using a fire extinguishing gas, a method of supplying from a chemical tank disposed in the upper part of the building, and the like can be used. Moreover, the state of the foam generated can be adjusted by the pressure of the supplied fire extinguishing gas and the supply amount of the foaming agent, and can be adjusted according to the environment in which the foam generator 120 is disposed.

  FIG. 21 is a schematic view showing the action of bubbles containing fire extinguishing gas. As shown in FIG. 21, the fire extinguishing bubbles 57 cover the flame 58, so that new air does not flow in and the fire extinguishing gas is reliably supplied to the flame 58. Even when there is a rescuer 59, the rescuer 59 can be protected from toxic gas by covering with the fire extinguishing foam 57. Since the fire extinguishing gas has an oxygen concentration of 10% to 15%, fire extinguishing is performed while maintaining the life of the rescuer 59. And by supplying this gas with a bubble, the convection of the toxic gas by combustion can be prevented and a fire extinguishing gas can be supplied to a combustion location, without diffusing. In addition, fire extinguishing gas can be reliably supplied to the fire site, and smoke and toxic gases from fire can be discharged.

The schematic diagram which shows the whole structure of a fire extinguishing gas supply system. The schematic diagram which shows the connection structure of the fire extinguishing equipment in a fire extinguishing gas supply system. The figure which shows the internal structure of a common groove and nitrogen gas piping. The figure which shows the structure of the storage facility of fire extinguishing gas. The figure which shows the scavenging structure by fire extinguishing equipment. The schematic diagram which shows the structure of a sprinkler installation. The figure which shows the supply structure of the fire extinguishing gas using an oxygen separator. The schematic diagram which shows an example of the supply structure of fire extinguishing gas. The figure which shows the storage structure in a coastal part. The figure which shows the compression structure of the fire extinguishing gas in a coastal part. The figure which shows the structure which utilizes a water pipe as supply piping of fire extinguishing gas. The perspective view which shows the fire extinguishing gas supply system which discharge | releases foam. The schematic diagram which shows the smoke exhaustion effect | action by the bubble which contains fire extinguishing gas. The figure which shows the example which attached the fire-extinguishing bubble discharge port to the indoor lower part. The figure which shows the fire extinguishing process of the fire extinguishing foam of the indoor lower part. The figure which shows the generator of the fire-extinguishing bubble using the pressure of fire-extinguishing gas. The figure which shows the generator of the fire-fighting bubble using a bubbling and a fan. The figure which shows the foam generator using a mesh and a fan. Similarly a cross section and a perspective view. Side surface sectional drawing of the foam generator using the fire extinguishing gas emitted with a mesh. The schematic diagram which shows the effect | action of the foam which contains fire extinguishing gas.

Explanation of symbols

1 Nitrogen tank 2 Vaporizer 3 Piping 4 Fire extinguishing purpose 5 Branch pipe

Claims (2)

  A fire extinguishing gas storage facility for storing an inert fire extinguishing gas mainly containing nitrogen at an oxygen concentration of 10% to 15%, a fire extinguishing gas release facility disposed on a fire prevention object, the fire extinguishing gas storage facility, and a fire extinguishing gas release A fire extinguishing gas comprising a piping facility connected to the facility and configured to discharge an inert fire extinguishing gas mainly composed of nitrogen at an oxygen concentration of 10% to 15% from the fire extinguishing gas discharge facility Supply system.   The fire extinguishing gas supply system according to claim 1, wherein the inert fire extinguishing gas is used as a pressure source of a fire extinguishing agent discharge facility disposed on a fire prevention object.

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