JP2008005998A - Fire extinguishing equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide fire extinguishing equipment capable of quickly extinguishing the combustion of a nitroso compound. <P>SOLUTION: The fire extinguishing equipment has fire extinguishing agent radiation nozzles 22 for radiating a fire extinguishing agent to the fire of the nitroso compound. The fire extinguishing agent radiation nozzle 22 radiates one, two or more fire extinguishing agents among a water-based fire extinguishing agent containing ammonium phosphate, a water-based fire extinguishing agent containing potassium carbonate, a fluorinated ketone fire extinguishing agent, and the powder fire extinguishing agents of first, second, third and fourth kinds. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to fire extinguishing equipment mainly intended for extinguishing fires caused by nitroso compounds.

  In facilities that store or handle more than a certain amount of Class 5 hazardous materials, fire extinguishers shall install fire extinguishers, fire hydrant equipment or fixed fire extinguishing equipment as sprinkler equipment, foam fire extinguishing equipment, etc. It has become. And this kind of fire extinguishing equipment, for example, “a closed foam head senses a fire and opens a pressure switch that intervenes in the middle of the water supply pipe detects a decompression phenomenon in the water supply pipe and sends this signal to the control panel. The starting container is activated by the control panel, the gas pressure from the gas container for pressurization is sent to the fire extinguishing agent tank, the aqueous foam solution in the foam extinguisher tank is pressurized, and the aqueous foam solution from the foam extinguishing agent tank is closed through the water supply pipe It has been proposed that an aqueous foam solution is foamed and discharged from the closed type foam head.

JP 2001-346899 A (summary)

  By the way, nitroso compounds (powder form) among Class 5 hazardous materials are easily ignited even with small seed fires such as sparks, and once ignited, self-thermal decomposition is generated by the combustion heat to generate flammable gas, and continuously. It burns, and the pyrolysis rate is fast, and it becomes like a gas jet fire. For this reason, it was difficult to extinguish the combustion flame of the nitroso compound itself even though the spread of fire to the surroundings could be suppressed by spraying water or bubbles. For this reason, in the fire extinguishing equipment proposed in the above-mentioned Patent Document 1, it is difficult to extinguish the combustion of dangerous materials itself, even if the spread of water by sprinklers and bubbles can suppress the spread of fire to the surroundings. There was a problem that it was difficult to extinguish the fire until the reaction of the object itself ended.

  The present invention has been made to solve such problems, and an object of the present invention is to provide a fire extinguishing facility that can quickly extinguish the combustion of a nitroso compound.

The fire extinguishing equipment according to the present invention includes a fire extinguishing agent radiation nozzle that radiates a fire extinguishing agent to a nitroso compound fire, and the fire extinguishing agent radiation nozzle includes an aqueous phosphate containing ammonium phosphate and an aqueous fire extinguishing agent containing potassium carbonate. , Fluorinated ketone extinguishing agents, and one, a plurality of extinguishing agents among the first, second, third and fourth powder extinguishing agents.
In the fire-extinguishing equipment according to the present invention, the fire-extinguishing agent radiating nozzle may be one or more of a water-based fire extinguisher containing ammonium phosphate, a water-based fire extinguisher containing potassium carbonate, and a fluorinated ketone fire-extinguishing agent. The agent is emitted at a spraying density of ² L / m ² / min or more.
In the fire-extinguishing equipment according to the present invention, the fire-extinguishing agent radiating nozzle may be one or more of a water-based fire extinguisher containing ammonium phosphate, a water-based fire extinguisher containing potassium carbonate, and a fluorinated ketone fire-extinguishing agent. The agent is emitted at a radiation pressure of 0.2 MPa or more.
In the fire-extinguishing equipment according to the present invention, the fire-extinguishing agent radiating nozzle may spray one or a plurality of fire-extinguishing agents among the first, second, third, and fourth powder extinguishing agents at a spray density of 0.15 kg / Radiates at m ² / sec or more.
Moreover, in the fire extinguishing equipment according to the present invention, the fire extinguishing agent radiation nozzle is composed of a spray nozzle having no deflector.
In the fire-extinguishing equipment according to the present invention, the fire-extinguishing agent radiating nozzle is disposed immediately above a container or region for storing or handling a nitroso compound within the radiating range.

In the present invention, a water-based fire extinguisher containing ammonium phosphate (such as water containing a wetting agent), a water-based fire extinguisher containing potassium carbonate (such as a strengthening liquid), a fluorinated ketone fire extinguisher (Novec ^TM 1230), the first Combustion of the nitroso compound can be quickly extinguished by radiating one or more of the types 2, 2, 3 and 4 types of powder extinguishing agents.
In the present invention, an aqueous fire extinguisher containing ammonium phosphate, an aqueous fire extinguisher containing potassium carbonate, and a fluorinated ketone fire extinguisher are spray density of ² L / m ² / min or more (more preferably 5 L / m). It has been confirmed by fire-fighting experiment data that the combustion of nitroso compounds can be extinguished quickly if emitted at ² / min or higher. Moreover, the combustion of the nitroso compound is similar to the gas jet fire as described above, and the combustion of the nitroso compound can be quickly extinguished by setting the radiation pressure of the nozzle to 0.2 MPa or more.
In addition, for Type 1, 2, 3 and 4 powder extinguishing agents, based on the same experimental data, radiating at a spraying density of 0.15 kg / m ² / sec or more to burn nitroso compounds. Can be extinguished quickly.
Moreover, as a form of the extinguishing agent radiation nozzle, it is possible to overcome the momentum of injecting combustible pyrolysis gas by using a type without a deflector, that is, a full cone or holo cone type spray nozzle, Thereby, the combustion of the nitroso compound can be quickly extinguished.
Furthermore, the radiation range of the fire extinguishing agent radiation nozzle is a storage, a hopper, a belt conveyor, etc., and by arranging a plurality of fire extinguishing agent radiation nozzles to include the fire extinguishing agent radiation range, the combustion of the nitroso compound Can be extinguished quickly.

Embodiment 1. FIG.
FIG. 1 is a system diagram of a fire extinguishing facility using a liquid fire extinguisher according to Embodiment 1 of the present invention. In the figure, for example, in a rubber product manufacturing factory, a storage box 10 stores a container 12 containing, for example, a nitroso compound 11. The nitroso compound 11 in the container 12 is transferred to a hopper 13 and supplied onto a belt conveyor 15 by an automatic feeder 14 provided below the hopper 13. The belt conveyor 15 transfers the nitroso compound 11 and supplies it to the manufacturing apparatus 16. The manufacturing apparatus 16 manufactures a predetermined rubber product using the nitroso compound 11 and other raw materials.

  Fire detectors 21 are arranged on the ceiling side of the manufacturing plant in FIG. A plurality of fire extinguishing agent radiation nozzles 22 are arranged on the ceiling side of the storage 10, on the hopper 13 and on the belt conveyor 15. The fire extinguishing agent radiation nozzle 22 has a container or region in which the nitroso compound 11 is stored or handled in a lump or powder form as a radiation range, and as described above, the storage 10, the hopper 13 and the belt conveyor 15 are included in the radiation range. As described above, a plurality of extinguishing agent radiation nozzles 22 are arranged. Further, for example, when there is a region where the scattered powdered nitroso compound may be deposited, the fire extinguishing agent radiation nozzle 22 is also installed in such a region.

As the fire detector 21, a flame detector is usually used. The output of the fire detector 21 is output to the fire receiver 23. The fire receiver 23 issues a fire alarm and displays a fire based on the output of the fire detector 21, and further outputs a fire occurrence signal to the control panel 24. . The fire extinguisher tank 25 stores a fire extinguisher which will be described later, and the pump 26 sends out the fire extinguisher based on a control command from the control panel 24. Further, the control panel 24 opens the release valve 27 provided on the downstream side of the pump 26. The extinguishing agent from the pump 26 is sent out to the extinguishing agent pipe 28 via the release valve 27. The fire extinguisher tank 25 includes, for example, a water-based fire extinguisher containing ammonium phosphate (such as water containing an infiltrant), a water-based fire extinguisher containing potassium carbonate (such as a strengthening liquid), and a fluorinated ketone fire extinguisher (Novec ^TM 1230). One or more extinguishing agents are stored.

  The above-mentioned extinguishing agent radiation nozzle 22 is attached to the extinguishing agent pipe 28, and when a fire occurs, the above-mentioned extinguishing agent is emitted and directly applied to the nitroso compound 11. The fire detector 21 and the fire receiver 23 are connected by a fire detector wiring 31, and the detection output of the fire detector 21 is supplied to the fire receiver 23 via the fire detector wiring 31. The control panel 24 and the pump 26 are connected by a pump control wiring 32, and a control signal from the control panel 24 is supplied to the pump 26 via the pump control wiring 32. Further, the control panel 24 and the release valve 27 are connected by the release valve wiring 33, and a control signal from the control panel 24 is supplied to the release valve 27 via the release valve wiring 33.

  FIG. 2 is a view showing an arrangement example of the fire extinguishing agent radiation nozzle 22 with respect to the hopper 13. The extinguishing agent radiating nozzle 22 is preferably of a type without a deflector, and is a full cone or an empty cone (conical shape) that radiates the extinguishing agent in a full conical shape (a state in which the extinguishing agent is filled in the conical shape). It is desirable to use a holo-cone type spray nozzle that emits fire extinguishing agent in a state where the extinguishing agent is not filled in and there is a fire extinguishing agent only in the part corresponding to the outer surface. A nozzle is used. The extinguishing agent radiation nozzle (full cone nozzle) 22 is arranged so that the radiation area covers the entire area of the hopper 13.

  FIG. 3 is a view showing an arrangement example of the fire extinguishing agent radiation nozzle 22 with respect to the belt conveyor 15. The extinguishing agent radiation nozzle 22 is composed of a full cone nozzle, and is arranged in two examples at predetermined intervals along the length direction of the belt conveyor 15. The fire extinguishing agent radiation nozzle (full cone nozzle) 22 is arranged so that the radiation area covers almost the entire area of the belt conveyor 15 as shown in the figure.

Next, operation | movement of the fire extinguishing equipment of this Embodiment 1 is demonstrated.
(1) When the powdered nitroso compound 11 on the belt conveyor 15 in FIG. 1 burns for some reason and a fire occurs, the fire detector 21 is activated and outputs a fire detection signal to the fire receiver 23. When receiving the fire detection signal from the fire detector 21, the fire receiver 23 issues a fire alarm and displays a fire based on the fire detection signal, and further outputs a fire occurrence signal to the control panel 24.

(2) The control panel 24 displays a fire and outputs a control signal to the pump 26 and the release valve 27. As a result, the release valve 27 is released, and the pump 26 is activated to deliver the extinguishing agent in the extinguishing agent tank 25 to the extinguishing agent pipe 28. Thereby, a fire extinguisher is radiated | emitted from the fire extinguisher radiation nozzle 22, fire extinguishing activity continues, and it leads to fire extinguishing.

Examples of the fire extinguishing agent from the above-mentioned fire extinguishing agent radiation nozzle 22 include water-based fire extinguishing agents containing ammonium phosphate (water containing infiltrant, etc.), water-based fire extinguishing agents containing potassium carbonate (strengthening liquid, etc.), fluorinated ketone fire extinguishing In the case of liquid fire extinguishing agents such as the agent (Novec ^TM 1230), it has been confirmed that the fire can be extinguished by radiating it to a spraying density of ² L / m ² / min or more based on the fire extinguishing experiment data described later. The density is 5 L / m ² / min or more. Further, since the combustion of the nitroso compound is similar to a gas jet fire as described above, the radiation form of the fire extinguishing agent radiation nozzle 22 is superior to that of the deflector in order to overcome the momentum of the combustible pyrolysis gas jet. It is desirable to use a type that does not exist (full cone or holo cone type spray nozzle), and the radiation pressure is 0.2 MPa or more.

As described above, in Embodiment 1, a water-based fire extinguisher containing ammonium phosphate (such as water containing a wetting agent), a water-based fire extinguisher containing potassium carbonate (such as a strengthening liquid), a fluorinated ketone fire extinguisher (Novec By using a liquid fire extinguisher such as ^TM 1230), it is possible to extinguish the combustion of nitroso compounds quickly.

  In addition, in this Embodiment 1, although the example which the fire detector 21 act | operates was demonstrated, when a fire was discovered by the worker etc., a fire reception is performed by operating a manual starter (not shown). When the machine 23 captures the activation signal, the same operation as in the above example can be obtained. Although the description has been made on the assumption that the extinguishing agent radiation nozzle 22 is an open type, it goes without saying that a closed type nozzle which is also used as a fire detection means may be used. Further, the fire extinguisher pipe 30 may be filled with a fire extinguisher in advance.

  Further, in the above description of the first embodiment, the fire prevention section is not mentioned. However, if necessary, a fire prevention section is provided, and bubbles are generated from the fire extinguishing section or the fire extinguishing agent radiation nozzle 22 in the adjacent section including the fire generation section. A fire extinguishing liquid or the like may be emitted.

Embodiment 2. FIG.
FIG. 4 is a system diagram of a fire extinguishing facility using a powder fire extinguisher (first type, second type, third type, and fourth type) according to Embodiment 2 of the present invention. Here, the difference from the first embodiment will be mainly described. The extinguishing agent tank 25 stores a powder extinguishing agent, and the extinguishing agent powder in the extinguishing agent tank 25 is sent to the extinguishing agent pipe 28 by the pressurized gas in the pressurized gas container 40. A pressurized gas container release valve 41 is attached to the upper part of the pressurized gas container 40, and a pressure regulator 42 is provided between the pressurized gas container release valve 41 and the extinguishing agent tank 25. In addition, a starting gas container 43 for controlling the pressurized gas container opening valve 41 is provided, and a container valve opening device 44 is provided on the upper part thereof. The container valve opening device 44 and the control panel 24 are connected via an activation valve control wiring 45, and a control signal from the control panel 24 is supplied to the container valve opening device 44 via the activation valve control wiring 45. .

  Next, the operation of the fire extinguishing facility according to the second embodiment will be described. The operation is the same as in the first embodiment. However, when a fire occurs and the control panel 24 receives a fire occurrence signal from the fire receiver 23, the control panel 24 controls the opening valve 27 and the container valve opening device 44. Output a control signal. As a result, the release valve 27 is opened, and the activation gas container 43 is opened. When the starting gas container 43 is opened, the starting gas is supplied to the pressurized gas container opening valve 41 and the pressurized gas container opening valve 41 is opened. When the pressurized gas container release valve 41 is opened, the pressurized gas container 40 is opened and the pressurized gas is supplied to the fire extinguisher tank 25, and the powder fire extinguisher in the fire extinguisher tank 25 is pressurized to the fire extinguisher pipe 28. Send it out. And a powder fire extinguisher is radiated | emitted from the fire extinguisher radiation | emission nozzle 22. FIG. Thereby, the combustion of the nitroso compound can be quickly extinguished.

Powder of sodium hydrogen carbonate (first type), potassium hydrogen carbonate (second type), ammonium phosphate (third type), sodium hydrogen carbonate and urea reaction product (fourth type) In the case of a fire extinguisher, it is desirable to radiate so that the spray density is 0.15 kg / m ² / sec or more based on the fire extinguishing experiment data similar to that of the first embodiment.

Example 1.
(Fire extinguishing test method)
Fire model: Molded to 3.0kg nitroso compound powder, 33cm in diameter x 7cm in height Ignition method: Lighted with a lighter in the center of the upper surface of the above-mentioned nitroso compound mixed powder fire extinguishing method: Full cone at a height of 2m directly above the fire model Install a nozzle, extinguishant,
Fire extinguishing with different spraying density and radiation pressure. Also, pressurize in the case of powder
The fire extinguisher was put into a fire extinguisher and the fire density was adjusted by changing the distance from the model and extinguishing the fire.
.
Extinguishing media: Water containing 3 types of infiltrant (containing ammonium phosphate), strengthening liquid (potassium carbonate)
Novec ^TM 1230 (fluorinated ketone extinguishing agent), powder extinguishing agent (type 2,
Type 3)
Comparative example: Water, water film foam extinguishing agent (3%) aqueous solution

FIG. 5 shows the results of the above test. For three kinds of infiltrating water, fortification liquid and Novec ^TM 1230, the spraying density is ² L / m ² / min or more and / or the radiation pressure is 0.2 MPa or more. It can be seen that the fire can be extinguished reliably. In addition, powder fire extinguishing agents (type 2 and type 3) can be extinguished reliably and quickly at a spraying density of 0.15 L / m ² / min or more.

It is a systematic diagram of the fire extinguishing equipment using the liquid fire extinguisher concerning Embodiment 1 of the present invention. It is the figure which showed the example of arrangement | positioning of the fire extinguisher radiation nozzle with respect to a hopper. It is the figure which showed the example of arrangement | positioning of the extinguishing agent radiation | emission nozzle with respect to a belt conveyor. It is a systematic diagram of the fire extinguishing equipment using the powder fire extinguisher which concerns on Embodiment 2 of this invention. It is the figure which showed the test result of the spraying density of a fire extinguishing agent, radiation pressure, and fire extinguishing time.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Storage, 11 Nitroso compound, 12 Container, 13 Hopper, 14 Automatic feeder, 15 Belt conveyor, 16 Manufacturing apparatus, 21 Fire detector, 22 Extinguishing agent radiation nozzle, 23 Fire receiver, 24 Control panel, 25 Extinguishing agent Tank, 26 Pump, 27 Opening valve, 28 Fire extinguisher piping, 31 Fire detector wiring, 32 Pump control wiring, 33 Opening valve wiring, 40 Pressurized gas container, 41 Pressurized gas container opening valve, 42 Pressure regulator, 43 Gas container for starting, 43 Gas container for starting, 44 Container valve opening device, 45 Starting valve control wiring.

Claims (6)

Equipped with a fire extinguisher radiation nozzle that radiates the fire extinguisher in a nitroso compound fire
The fire-extinguishing radiant nozzle is composed of an aqueous phosphate containing ammonium phosphate, an aqueous fire extinguisher containing potassium carbonate, a fluorinated ketone fire extinguisher, and first, second, third and fourth powder fire extinguishing agents. Fire extinguishing equipment that emits one or more extinguishing agents. The fire extinguisher radiation nozzle is composed of an aqueous phosphate containing ammonium phosphate, an aqueous fire extinguisher containing potassium carbonate, and a fluorinated ketone fire extinguisher. One or more extinguishing agents are sprayed at a density of ² L / m ² / min. The fire extinguishing equipment according to claim 1 radiating as described above.   The fire extinguishing agent radiation nozzle radiates one or a plurality of fire extinguishing agents at a radiation pressure of 0.2 MPa or more among aqueous fire extinguishing agents containing ammonium phosphate, aqueous extinguishing agents containing potassium carbonate, and fluorinated ketone extinguishing agents. The fire extinguishing equipment according to claim 1 or 2, wherein The fire extinguisher radiation nozzle emits one or more of the first, second, third and fourth powder fire extinguishing agents at a spraying density of 0.15 kg / m ² / sec or more. The fire extinguishing equipment according to claim 1, wherein   The fire-extinguishing equipment according to any one of claims 1 to 4, wherein the fire-extinguishing agent radiation nozzle includes a spray nozzle having no deflector. The fire extinguisher radiation nozzle is disposed immediately above a container or region for storing or handling a nitroso compound so that the radiation range is included in the fire extinguisher radiation nozzle. Facility.

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