JP3605277B2 - How to use inert gas fire extinguishing equipment - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides fire extinguishing by releasing an inert gas fire extinguishing agent stored in a gaseous state in a fire extinguishing agent storage container into a fire extinguishing target compartment and maintaining the concentration of the fire extinguishing agent in the fire extinguishing target compartment equal to or higher than the flame-extinguishing concentration. Gas fire extinguishing equipmentHow to useIt is about.
[0002]
[Prior art]
Conventionally, as a gas fire extinguishing system that extinguishes fire by extinguishing a fire extinguishing agent into the fire extinguishing compartment and maintaining the concentration of the fire extinguishing agent in the fire extinguishing compartment at or above the flame-extinguishing concentration, carbon dioxide, halon gas, etc. The use of such an inert gas has been put to practical use.
[0003]
By the way, when using an inert gas such as carbon dioxide or halon gas as a fire extinguishing agent, these fire extinguishing agents are liquefied under pressure and stored in a fire extinguishing system in a state filled in a fire extinguishing agent storage container consisting of a high-pressure gas container. In the event of a fire, carbon dioxide or halon gas is injected from the fire extinguishing agent storage container through piping by opening the container valve of the fire extinguishing agent storage container using appropriate electric or pneumatic means. It is sent to the head and discharged from the ejection head into the fire extinguishing target compartment. At this time, the inert gas such as carbon dioxide and halon gas is sent in a liquid state to the ejection head, and is vaporized at the moment when the gas is discharged from the ejection head into the fire extinguishing section, and becomes a gaseous state. To suppress the fire.
[0004]
Gas-based fire extinguishing equipment that uses inert gas such as carbon dioxide and halon gas can rapidly suppress the fire, hardly contaminates the fire extinguishing agent with fire extinguishing agents, and does not impair electrical insulation. In addition, the fire extinguishing agent can penetrate through gaps and exert a strong fire-extinguishing effect even on fire-extinguishing objects with a complicated structure, and the fire extinguishing agent has a long-term constant fire-extinguishing ability without aging. It is widely used not only for petroleum-related facilities and electric facilities, but also for general facilities.
[0005]
However, in recent years, problems relating to the depletion of the ozone layer have been raised on a global scale, and the production of fire extinguishing agents containing halogenated hydrocarbon components such as halon gas was discontinued in January 1994, resulting in practical use. I can no longer do it. Thus, excluding special fire extinguishing equipment using expensive rare gas such as argon, it can be said that the extinguishing agent currently used in gas fire extinguishing equipment is only carbon dioxide.
[0006]
On the other hand, fire extinguishing equipment using this carbon dioxide as a fire extinguishing agent is also known to have the following problems.
(1) The design concentration of carbon dioxide in the fire extinguishing target compartment at the time of fire extinguishing is about 35%. At this concentration, if a person is present in the fire extinguishing target compartment, the toxicity of carbon dioxide (narcotic ) May cause a situation involving human life.
(2) In the event of a fire, carbon dioxide is sent to the injection head in a liquid state, and when it is released from the injection head into the fire extinguishing target compartment, it evaporates and becomes a gaseous state. Saturated vapor pressure of indoor air decreases because heat of vaporization is taken away, moisture in the air is dewed, and static electricity is generated. As a result, the interior of the room is in a fog state, which is a hindrance to evacuation and rescue of people and fire extinguishing work, as well as condensation and static electricity, which may cause insulation failure or breakdown of electronic equipment, and may cause a serious secondary disaster. is there.
(3) Since the density of carbon dioxide is much higher than that of air, the carbon dioxide released into the fire extinguishing compartment stays in the lower part of the fire extinguishing compartment and the fire extinguishing effect is reduced. It is easy to dissipate outside from the lower opening.
(4) As issues related to global warming are raised on a global scale, the use of carbon dioxide may be restricted in the future, similar to halon gas.
[0007]
[Problems to be solved by the invention]
By the way, in order to solve many problems of the conventional gas-based fire extinguishing equipment, the present applicant firstly added nitrogen gas or nitrogen gas to perfluoroalkane (perfluorobutane (C) which does not destroy the ozone layer.₄F₁₀)), Hydrogenofluoroalkane (trifluoromethane (CHF₃), Heptafluoropropane (C₃HF₇) Or pentafluoroethane (C₂HF₅)) Or hydrogenofluorohalogenoalkane (iodotrifluoromethane (CF)₃I)) (hereinafter, these are collectively referred to as "fluorine-based compounds"), and a mixed gas (hereinafter, simply referred to as "mixed gas") in which at least one kind is mixed at a ratio of 10% by volume or less is used as a fire extinguishing agent. (Refer to JP-A-8-141102 and JP-A-8-243186).
[0008]
However, it has been found that the following problems also occur when nitrogen gas or a mixed gas is used as a fire extinguishing agent for gas fire extinguishing equipment.
(1) Nitrogen gas or mixed gas as a fire extinguishing agent for gas fire extinguishing equipment is used under pressure and stored in gaseous state. Compared with halon gas, the number of fire extinguisher storage containers required for extinguishing a fire extinguisher in a fire extinguisher compartment of the same volume is several times as large, and a large installation space for fire extinguisher storage containers is required.
(2) In order to reduce the number of fire extinguishing agent storage containers to be installed, it is necessary to increase the filling pressure of the inert gas fire extinguishing agent to be filled in the fire extinguishing agent storage container. In such a case, the secondary side equipment of the fire extinguishing equipment such as the selection valve, main pipe, branch pipe, injection head, etc. will also be subjected to the high gas pressure of the inert gas fire extinguishing agent. It is necessary to increase the cost, and the equipment cost becomes remarkably high, and it cannot be applied to existing equipment.
[0009]
The present invention solves the problem of an inert gas fire extinguishing system that uses an inert gas extinguishing agent stored in a gaseous state in a fire extinguisher storage container such as a nitrogen gas or a mixed gas as a fire extinguishing agent. Inert gas fire extinguishing equipment that can increase the filling pressure of inert gas fire extinguishing agent without increasing the pressure resistance grade of the secondary equipmentHow to useThe purpose is to provide.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, an inert gas fire extinguishing system of the first invention is provided.How to useShall release the inert gas extinguishing agent stored in gaseous state in the extinguishing agent storage container into the fire extinguishing target compartment, and maintain the concentration of the inert gas extinguishing agent in the extinguishing extinguishing compartment equal to or higher than the extinguishing concentration. Inert gas extinguishing system designed to extinguish fireHow to useIn the fire extinguisher storage containerAt 35 ° C. kgf / cm ² The inert gas extinguishing agent is now filled. As well asFor container valve of fire extinguisher storage containerTherefore, The gas pressure of the inert gasReduce the pressure according to the pressure-resistant grade of the secondary equipment of the fire extinguishing equipment and supply it to the secondary side of the fire extinguishing equipmentThat is the gist.
[0011]
The inert gas fire extinguishing equipment according to the second aspect of the present invention discharges the inert gas fire extinguishing agent stored in a gaseous state in the fire extinguishing agent storage container into the fire extinguishing target compartment, and discharges the inert gas fire extinguishing agent in the fire extinguishing target compartment. An inert gas fire extinguishing system that extinguishes the fire by maintaining the concentration above the quenching concentrationHow to useAtIn a fire extinguisher storage container at 35 ° C., 180 kgf / cm ² Filling with inert gas fire extinguishing agent above,In the collecting pipe connecting the extinguishing agent storage container and the selection valveArrangedSuppression valveBy, The gas pressure of the inert gasReduce the pressure according to the pressure-resistant grade of the secondary equipment of the fire extinguishing equipment and supply it to the secondary side of the fire extinguishing equipmentThat is the gist.
[0012]
In this case,Nitrogen gas can be used as an inert gas fire extinguisher.
[0013]
In this case,By using a suppression valve for the container valve of the extinguishing agent storage container or by installing a suppression valve in the collecting pipe connecting the extinguishing agent storage container and the selection valve, the inert gas extinguishing agent gas on the discharge side of the suppression valve can be used. The pressure can be regulated below the reference gas pressure specified by the gas pressure of the constant pressure gas source. Even when the filling pressure of the inert gas fire extinguisher is high, the inert gas No high gas pressure is applied.
In addition, the pressure control valve keeps the gas pressure of the inert gas fire extinguishing agent on the discharge side of the pressure suppressing valve until the pressure of the inert gas fire extinguishing agent in the fire extinguishing agent storage container falls below the reference gas pressure. Even if the pressure of the inert gas fire-extinguishing agent in the fire-extinguishing agent storage container drops due to the release of the inert gas fire-extinguishing agent, the discharge amount of the inert gas fire-extinguishing agent is kept constant. be able to.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described based on the illustrated examples.
[0015]
FIG. 1 shows the present invention.Apply1 shows a first embodiment of an inert gas fire extinguishing system.
[0016]
This embodiment shows an inert gas fire extinguishing system having three fire extinguishing target sections 6-1, 6-2, and 6-3.
This inert gas fire extinguishing equipment uses, for example, nitrogen gas as an inert gas fire extinguishing agent, pressurizes it and fills it with a high-pressure gas container (at 180 ° C. at 35 ° C., 180 kgf / cm).²) Is used as a fire extinguisher storage container 1 by storing it in a fire extinguishing facility.
The inert gas fire extinguishing equipment of this example is provided with five fire extinguishing agent storage containers 1-1, 1-2,... 1-5, and each container 1 is connected to a connecting pipe 3 via a container valve 2. And the connecting pipe 3 is connected to one collecting pipe 4, and the collecting pipe 4 is extended to each fire extinguishing target section 6-1, 6-2, 6-3. -2, 5-3.
Select valves 9-1, 9-2, 9-3 are provided in the main pipes 5-1, 5-2, 5-3 to select fire extinguishing target sections 6-1, 6-2, 6-3. Send an inert gas fire extinguisher.
The main pipes 5-1, 5-2 and 5-3 extending to the fire extinguishing target sections 6-1, 6-2 and 6-3 are respectively placed in the fire extinguishing target sections 6-1, 6-2 and 6-3. The branch pipes 8-1, 8-2, and 8-3 are connected to the branch pipes 8-1, 8-2, and 8-3. Are connected to a plurality of ejection heads 7-1, 7-2, 7-3 arranged at appropriate places.
[0017]
Incidentally, since the fire extinguishing target sections 6-1, 6-2, and 6-3 usually have different volumes, the amount of the inert gas fire extinguishing agent required to extinguish the fire naturally also differs.
For this reason, the diameters of the main pipes 5-1, 5-2, 5-3 are made different according to the volumes of the fire extinguishing sections 6-1, 6-2, 6-3. The inert gas fire extinguishing equipment is configured so that the number of fire extinguishing agent storage containers 1 corresponding to the fire extinguishing target sections 6-1, 6-2, and 6-3 is opened.
[0018]
Here, the number of fire extinguishing agent storage containers 1 to be opened is set to five for the fire extinguishing section 6-1, three for the fire extinguishing section 6-2, and one for the fire extinguishing section 6-3. .
In the figure, 9-1, 9-2, and 9-3 are selection valves, 10-1, 10-2, and 10-3 are selection valve opening devices, and 11-1, 11-2, and 11-3 are activated. Reference numerals 12-1, 12-2, and 12-3 denote solenoids for opening the starting gas container.
In the figure, 13-1, 13-2, and 13-3 open the selection valves 9-1, 9-2, and 9-3 and the starting gas containers 11-1, 11-2, and 11-3. The starting gas line to be controlled is connected to the selection valve opening devices 10-1, 10-2, and 10-3, and the non-return valves 14-1, 14-2, 14-3, and 14- A, 14-B are provided. The directions in which the non-return valves 14-1, 14-2, 14-3, 14-A and 14-B can pass are indicated by the directions of arrows in the figure.
The numbers 1, 2, and 3 at the end of these members correspond to the numbers 1, 2, and 3 at the end of the fire extinguishing section, respectively.
[0019]
In this case, the gas pressure P of the inert gas fire extinguishing agent on the discharge side of the container valve 2 shown in FIG. 2 is regulated to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source. Use a control valve.
The pressure control valve includes a flow path valve 22 having three guide members 22a provided in a flow path 21 for the inert gas fire extinguishing agent, and a flow path valve 22 in a direction to close the flow path 21 for the inert gas fire extinguishing agent. A biasing spring 23 and a constant pressure gas source (in the case of the present embodiment, nitrogen gas is charged as a constant pressure gas source (110 kgf / cm at 35 ° C.)²The starting gas containers 11-1, 11-2, and 11-3 described above are used. ), A piston 26 disposed in a cylinder 25 having one end connected to the gas supply port 24 and the other end connected to the discharge side of the flow path 21 for the inert gas fire extinguishing agent, An operating rod 27 formed at an end of a piston 26 for operating the flow path valve 22 in a direction to open the flow path 21 of the agent, and a spring 28 for urging the piston 26 in a direction opposite to the flow path valve 22. It was done.
[0020]
Next, the operation of the suppression valve will be described.
The gas pressure P1 (110 kgf / cm) is supplied from the starting gas containers 11-1, 11-2 and 11-3 as the constant pressure gas source to the gas supply port 24.²2), the piston 26 is moved against the urging force of the spring 28, and the operation valve 27 formed at the end of the piston 26 moves the flow path valve 22 against the urging force of the spring 23. By operating, the flow path 21 of the inert gas fire extinguishing agent is opened.
When the flow path 21 of the inert gas fire extinguishing agent is opened, the inert gas fire extinguishing agent flows into the flow path 21 from the fire extinguishing agent storage container 1 and the gas pressure of the inert gas fire extinguishing agent in the fire extinguishing agent storage container 1 is increased. P2 (180 kgf / cm at 35 ° C.)²) Acts on the other end of the piston 26, and the piston 26 moves in a direction in which the operation of the operation rod 27 to release the operation of the flow path valve 22, whereby the flow path valve 22 also receives the urging force of the spring 23. It moves in a direction to close the flow path 21 of the inert gas fire extinguishing agent.
However, on one end side of the piston 26, the gas pressure P1 (110 kgf / cm) of the starting gas containers 11-1, 11-2, and 11-3 is provided.²) Is acting, the flow path valve 22 does not completely close the flow path 21 of the inert gas fire extinguishing agent, and the flow path valve 22, the piston 26 and the operation rod 27 are instantaneously balanced, In the case of the embodiment, the gas pressure P of the inert gas fire extinguishing agent on the discharge side of the flow path 21 is the gas pressure P1 (110 kgf / cm) of the starting gas containers 11-1, 11-2, and 11-3.²).
In this case, the gas pressure P of the inert gas extinguishing agent on the discharge side held by the suppression valve, that is, the reference gas pressure P0 is a constant-pressure gas source, that is, the starting gas containers 11-1, 11-2, 11 -3, or a pressure regulator is provided in the starting gas containers 11-1, 11-2, and 11-3, and the gas pressure P1 is adjusted by the pressure regulator. , 28 can be changed by using springs having different spring constants or by changing the ratio of the upper diameter to the lower diameter of the piston 26. However, due to the design of the inert gas fire extinguishing equipment, the reference gas pressure P0 is It is desirable that the pressure is set to be equal to the gas pressure P1 of the constant pressure gas source.
The pressure control valve stops the supply of gas from the constant pressure gas source to the supply port 24 and discharges the gas in the cylinder 25 above the piston 26, thereby forming the flow path 21 of the inert gas fire extinguishing agent. The fire extinguisher storage container, which has been once opened, can be closed by utilizing this function, which has a function that can be closed.
[0021]
Then, as shown in FIG. 3, the pressure-reducing valve operates on the discharge side of the pressure-reducing valve until the pressure P2 of the inert gas fire-extinguishing agent in the fire-extinguishing agent storage container 1 falls below the reference gas pressure P0. Since it has a function of maintaining the gas pressure P of the gas fire extinguishing agent at the reference gas pressure P0, even when the pressure P2 of the inert gas fire extinguishing agent in the fire extinguishing agent storage container is reduced due to the release of the inert gas fire extinguishing agent. By maintaining the gas pressure P of the inert gas fire extinguishing agent on the discharge side of the suppression valve at the reference gas pressure P0, the amount of the inert gas fire extinguishing agent released can be kept constant.
FIG. 3 shows, as a comparative example, the gas pressure P ′ of the inert gas fire extinguisher on the discharge side of the container valve and the inert gas fire extinguisher in the fire extinguisher storage container when a container valve having a pressure reducing function is used. Although the relationship of the pressure P2 'is shown, in the case of a container valve having a pressure reducing function, when the pressure P2' of the inert gas fire-extinguishing agent in the fire-extinguishing agent storage container decreases due to the release of the inert gas fire-extinguishing agent, the container valve is discharged. Since the gas pressure P ′ of the inert gas fire extinguishing agent on the side also decreases in proportion thereto, the discharge amount of the inert gas fire extinguishing agent decreases (the difference from the case of the suppression valve is indicated by hatching). In order to discharge a predetermined amount of the inert gas fire extinguisher within the predetermined discharge time t0, the inside diameter of the pipe is increased or the degree of pressure reduction is reduced (the inert gas fire extinguisher on the discharge side of the original container valve). Need to increase the gas pressure P '), but this increases equipment costs. There is a problem to say.
[0022]
Next, the operation of the inert gas fire extinguishing system of the first embodiment in the event of a fire will be described.
Now, assuming that a fire has occurred in the fire extinguishing target section 6-1, when a fire discoverer operates the push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-1, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-1, and the solenoid 12-1 operates to open the starting gas container 11-1.
The starting gas released by opening the starting gas container 11-1 is first introduced into the selection valve opening device 10-1 to open the selection valve 9-1, and then the non-return valve 14- After passing through the starting gas pipeline 13-1 through the non-return valve 14-A and the non-return valve 14-B, all the fire extinguishing agent storage containers 1 are opened to all the container valves 2. At this time, since it cannot pass through the non-return valve 14-2 and the non-return valve 14-3, the selection valve 9-2 and the selection valve 9-3 are not opened.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. The reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-1 via the container valve 2, the connecting pipe 3, the collecting pipe 4, the selection valve 9-1, the main pipe 5-1 and the branch pipe 8-1. The fuel is discharged from the ejection head 7-1 into the fire extinguishing target section 6-1.
[0023]
Further, if a fire occurs in the fire extinguishing target section 6-2, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-2, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-2, and the solenoid 12-2 operates to open the starting gas container 11-2.
The starting gas released by opening the starting gas container 11-2 is first introduced into the selection valve opening device 10-2 to open the selection valve 9-2, and then the non-return valve 14- 2, through the starting gas line 13-2, through the non-return valve 14-B, to the container valve 2, and only three fire extinguisher storage containers 1, that is, fire extinguisher storage containers 1-3, 1 -4 and 1-5 are released.
At this time, since it cannot pass through the non-return valve 14-A, two of the extinguishing agent storage containers 1, that is, the extinguishing agent storage containers 1-1 and 1-2 are not opened.
Further, since the gas cannot pass through the non-return valve 14-1 and the non-return valve 14-3, the selection valve 9-1 and the selection valve 9-3 are not opened.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. From the three extinguishing agent storage containers 1-3, 1-4, and 1-5, the reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-2 via the container valve 2, the connection pipe 3, the collecting pipe 4, the selection valve 9-2, the main pipe 5-2, and the branch pipe 8-2. The fuel is discharged from the ejection head 7-2 into the fire extinguishing section 6-2.
[0024]
Further, if a fire occurs in the fire extinguishing section 6-3, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing section 6-3, an electric signal is output to open the starting gas container. The starting gas container 11-3 is opened by being sent to the solenoid 12-3.
The starting gas released by opening the starting gas container 11-3 is first introduced into the selection valve opening device 10-3 to open the selection valve 9-3, and then the non-return valve 14- After passing through 3 and passing through the starting gas pipeline 13-3 and reaching the container valve 2, only one extinguishing agent storage container 1 is opened, that is, the extinguishing agent storage container 1-5 is opened.
At this time, since it cannot pass through the non-return valve 14-B (and, of course, cannot also pass through the non-return valve 14-A), four of the fire-extinguishing agent storage containers 1 The containers 1-1, 1-2, 1-3, and 1-4 are not opened.
Further, since the gas cannot pass through the non-return valves 14-1 and 14-2, the selection valves 9-1 and 9-2 are not opened.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. From the single extinguishing agent storage container 1-5, the reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-3 via the container valve 2, the connecting pipe 3, the collecting pipe 4, the selection valve 9-3, the main pipe 5-3, and the branch pipe 8-3. Then, the fuel is discharged from the ejection head 7-3 into the fire extinguishing target section 6-3.
[0025]
As described above, the case where the number of fire extinguisher compartments is three and the number of fire extinguisher storage containers 1 is five has been described as an example. The number of containers 1 is not limited to that of the present embodiment (the same applies to the second and third embodiments described below), and can be set arbitrarily as needed.
[0026]
FIG.ApplyA second embodiment of the inert gas fire extinguishing equipment is shown.
[0027]
This embodiment is a modification of the first embodiment, and is filled with nitrogen gas as a constant-pressure gas source (110 kgf at 35 ° C.) separately from the starting gas containers 11-1, 11-2, and 11-3. / Cm²) Is provided with the constant pressure gas container 17 described above.
By using a constant pressure gas source in which a pressure regulator is provided in a gas container filled with a high-pressure gas, the pressure regulator can be used to adjust the gas pressure P1, or The constant-pressure gas source may be constituted by a high-pressure generator and an accumulator for maintaining the pressure generated by the high-pressure generator.
By providing the constant pressure gas container 17 in this manner, even if the number of fire extinguishing agent storage containers 1 to be installed, that is, the number of container valves (suppression valves) 2 increases, the capacity of the constant pressure gas container 17 is correspondingly increased. It can be easily changed, and the predetermined reference gas pressure P0 can be maintained.
In the figure, reference numerals 15-1, 15-2, 15-3 denote start-up gas pipelines 13-1, 14-2, 14-3 instead of the non-return valves 14-1, 14-2, 14-3 of the first embodiment. 13-2, 13-3 are piston valves, and 16-1, 16-2, 16-3 are starting gas containers 11-1, 11-2, 11-3 and a constant pressure gas container. This is a non-return valve placed in place between 17 The directions in which the non-return valves 16-1, 16-2, and 16-3 can pass are indicated by the directions of arrows in the figure.
The numbers 1, 2, and 3 at the end of these members correspond to the numbers 1, 2, and 3 at the end of the fire extinguishing section, respectively.
[0028]
Next, the operation of the inert gas extinguishing system of the second embodiment in the event of a fire will be described.
Now, assuming that a fire has occurred in the fire extinguishing target section 6-1, when a fire discoverer operates the push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-1, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-1, and the solenoid 12-1 operates to open the starting gas container 11-1.
The starting gas released by opening the starting gas container 11-1 is first introduced into the selection valve opening device 10-1 to open the selection valve 9-1, and then the non-return valve 16- 1 and the constant pressure gas container 17 is opened, and the piston valve 15-1 is opened.
Thus, the constant-pressure gas in the constant-pressure gas container 17 passes through the piston valve 15-1, the starting gas (constant-pressure gas) line 13-1, the non-return valve 14-A, and the non-return valve 14-B. All five extinguishing agent storage containers 1 are opened to all the container valves 2.
At this time, since the starting gas cannot pass through the non-return valve 16-2 and the non-return valve 16-3, the selection valve 9-2 and the selection valve 9-3, and the piston valve 15-2 and the piston valve 15 -3 is not released.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. The reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-1 via the container valve 2, the connecting pipe 3, the collecting pipe 4, the selection valve 9-1, the main pipe 5-1 and the branch pipe 8-1. The fuel is discharged from the ejection head 7-1 into the fire extinguishing target section 6-1.
[0029]
Further, if a fire occurs in the fire extinguishing target section 6-2, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-2, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-2, and the solenoid 12-2 operates to open the starting gas container 11-2.
The starting gas released by opening the starting gas container 11-2 is first introduced into the selection valve opening device 10-2 to open the selection valve 9-2, and then the non-return valve 16- 2 and the constant pressure gas container 17 is opened, and the piston valve 15-2 is opened.
Thus, the constant-pressure gas in the constant-pressure gas container 17 passes through the piston valve 15-2, passes through the starting gas (constant-pressure gas) line 13-2, passes through the non-return valve 14-B, reaches the container valve 2, and extinguishes the fire. Only three agent storage containers 1, that is, fire extinguisher storage containers 1-3, 1-4, and 1-5 are opened.
At this time, since it cannot pass through the non-return valve 14-A, two of the extinguishing agent storage containers 1, that is, the extinguishing agent storage containers 1-1 and 1-2 are not opened.
Further, since the starting gas cannot pass through the non-return valve 16-1 and the non-return valve 16-3, the selection valve 9-1 and the selection valve 9-3, and the piston valve 15-1 and the piston valve 15- 3 is not released.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. From the three extinguishing agent storage containers 1-3, 1-4, and 1-5, the reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-2 via the container valve 2, the connection pipe 3, the collecting pipe 4, the selection valve 9-2, the main pipe 5-2, and the branch pipe 8-2. The fuel is discharged from the ejection head 7-2 into the fire extinguishing section 6-2.
[0030]
Further, if a fire occurs in the fire extinguishing section 6-3, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing section 6-3, an electric signal is output to open the starting gas container. The starting gas container 11-3 is opened by being sent to the solenoid 12-3.
The starting gas released by opening the starting gas container 11-3 is first introduced into the selection valve opening device 10-3 to open the selection valve 9-3, and then the non-return valve 16- 3 and the constant pressure gas container 17 is opened, and the piston valve 15-3 is opened.
As a result, the constant-pressure gas in the constant-pressure gas container 17 passes through the piston gas 15-3 through the starting gas (constant-pressure gas) pipe line 13-3, reaches the container valve 2, and stores only one fire extinguisher storage container 1, that is, Then, the fire extinguisher storage container 1-5 is opened.
At this time, since it cannot pass through the non-return valve 14-B (and, of course, cannot also pass through the non-return valve 14-A), four of the fire-extinguishing agent storage containers 1 The containers 1-1, 1-2, 1-3, and 1-4 are not opened.
Further, since the starting gas cannot pass through the non-return valve 16-1 and the non-return valve 16-2, the selection valve 9-1 and the selection valve 9-2, and the piston valve 15-1 and the piston valve 15- 2 is not released.
By the way, the container valve 2 is opened because a pressure control valve for controlling the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant pressure gas source is used. From the single extinguishing agent storage container 1-5, the reference gas pressure P0 (110 kgf / cm²Inert gas regulated below is sent to the injection head 7-3 via the container valve 2, the connecting pipe 3, the collecting pipe 4, the selection valve 9-3, the main pipe 5-3, and the branch pipe 8-3. Then, the fuel is discharged from the ejection head 7-3 into the fire extinguishing target section 6-3.
[0031]
FIG.ApplyA third embodiment of the inert gas fire extinguishing equipment is shown.
[0032]
This embodiment is a modified example of the first embodiment. In the present embodiment, the discharge pipe is provided at an appropriate position of the collecting pipe 4 connecting the fire extinguisher storage container 1 and the selection valves 9-1, 9-2, 9-3. A pressure control valve 18 for regulating the gas pressure P of the active gas extinguishing agent to a reference gas pressure P0 or less defined by a gas pressure P1 of a constant pressure gas source is provided, and a starting gas container 11-1, 11-2, 11-3. Separately, a nitrogen gas is charged as a constant-pressure gas source (110 kgf / cm at 35 ° C.).²) Is provided with the constant pressure gas container 19 described above.
Note that, as in the first embodiment, the starting gas containers 11-1, 11-2, and 11-3 are configured to be used as the constant-pressure gas source, or the high-pressure gas container is filled with the high-pressure gas. By using a pressure regulator provided with a regulator, the gas pressure P1 can be regulated by the pressure regulator, or the constant pressure gas source can be controlled by a high pressure generator and a pressure generated by the high pressure generator. It can also be configured with a holding accumulator.
Thus, by providing the pressure-reducing valve 18 in the collecting pipe 4, a normal container valve can be used as the container valve 2, and the equipment cost can be reduced. In addition, high gas pressure of the inert gas fire extinguisher is applied to the primary devices of the fire extinguishing equipment such as the container valve 2, the connecting pipe 3, and the collecting pipe 4 from the extinguishing agent storage container 1 to the suppression valve 18. For this reason, these primary devices need to be configured to withstand this high gas pressure. However, the collecting pipe 4 and the like have a smaller inner diameter than the main pipes 5-1, 5-2, and 5-3. Therefore, the pressure resistance is high, and therefore, it is not necessary to increase the pressure resistance grade of the primary equipment of the fire extinguishing equipment, so that the equipment cost can be reduced and the existing equipment can be applied as it is.
The numbers 1, 2, and 3 at the end of these members correspond to the numbers 1, 2, and 3 at the end of the fire extinguishing section, respectively.
[0033]
As shown in FIG. 6, the pressure control valve 18 has basically the same structure and operation as those of the pressure control valve used in the container valve 2 of the first embodiment. A flow path valve 182 provided in the passage 181, a spring 183 for urging the flow path valve 182 in a direction to close the flow path 181 of the inert gas fire extinguishing agent, a gas supply port 184 from the constant pressure gas container 19, To a gas supply port 184, a piston 186 disposed in a cylinder 185 having the other end connected to the discharge side of the flow path 181 for the inert gas fire extinguishing agent, and a direction to open the flow path 181 for the inert gas fire extinguishing agent. An operation rod 187 formed at an end of a piston 186 for operating the flow valve 182 and a spring 188 for urging the piston 186 in a direction opposite to the flow valve 182 are provided. The gas pressure P of the active gas extinguishing agent is changed to the gas of the constant pressure gas source. P1 is obtained so as to regulate below the reference gas pressure P0 defined by.
[0034]
Next, the operation of the inert gas extinguishing system of the third embodiment in the event of a fire will be described.
Now, assuming that a fire has occurred in the fire extinguishing target section 6-1, when a fire discoverer operates the push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-1, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-1, and the solenoid 12-1 operates to open the starting gas container 11-1.
The starting gas released by opening the starting gas container 11-1 is first introduced into the selection valve opening device 10-1 to open the selection valve 9-1, and then the non-return valve 14- 1, the constant-pressure gas container 19 is opened, the gas passes through the starting gas line 13-1, passes through the nonreturn valves 14-A and 14-B, reaches all the container valves 2, and stores the fire extinguishing agent. All five containers 1 are opened.
At this time, since it cannot pass through the non-return valve 14-2 and the non-return valve 14-3, the selection valve 9-2 and the selection valve 9-3 are not opened.
By the way, since the collecting pipe 4 is provided with the pressure control valve 18 for regulating the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant-pressure gas source, it is opened. The inert gas discharged from the five extinguishing agent storage containers 1 and sent to the collecting pipe 4 via the container valve 2 and the connection pipe 3 is supplied to the reference gas pressure P0 (110 kgf / cm²) Regulated below, sent to the injection head 7-1 via the selection valve 9-1, the main pipe 5-1 and the branch pipe 8-1, and discharged from the injection head 7-1 into the fire extinguishing target section 6-1. Is done.
[0035]
Further, if a fire occurs in the fire extinguishing target section 6-2, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing target section 6-2, an electric signal is output to open the starting gas container. Is sent to the solenoid 12-2, and the solenoid 12-2 operates to open the starting gas container 11-2.
The starting gas released by opening the starting gas container 11-2 is first introduced into the selection valve opening device 10-2 to open the selection valve 9-2, and then the non-return valve 14- 2 and open the constant-pressure gas container 19, and pass through the starting gas line 13-2, pass through the non-return valve 14-B, reach the container valve 2, and only three fire extinguishing agent storage containers 1, that is, The fire extinguishing agent storage containers 1-3, 1-4, and 1-5 are opened.
At this time, since it cannot pass through the non-return valve 14-A, two of the extinguishing agent storage containers 1, that is, the extinguishing agent storage containers 1-1 and 1-2 are not opened.
Further, since the gas cannot pass through the non-return valve 14-1 and the non-return valve 14-3, the selection valve 9-1 and the selection valve 9-3 are not opened.
By the way, since the collecting pipe 4 is provided with the pressure control valve 18 for regulating the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant-pressure gas source, it is opened. The inert gas discharged from the three fire extinguishing agent storage containers 1-3, 1-4, and 1-5 sent to the collecting pipe 4 through the container valve 2 and the connecting pipe 3 is supplied to the inert gas by the suppression valve 18. Reference gas pressure P0 (110 kgf / cm²) Is regulated below, is sent to the injection head 7-2 via the selection valve 9-2, the main pipe 5-2, and the branch pipe 8-2, and is discharged from the injection head 7-2 into the fire extinguishing target section 6-2. Is done.
[0036]
Further, if a fire occurs in the fire extinguishing section 6-3, when a fire discoverer operates a push button (in the case of manual operation) corresponding to the fire extinguishing section 6-3, an electric signal is output to open the starting gas container. The starting gas container 11-3 is opened by being sent to the solenoid 12-3.
The starting gas released by opening the starting gas container 11-3 is first introduced into the selection valve opening device 10-3 to open the selection valve 9-3, and then the non-return valve 14- 3, the constant pressure gas container 19 is opened, and only one fire extinguisher storage container 1 is passed through the starting gas pipeline 13-3 to the container valve 2, that is, the fire extinguisher storage container 1-5 is opened. .
At this time, since it cannot pass through the non-return valve 14-B (and, of course, cannot also pass through the non-return valve 14-A), four of the fire-extinguishing agent storage containers 1 The containers 1-1, 1-2, 1-3, and 1-4 are not opened.
Further, since the gas cannot pass through the non-return valves 14-1 and 14-2, the selection valves 9-1 and 9-2 are not opened.
By the way, since the collecting pipe 4 is provided with the pressure control valve 18 for regulating the gas pressure P of the discharge side inert gas fire extinguishing agent to a reference gas pressure P0 defined by the gas pressure P1 of the constant-pressure gas source, it is opened. The inert gas discharged from the single fire extinguishing agent storage container 1-5 and sent to the collecting pipe 4 via the container valve 2 and the connecting pipe 3 is supplied to the reference gas pressure P0 (110 kgf / cm²) Regulated below, sent to the injection head 7-3 through the selection valve 9-3, the main pipe 5-3 and the branch pipe 8-3, and discharged from the injection head 7-3 into the fire extinguishing section 6-3. Is done.
[0037]
【The invention's effect】
According to the present invention, the filling pressure of the inert gas fire extinguishing agent can be increased without increasing the pressure resistance grade of the secondary device of the fire extinguishing equipment, the installation space for the fire extinguishing agent storage container can be reduced, In addition to the fact that it is not necessary to increase the pressure resistance grade of the secondary equipment, the equipment costs can be reduced, and there is no need to increase the pressure resistance grade of the secondary equipment of the fire extinguishing equipment. The inert gas fire extinguishing agent stored in a gas state in the storage container can be applied to existing equipment as it is.
Note thatUntil the pressure of the inert gas fire-extinguishing agent in the fire-extinguishing agent storage container falls below the reference gas pressure, the gas pressure of the inert gas fire-extinguishing agent on the discharge side of the pressure-control valve is reduced to the reference gas pressure. Because it has the function of retaining, even if the pressure of the inert gas fire-extinguishing agent in the fire-extinguishing agent storage container drops due to the release of the inert gas fire-extinguishing agent, keep the amount of the released inert gas fire-extinguishing agent constant. Therefore, the capacity of the fire extinguishing equipment can be effectively used, and the equipment cost can be reduced.
[Brief description of the drawings]
FIG. 1 shows the present invention.ApplyIt is a figure which shows the 1st Example of inert gas fire extinguishing equipment.
FIG. 2Suppression valve for inert gas fire extinguishing equipmentFIGS. 3A and 3B are diagrams showing a first embodiment of the present invention, in which FIG. 3A is an overall view, FIG. 3B is a plan view of a flow path valve, and FIG.
FIG. 3 is an explanatory diagram of an operation of a suppression valve for an inert gas fire extinguishing equipment.
FIG. 4 shows the present invention.ApplyIt is a figure which shows the 2nd Example of the inert gas fire extinguishing equipment.
FIG. 5 The present inventionApplyIt is a figure which shows the 3rd Example of inert gas fire extinguishing equipment.
FIG. 6Suppression valve for inert gas fire extinguishing equipmentIt is a figure showing the 3rd Example of.
[Explanation of symbols]
1 Fire extinguisher storage container
2 Container valve (suppression valve)
21 Inert gas extinguishing agent flow path
22 Flow valve
23 spring
24 Gas supply port
25 cylinder
26 piston
27 Operation stick
28 spring
6 fire extinguishing target compartment
7 Injection head
11 Startup gas container (constant pressure gas source)
17 Constant pressure gas container
18 Suppression valve
181 Inert gas extinguishing agent flow path
182 Flow valve
183 spring
184 gas supply port
185 cylinder
186 piston
187 Operation stick
188 spring
19 Constant pressure gas container
P Gas pressure of inert gas fire extinguishing agent
P0 Reference gas pressure
P1 Gas pressure of constant pressure gas source

Claims (3)

Extinguishes by releasing the inert gas extinguishing agent stored in gaseous form in the extinguishing agent storage container into the fire extinguishing target compartment and maintaining the concentration of the inert gas extinguishing agent in the fire extinguishing target compartment equal to or higher than the flame-extinguishing concentration. in use of the inert gas fire extinguishing system which is adapted to fire extinguisher storage vessel, at 35 ° C., to fill the inert gas extinguishing agents in 180 kgf / cm ² or more, depending on the container valve of the fire extinguishing agent storage vessel, A method for using an inert gas fire extinguishing system , characterized in that the gas pressure of the discharge side inert gas fire extinguishing agent is reduced and supplied to the secondary side of the fire extinguishing system according to the pressure resistance grade of the secondary device of the fire extinguishing system . . Extinguishes by releasing the inert gas extinguishing agent stored in gaseous form in the extinguishing agent storage container into the fire extinguishing target compartment and maintaining the concentration of the inert gas extinguishing agent in the fire extinguishing target compartment equal to or higher than the flame-extinguishing concentration. In the method of using the inert gas fire extinguishing equipment described above , the extinguishing agent storage container is filled with the inert gas extinguishing agent at 35 ° C. at 180 kgf / cm ² or more, and the extinguishing agent storage container is connected to the selection valve. by Suppression valve disposed in the collecting pipe to, the supply to the secondary side of the fire fighting equipment in vacuo according to the gas pressure of the inert gas fire extinguishing agent releasing side pressure-resistant grade of secondary device of the fire-extinguishing system How to use inert gas fire extinguishing equipment. 3. The method for using an inert gas fire extinguishing system according to claim 1, wherein nitrogen gas is used as the inert gas fire extinguishing agent.

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