JP2009056044A - Fire extinguisher - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fire extinguisher, wherein it is not necessary to install a pressure gas cylinder, while man-power for inspection is reduced and the maintenance cost is reduced. <P>SOLUTION: The fire extinguisher includes an extinguisher main body 1 and an open injection head 2. Inside the extinguisher main body 1, a storage tank 4 for storing a fire extinguishing agent is provided, wherein the storage tank 4 is connected to an air compressor 5 and can be pressurized. The storage tank 4 is also connected to the open type injection head 2 through piping 6, and a pressure switch 10 is set in the middle of the piping 6. The air compressor 5 is designed so that driving and stopping are performed by on/off of the pressure switch 10, so that the pressure inside the storage tank 4 is controlled to be within a prescribed range. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fire extinguishing apparatus for extinguishing a fire in a small-scale section.

Conventionally, as a small-sized fire extinguisher for a small-scale section where there is a risk of a fire, a compact fire extinguisher including a storage tank for extinguishing agent and a pressurized gas cylinder for pressurizing the tank is known ( For example, Patent Document 1 and Patent Document 2).
In these fire extinguishing devices, when a fire occurs in the target area, the high pressure gas in the pressurized gas cylinder is supplied to the fire extinguisher storage tank, the pressure in the storage tank is increased, and the fire extinguisher is released. The pressurized gas cylinder is usually sealed with a sealing plate and is extremely airtight, so that the gas pressure hardly changes even after a long period of time. For this reason, there exists an advantage which can lengthen the span of cylinder replacement | exchange by the fall of gas pressure.
JP-A-6-292737 JP-A-8-215332

  However, pressurized gas cylinders may be subject to laws and regulations depending on the installation location, in which case various conditions are required for installation, and many restrictions on disposal are provided, Management becomes troublesome.

  For this reason, it can be considered that the extinguishing agent storage tank itself is always kept in a pressurized state (accumulated state) to eliminate the pressurized gas cylinder. However, since the airtight performance of the fire extinguishing agent storage tank is much inferior to the airtight performance of the pressurized gas cylinder sealing plate, inspection for gas pressure inspection and refilling must be performed frequently. For this reason, manpower is required, and there is a risk that the maintenance cost will increase.

The present invention has been made in view of the above-described conventional circumstances, and provides a fire extinguishing apparatus that does not require installation of a pressurized gas cylinder, requires less labor for inspection, and has low maintenance costs. This is a problem to be solved.

  A first aspect of the fire extinguishing apparatus of the first invention is a storage tank for storing a fire extinguishing agent, an injection head for spraying the fire extinguishing agent to a predetermined area, and a pipe connecting the storage tank and the injection head And a transportation means for transporting the fire extinguishing agent in the storage tank to the jet head via the pipe, the transportation means compressing air in the storage tank so as to be pressurized It is a mechanism.

  In the first aspect of the fire extinguishing apparatus of the first invention, the inside of the storage tank can be pressurized by the air compression mechanism as the transport means, and thereby the fire extinguisher in the storage tank can be transported to the ejection head. . For this reason, a pressurized gas cylinder for transporting the fire extinguishing agent to the ejection head is not necessary and is not subject to legal regulations. For this reason, it becomes possible to install in a larger number of protection targets, and since many restrictions on disposal are not imposed, management becomes extremely easy.

  In the second aspect of the fire extinguishing apparatus of the first invention, the air compression mechanism is controlled by the pressure control unit so that the pressure of the compressed air for transporting the fire extinguishing agent in the storage tank to the ejection head is within a predetermined range. It was decided that In this way, the fire extinguisher in the storage tank can be transported to the injection head at any time, and it is not necessary to conduct frequent inspections for gas pressure inspection. Cost can be reduced.

In the third aspect of the fire-extinguishing apparatus of the first invention, the ejection head is an open-type ejection head in which the nozzle is open even during normal operation, and a fire detector and an on-off valve provided in the middle of the piping And an on / off valve control unit that receives the fire signal from the fire detector and switches the on / off valve from the closed state to the open state.
In this case, in the event of a fire, the on-off valve control unit can open the on-off valve based on the fire signal from the fire detector, and the fire extinguishing agent can be automatically released from the ejection head.
Note that a plurality of open-type ejection heads can be installed.

According to a fourth aspect of the fire extinguishing apparatus of the first invention, the nozzle is normally closed, and is a closed jet head that is automatically opened by heat in the event of a fire.
If this is the case, the closed-type jet head automatically detects heat in the event of a fire and automatically opens, and fire extinguishing agent is sprayed from the jet head, so it is necessary to provide a fire detector and a complicated control device. Absent. For this reason, the power supply for driving a fire detector and a control apparatus becomes unnecessary, and the installation of the storage battery for the time of a power failure can be made unnecessary.

  In the fifth aspect of the fire extinguishing apparatus of the first invention, a plurality of closed type ejection heads are installed in a predetermined area. If this is the case, the closed jet head at the location where the fire has occurred is first opened. For this reason, a fire extinguishing agent can be concentrated and sprayed on the most necessary location.

  In the sixth aspect of the fire extinguisher of the first invention, a storage battery is provided for enabling the fire extinguisher to be driven even during a power failure. If this is the case, fire extinguishing agent can be sprayed from the jetting head using a fire extinguishing device even when a power failure occurs due to a fire or when the power supply is forcibly stopped to ensure safety in the event of a fire. it can.

  In the seventh aspect of the fire-extinguishing apparatus of the first invention, the fire-extinguishing agent is a liquid fire-extinguishing agent having electrical insulation. If a liquid fire extinguisher having electrical insulation is used as a fire extinguisher, it is possible to extinguish a fire of an electric system that cannot be extinguished using water, a general fire or an oil fire. Moreover, since there is no water loss, even if a liquid fire extinguisher is accidentally released, it does not affect the electrical system in the energized state. Furthermore, since it has high volatility, no wiping cleaning or waste liquid treatment is required. Examples of such halogen-based liquid fire extinguishing agents include dodecafluoro-2-methylpentan-3-one.

  The first aspect of the fire extinguishing apparatus of the second invention is a storage tank for storing a fire extinguishing agent, an injection head for spraying the fire extinguishing agent to a predetermined area, and a pipe connecting the storage tank and the injection head. And a fire extinguishing apparatus comprising a transport means for transporting the fire extinguishing agent in the storage tank to the jet head via the pipe, wherein the transport means is a liquid feed pump.

  In the first aspect of the fire-extinguishing apparatus of the second invention, the fire-extinguishing agent in the storage tank can be transported to the ejection head by driving the liquid feed pump as the transporting means. For this reason, a pressurized gas cylinder for transporting the fire extinguishing agent to the ejection head is not necessary and is not subject to legal regulations. For this reason, it becomes possible to install in more protection objects, and since many restrictions are not imposed at the time of disposal, management becomes very easy.

  In the second aspect of the fire-extinguishing apparatus of the second invention, the ejection head is an open-type ejection head in which the nozzle is open even during normal times, and includes a fire detector, an on-off valve provided in the middle of the piping, And a liquid feed pump controller that drives the liquid feed pump in response to a fire signal from the fire detector. In this case, in the event of a fire, the liquid feed pump control unit can open the on-off valve based on the fire signal from the fire detection means, and the fire extinguishing agent can be automatically released from the ejection head.

  According to a third aspect of the fire extinguishing apparatus of the second invention, the jet head is a closed jet head in which the nozzle is normally closed and is automatically opened by heat in the event of a fire. did. If this is the case, the closed-type jet head automatically detects heat in the event of a fire and automatically opens, and fire extinguishing agent is sprayed from the jet head, so it is necessary to provide a fire detector and a complicated control device. Absent. For this reason, the power supply for driving a fire detector and a control apparatus becomes unnecessary, and the installation of the storage battery for the time of a power failure can be made unnecessary.

  In the fourth aspect of the fire-extinguishing apparatus of the second invention, a plurality of closed-type ejection heads are installed in a predetermined area. If this is the case, the closed jet head at the location where the fire has occurred is first opened. For this reason, a fire extinguishing agent can be concentrated and sprayed on the most necessary location.

  In the fifth aspect of the fire extinguishing apparatus of the second invention, a pressure switch that generates a fire signal due to a decrease in piping pressure during a fire is provided, and the liquid feed pump is driven by the fire signal from the pressure switch It was. In this case, when a fire occurs, the liquid feed pump operates when the closed jet head is operated and the pressure in the pipe is released, and the fire extinguishing agent can be continuously fed.

  In the sixth aspect of the fire extinguishing apparatus of the second invention, a storage battery for enabling the fire extinguishing apparatus to be driven even during a power failure is provided. If this is the case, fire extinguishing agent can be sprayed from the jetting head using a fire extinguishing device even when a power failure occurs due to a fire or when the power supply is forcibly stopped to ensure safety in the event of a fire. it can.

  In the seventh aspect of the fire extinguishing apparatus of the second invention, the fire extinguishing agent is a liquid fire extinguishing agent having electrical insulation. If a liquid fire extinguisher having electrical insulation is used as a fire extinguisher, it is possible to extinguish a fire of an electric system that cannot be extinguished using water, a general fire or an oil fire. Moreover, since there is no water loss, even if a liquid fire extinguisher is accidentally released, it does not affect the electrical system in the energized state. Furthermore, since it has high volatility, no wiping cleaning or waste liquid treatment is required. Examples of such halogen-based liquid fire extinguishing agents include dodecafluoro-2-methylpentan-3-one.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments embodying the present invention will be described in detail with reference to the drawings.
(Embodiment 1)
As shown in FIG. 1, the fire extinguisher of Embodiment 1 is a fire extinguisher that uses a relay 91 attached to a wall in the switchboard 90 and a covered electric wire (not shown) as a fire extinguishing target. This fire extinguisher is connected to the outside of the switchboard 90 in the vicinity of the fire extinguisher main body 1, the open type injection head 2 attached to the ceiling 90 a on the switchboard 90, the fire detector 3 a, and the fire extinguisher main body 1. And an attached alarm 3b.

  A storage tank 4 is provided in the fire extinguisher main body 1, and dodecafluoro-2-methylpentan-3-one is stored in the storage tank 4 as a fire extinguishing agent. The storage tank 4 is connected to an air compressor 5 and can be pressurized. The storage tank 4 is connected to the open type injection head 2 via a pipe 6, and an electromagnetic on-off valve 7 is provided in the middle of the pipe 6. Furthermore, a degassing safety valve 9 is attached to the storage tank 4 via a degassing pipe 8 so that the pressure in the storage tank becomes less than the design pressure of the storage tank. In the middle of 8, a pressure switch 10 is attached. The air compressor 5 is driven and stopped by turning the pressure switch 10 on and off so that the pressure in the storage tank 4 falls within a predetermined range.

  In addition, a control panel 11 is installed inside the fire extinguisher body 1, and the control panel 11 is provided with a control unit 12 for controlling the air compressor 5 and the on-off valve 7 and a storage battery 13. ing. The storage battery 13 is supplied with electric power from within the switchboard 90 and can supply electric power necessary for the fire extinguishing device. The control unit 12 receives a fire signal from the fire detector 3a, drives the on-off valve 7 and the alarm 3b, and interrupts the supply of electricity to the air compressor 5.

Next, the effect of this fire extinguishing apparatus is demonstrated.
<Normal time>
In a normal state where no fire has occurred, the on-off valve 7 is closed, and the storage tank 4 is always sealed in a pressurized state. Since the airtightness in the storage tank 4 is not perfect, the gas inside leaks little by little. And if the pressure in the storage tank 4 becomes below a predetermined pressure, the pressure switch 10 will be in an ON state and the air compressor 5 will drive. As a result, the pressure in the storage tank 4 rises, and when the pressure reaches a predetermined pressure, the pressure switch 10 is turned off. Thus, the pressure in the storage tank 4 returns to the original pressure again. In this way, the ON / OFF of the pressure switch 10 is repeated, and the pressure in the storage tank 4 is constantly in a pressurized state within a predetermined range.

<When a fire occurs>
When a fire occurs, the fire detector 3a is activated by the heat of the fire, and a fire signal is sent to the control unit 12. Upon receiving the fire signal, the control unit 12 stops receiving electricity from the switchboard 90. Thereby, it can prevent that the fire extinguishing apparatus main body 1 receives supply of electric power from the switchboard 90 which has caused the fire at least. Thus, in the event of a fire, the control unit 12 stops the supply of electricity from the switchboard 90 and receives supply of power from the storage battery 13. Then, based on the fire signal, the alarm 3b is driven to notify the occurrence of the fire with an alarm sound, and the on-off valve 7 is opened. Thereby, the fire extinguisher (dodecafluoro-2-methylpentan-3-one) in the storage tank 4 is sprayed from the open type injection head 2 through the pipe 6 to extinguish the fire.

In the fire extinguishing apparatus of the first embodiment, the storage tank 4 is constantly pressurized so as to be in a predetermined pressure range by driving the air compressor 5. For this reason, the pressurized gas cylinder excellent in airtightness becomes unnecessary, and it does not become a target of laws and regulations.
Further, since the storage tank 4 is always pressurized so as to be in a predetermined pressure range, it becomes possible to transport the fire extinguisher in the storage tank 4 to the ejection head 2, and inspection for gas pressure inspection is frequently performed. Therefore, it is not necessary to perform the maintenance, and it is possible to reduce the maintenance cost by requiring less manpower for the maintenance.
Furthermore, even if a power failure occurs due to a fire, the supply of power from the storage battery 13 can continuously spray the fire extinguishing agent from the ejection head 2.
In addition, when a halogen-based liquid fire extinguisher is used, it is possible to extinguish an electric fire that cannot be extinguished using water, a general fire, or an oil fire. Moreover, since there is no water loss, even if the liquid fire extinguisher is accidentally released, it does not affect the electrical system in the energized state. Furthermore, since it has high volatility, wiping cleaning and waste liquid treatment are unnecessary, and early recovery is possible.

(Embodiment 2)
As shown in FIG. 2, the fire extinguishing apparatus according to the second embodiment is a fire extinguishing apparatus that uses a plurality of relays 93 a, 93 b, 93 c attached to a wall in the switchboard 92 and electric parts (not shown) as fire extinguishing targets. This fire extinguisher is provided with a fire extinguisher main body 21 provided close to the outside of the switchboard 92, and closed type injection heads 22a, 22b, 22c attached to a ceiling 92a on the relays 93a, 93b, 93c. Yes.

  A storage tank 24 is provided in the fire extinguisher main body 21, and dodecafluoro-2-methylpentan-3-one is stored in the storage tank 24 as a fire extinguishing agent. The storage tank 24 is connected to an air compressor 25 and can be pressurized. Further, the storage tank 24 is connected to the closed injection heads 22a, 22b, and 22c via a pipe 26, and pressure switches 27a and 27b are attached to the middle of the pipe 26. The pressure switch 27a is connected to the air compressor 25, the relay 93a, and electric parts (not shown), and the air compressor 25 is driven or stopped by turning on / off the pressure switch 27a. . The pressure switch 27b is connected to an alarm 29 attached to the outside of the storage battery 28 and the fire extinguishing device 21, and the alarm 29 is sounded when the pressure switch 27b is turned on. The operating pressure of the pressure switch 27b is set lower than the operating pressure of the pressure switch 27a. Further, a gas venting safety valve 30b is attached to the storage tank 24 through a gas vent pipe 30a so that the pressure in the storage tank 24 is less than the design pressure.

  As shown in FIG. 3, the closed type ejection heads 22a, 22b, and 22c are composed of an ejection head main body 22d and a thermal melting fuse 22e. The ejection head main body 22d includes a tubular screw portion 22f connected to a pipe 26 (see FIG. 2), a fuse holding portion 22g protruding from the tip of the screw portion 22f, and a center portion pulled out, and a tip of the fuse holding portion 22g. And a watering plate 22h attached to the head. The thermal melting fuse 22e is attached to the fuse holding portion 22g and has a structure that supports a closing plate 22i that closes the tubular screw portion 22f. The heat melting fuse 22e is melted at about 100 ° C., whereby the closing plate 22i is detached from the screw portion 22f, and the screw portion 22f communicates with the inside of the switchboard 92.

Next, the effect of this fire extinguishing apparatus is demonstrated.
<Normal time>
In a normal state where no fire has occurred, the storage tank 24 is always sealed in a pressurized state, but since the hermeticity is not perfect, the internal gas leaks little by little. And if the pressure in the storage tank 24 becomes below predetermined pressure, the pressure switch 27a will be in an ON state and the air compressor 25 will drive like the fire extinguishing apparatus of Embodiment 1. As a result, the pressure in the storage tank 24 rises, and when the pressure reaches a predetermined pressure, the pressure switch 27a is turned off. Thus, the pressure in the storage tank 24 returns to the original pressure again. In this way, the pressure switch 27a is repeatedly turned on and off, and the pressure in the storage tank 24 is constantly kept pressurized within a predetermined range.

<When a fire occurs>
On the other hand, in the event of a fire, the thermal melting fuse 22e of the head closest to the fire source melts among the closed type ejection heads 22a, 22b, 22c, the closing plate 22i is detached from the screw portion 22f, and the inside of the screw portion 22f is in the switchboard 92. It communicates with the inside (see FIG. 3). Thus, any of the closed type injection heads 22a, 22b, and 22c is opened, and dodecafluoro-2-methylpentan-3-one in the storage tank 24 is sprayed from the closed type injection head that is opened through the pipe 26. The fire is extinguished. Thereby, the pressure in the piping 26 falls, and the pressure switches 27a and 27b are turned on. As a result, the alarm 29 is sounded to notify that the extinguishing agent has been released.

In the fire extinguisher of the second embodiment, as in the fire extinguisher of the first embodiment, the storage tank 24 is always pressurized so as to be in a predetermined pressure range by driving the air compressor 25, so that a pressurized gas cylinder is unnecessary. Therefore, it is not subject to laws and regulations.
In addition, it is not necessary to frequently perform inspections for gas pressure inspection, and the maintenance can be performed with less manpower, and the maintenance cost can be reduced.
Furthermore, since the closed type ejection heads 22a, 22b, and 22c that are automatically opened by heat in the event of a fire are used as the ejection heads, the closed type ejection heads 22a, 22b, and 22c are automatically heated in the event of a fire. Is automatically opened and a fire extinguisher is sprayed. For this reason, it is not necessary to provide a fire detector or a complicated control device. In addition, in the event of a fire, only the closed-type jet head at the location where the fire occurred is opened first, so that the fire extinguishing agent can be intensively sprayed onto the fire source.

  In addition, in the fire extinguishing apparatus of the second embodiment, the storage battery 28 for operating the alarm 29 is provided. However, if the alarm 29 is not installed, the power source is unnecessary, and the installation of the storage battery for power failure is unnecessary. It can be. The pressure switch 27a can also be used to send a signal to other fire alarm equipment.

  Further, as a structure of the closed type injection head, a glass bubble type or the like can be used instead of the hot melt fuse type.

(Embodiment 3)
As shown in FIG. 4, the fire extinguishing apparatus according to the third embodiment is a fire extinguishing apparatus that uses a plurality of relays 95 a, 95 b, and 95 c attached to a wall in the switchboard 94 and electric parts (not shown) as fire extinguishing objects. This fire extinguishing device includes a fire extinguishing device main body 31 provided close to the outside of the switchboard 94, and closed jet heads 33a, 33b attached to a ceiling 94a on relays 95a, 95b, 95c and electric parts (not shown). , 33c. The structure of the closed type ejection heads 33a, 33b, and 33c is the same as that of the second embodiment.

  A storage tank 34 is provided in the fire extinguisher main body 31, and dodecafluoro-2-methylpentan-3-one is stored in the storage tank 34 as a fire extinguishing agent. A liquid feed pump 35 is connected to the storage tank 34, and the fire extinguishing agent can be transported to the closed jet heads 33 a, 33 b, and 33 c through a pipe 36. A check valve 36 a is provided in the middle of the pipe 36. In addition, a pressure accumulating tank 37 is attached in the middle of the pipe 36, and pressure switches 38 a and 38 b are attached to the pressure accumulating tank 37. In addition, an intake port 34b with a check valve 34a is attached to the upper portion of the storage tank 34, so that outside air can be taken in when the pressure in the storage tank 34 becomes negative.

  The liquid feed pump 35 is driven and stopped by turning on and off the pressure switch 38b so that the pressure in the pressure accumulation tank 37 and the pipe 36 is within a predetermined range. Moreover, the pressure switch 38a is connected to the alarm 40 provided in the storage battery 39 and the switchboard 94, and the alarm 40 sounds by the ON state of the pressure switch 38a. The operating pressure of the pressure switch 38a is set lower than the operating pressure of the pressure switch 38b.

Next, the effect of this fire extinguishing apparatus is demonstrated.
<Normal time>
In a normal state where no fire has occurred, the liquid feed pump 35 is stopped in a state in which the inside of the pipe 36 is pressurized. Therefore, the inside of the pipe 36 and the pressure accumulating tank 37 are always sealed in a pressurized state. . However, since the sealing property is not perfect, the gas in the pressure accumulating tank 37 leaks little by little. When the pressure in the pressure accumulating tank 37 becomes equal to or lower than a predetermined pressure, the pressure switch 38b is turned on and the liquid feed pump 35 is driven. As a result, the pressure in the pipe 36 and the pressure accumulation tank 37 rises, and when the pressure reaches a predetermined pressure, the pressure switch 38b is turned off. Thus, the pressure in the pipe 36 and the pressure accumulating tank 37 returns to the original pressure again. In this way, the pressure switch 38b is repeatedly turned on and off, so that the pressure in the pipe 36 and the pressure accumulation tank 37 is constantly pressurized within a predetermined range.

<When a fire occurs>
On the other hand, when a fire occurs, only the head closest to the fire source is opened among the closed type ejection heads 33a, 33b, and 33c. And the fire extinguisher in the piping 36 is sprayed from the closed type injection head opened through the piping 36, and fire extinguishing is performed. As a result, the pressure in the pressure accumulating tank 37 is rapidly reduced, and the pressure switches 38a and 38b are turned on. As a result, the liquid feed pump 35 is driven and an alarm 40 is sounded to notify that the extinguishing agent has been released.

  In the fire extinguishing apparatus of the third embodiment, the extinguishing agent in the pipe 36 is always pressurized by the pressure accumulating tank 37 so as to be in a predetermined pressure range, so that a pressurized gas cylinder is unnecessary and is subject to legal regulations. There is no. In addition, it is not necessary to frequently perform inspections for gas pressure inspection, and the maintenance can be performed with less manpower, and the maintenance cost can be reduced. Furthermore, since the closed type ejection heads 33a, 33b, and 33c are used as the ejection heads, the fire extinguishing agent is automatically sprayed, and there is no need to provide a fire detector or a complicated control device. In addition, a plurality of closed-type jet heads 33a, 33b, and 33c are installed, and the closed-type jet head at the place where the fire occurred is opened first, so that the extinguishing agent is concentrated on the place where the fire extinguishing agent is most needed Can be sprayed.

  The present invention is not limited to the description of the embodiments of the above invention. Various modifications are also included in the present invention as long as those skilled in the art can easily conceive without departing from the scope of the claims.

  The present invention can be suitably used for extinguishing a fire in a small area.

It is a schematic diagram of the fire extinguishing apparatus of Embodiment 1. It is a schematic diagram of the fire extinguishing apparatus of Embodiment 2. 6 is a front view of a closed type ejection head used in Embodiment 2. FIG. It is a schematic diagram of the fire extinguishing apparatus of Embodiment 3.

Explanation of symbols

4, 24, 34 ... storage tank 2 ... jet head (2 ... open type jet head, 22a, 22b, 22c, 33a, 33b, 33c ... closed type jet head)
6, 26, 36 ... piping 5, 25, 35 ... transport means (5, 25 ... air compression mechanism (air compressor), 35 ... liquid feed pump)
10, 27a, 38b ... pressure control unit (pressure switch)
3a ... Fire detector 7 ... Open / close valve 12 ... Open / close valve control unit 13, 28, 39 ... Storage battery 35 ... Liquid feed pump

Claims (14)

A storage tank for storing a fire extinguisher, an injection head for spraying the fire extinguishing agent to a predetermined area, a pipe connecting the storage tank and the injection head, and the pipe for supplying the fire extinguishing agent in the storage tank A fire extinguishing apparatus comprising transport means for transporting to the ejection head via
The fire extinguishing apparatus, wherein the transport means is an air compression mechanism that enables pressurization in the storage tank.   2. The fire extinguishing system according to claim 1, wherein the air compression mechanism is controlled by a pressure control unit so that the pressure of the compressed air for transporting the fire extinguisher in the storage tank to the ejection head is within a predetermined range. apparatus.   The injection head is an open type injection head in which the nozzle is open even under normal conditions. Upon receiving a fire signal from the fire detector, an on-off valve provided in the middle of the piping, and the fire detector. The fire-extinguishing apparatus according to claim 1, further comprising: an on-off valve control unit that switches the on-off valve from a closed state to an open state.   The fire-extinguishing apparatus according to claim 1 or 2, wherein the ejection head is a closed-type ejection head in which the nozzle is normally closed and is automatically opened by heat in the event of a fire.   The fire-extinguishing apparatus according to claim 4, wherein a plurality of closed-type ejection heads are installed in a predetermined area.   The fire extinguishing apparatus according to any one of claims 1 to 5, further comprising a storage battery capable of driving the fire extinguishing apparatus even during a power failure.   The fire extinguishing agent according to any one of claims 1 to 6, wherein the fire extinguishing agent is a liquid extinguishing agent having electrical insulation. A storage tank for storing a fire extinguisher, an injection head for spraying the fire extinguishing agent to a predetermined area, a pipe connecting the storage tank and the injection head, and the pipe for supplying the fire extinguishing agent in the storage tank A fire extinguishing apparatus comprising transport means for transporting to the ejection head via
The fire extinguishing apparatus, wherein the transport means is a liquid feed pump.   The ejection head is an open-type ejection head in which the nozzle is open even under normal conditions. The fire head, an on-off valve provided in the middle of the piping, and a fire signal from the fire sensor receive liquid. The fire extinguishing apparatus according to claim 8, further comprising a liquid feed pump control unit that drives the feed pump.   The fire-extinguishing apparatus according to claim 8, wherein the ejection head is a closed-type ejection head in which the nozzle is normally closed and is automatically opened by heat in the event of a fire.   The fire-extinguishing apparatus according to claim 10, wherein a plurality of closed-type ejection heads are installed in a predetermined area.   The fire extinguishing apparatus according to claim 10 or 11, wherein a pressure switch is provided that generates a fire signal when a pipe pressure is reduced in a fire, and the liquid feed pump is driven by the fire signal from the pressure switch. .   The fire extinguishing apparatus according to any one of claims 8 to 12, further comprising a storage battery that enables the fire extinguishing apparatus to be driven even during a power failure.   The fire-extinguishing apparatus according to any one of claims 8 to 13, wherein the fire-extinguishing agent is a liquid fire-extinguishing agent having electrical insulation.

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