JPS63292971A - Automatic fire extinguishing system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention provides an automatic fire extinguishing system that unmannedly extinguishes indoor fires in studio apartment complexes, for example, and remotely reports the occurrence of a fire to a central control room, etc. It is related to.

[Prior Art] ′ In recent years, the number of one-room apartments that are both functional and livable for young people has been rapidly increasing, but the current situation is that the number of fires in these one-room apartments is also gradually increasing.

A fire extinguishing system that operates unattended is particularly effective against such fires, and conventionally, as shown in Figure 5, a pressure-accumulated fire extinguishing agent storage container (8) is placed indoors or outdoors at 82°C. An indicating pressure gauge (35), a pressure switch (18), and a valve holder (36) are attached to the valve case (9) connected to the top of the drug container (8), and the room where the fire is to be extinguished is installed. A heat-sensing sensing nozzle (2) that is activated by the heat of a fire and a chemical chamber inside a chemical container (8) are connected through a flexible pipe (7), and a pressure switch (18) is installed outdoors. It is wired or wirelessly connected to the control panel (31) installed in the
3) and a power supply breaker (34).

When the nozzle (2) senses the heat of the fire, the chemical agent compressed to the tip of the flexible pipe (7) is ejected from the nozzle (2) due to the pressure, immediately extinguishing the fire. The pressure inside the conduit decreases due to the ejection of this medicine from the nozzle, so this is switched to the pressure switch (18
) detects this and activates the warning device (32), the alarm device (33), the power circuit breaker (34), etc.

[Problem that the invention seeks to solve]

In such a fire extinguishing system, the pressure up to the tip of each sensing nozzle is always maintained at the same pressure as in the extinguishing agent storage container, but as the number of sensing nozzles increases, the connections between the flexible tube and the agent container and between the flexible tube and the sensing nozzle are increased. As the number of connections increases, pressure leakage from these connection points becomes a bigger problem. In addition, once the above system has been upgraded, it cannot cope with the addition of a sensing nozzle from the same drug container or a major change in the position of the nozzle, and in such cases, the existing drug container must be removed and a similar system installed. This was extremely inconvenient for expanding the fire extinguishing system.

Furthermore, heat-sensing nozzles sometimes detect heat other than fire heat and malfunction, so improvements have been desired from a reliability standpoint.

[Means for solving problems]

In view of this, the present invention has high reliability as a result of various studies,
Furthermore, we have developed an automatic fire extinguishing system with excellent flexibility in system expansion, which requires installing a fire extinguishing agent storage container indoors or outdoors, and running multiple conduits from the container through the ceiling or floor to extinguish the fire inside the room. A sensing nozzle for injecting extinguishing agent with a mechanism that senses the fire heat and automatically opens the extinguishing agent is installed at the tip of each conduit, and the pressure nozzle in the conduit is installed in the storage container or a part close to it.] In a fire extinguishing system equipped with a pressure switch that detects a drop in pressure,
A heat sensor is installed near each of the above-mentioned sensing nozzles, and when the heat sensor detects a rise in temperature due to a fire, the inside of the extinguishing agent storage container is communicated with each conduit to pressurize the inside of the conduit. the extinguishing agent, and has a mechanism capable of opening the sensing nozzle for injecting the extinguishing agent to eject the extinguishing agent at a temperature roughly higher than the above temperature, and a signal of the heat sensor and an activation signal of the pressure switch. This feature is characterized in that an alarm device and/or a safety device are activated by both of the following.

[For production]

A heat sensor is installed near each sensing nozzle, and when the heat sensor detects a rise in temperature due to a fire, the inside of the extinguishing agent storage container is communicated with each conduit, and the inside of the conduit is pressurized. Filling with extinguishing agent means that unless there is a rise in temperature due to a fire, there is nothing inside the conduit installed in the ceiling or floor, so if you are expanding or renovating the room, increase the number of sensing nozzles or change the route of the conduit. This is because construction work to extend or shorten the conduit can be carried out freely.

In addition, opening the sensing nozzle at a temperature higher than the sensing temperature of the sensor increases the certainty that there is a fire by capturing the rising temperature in two stages, and it is safe to open the sensing nozzle at a temperature higher than the sensing temperature of the sensor. This is to activate in the event of a fire, and this prevents accidental injection.

Furthermore, the fire is notified to the outside by both the heat sensor signal and the signal that the pressure switch detects the pressure drop in the pipe due to the extinguishing agent sprayed from the sensing nozzle, and the alarm system to the central control is activated. When necessary, activate the safety device that shuts off the gas main valve and electricity.In an actual fire, the heat detector and pressure switch mentioned above will always be activated, and both signals will be generated, but due to malfunction, only one will be activated. This is to prevent the above-mentioned alarm and safety devices from operating when the alarm is activated.

Note that the extinguishing agent storage container in the system of the present invention can be used regardless of whether it is a pressure storage type or a pressurized type.

〔Example〕

The present invention will be explained in more detail with reference to examples.

Example (1) As shown in Fig. 1, in a system using an accumulator fire extinguisher, a nozzle fixing plate (2) with sensing nozzles (2) for extinguishing agent injection fixed in holes cut out in the ceiling (1) of multiple rooms is used. 3) and the fixing plate holder (5) that fixed the heat sensor (4) with the screw (6).
The sensing nozzle (2) is connected to a valve provided at the top of a pressure-accumulating fire extinguishing agent storage container (chemical container) (8) using a stainless steel flexible pipe (7) as a conduit. Pipe inlet (11) of pipe fitting (10) attached to case (9)
On the other hand, the heat sensors (4) are electrically connected in series, and roughly one end is led to a separate drive control board (12) containing a battery. In the figure, (35) indicates an indicator pressure gauge that indicates the internal pressure of the drug container (8).

The drug container (8) also has a valve case (9) attached to the top via a cap (13) as shown in FIG.
) A communication chamber (14) with an open lower part is formed vertically inside the valve case (14), and a head (15) is projected above the valve case (9) by penetrating the communication chamber (14) in the vertical direction. Valve (17) whose lower opening is closed by a spring (16)
A pressure switch (18) communicating with the communication chamber (14) is installed roughly on the side of the valve case (9), and a pipe inlet (11) communicating with the communication chamber (14) is installed.
) Attach the pipe fitting (10).

On the other hand, the above valve (17) is located at the top of the valve case (9).
The gunpowder starter (19) is installed so that the cylinder (20) of the starter (19) covers the head (15) of the valve collar (2).
It is attached by screwing into the upper part of the valve case (9) through the screws 1). A piston (29) that slides in the vertical direction is provided in the cylinder (20), and the upper end of the piston (29) has a gunpowder (23) in a socket (22) screwed into the upper end of the cylinder (20). It is in contact with the internal space, and the gunpowder (23) is connected to the lead wire (37) from the outside.
), and explodes when supplied with electricity from the separate drive control panel (12) shown in Figure 1, pushing the piston (29) downward.

In FIG. 2, (38) indicates the 0 ring. The pressure switch (18) is connected by wire or wirelessly to an alarm terminal (not shown), a gas main valve, and a safety device that shuts off the primary side of electricity.

This completes the installation work of the fire extinguishing system, but as shown in Figures 1 and 2, when any of the heat sensors (4) in the system detects a rise in temperature due to a fire, the signal is sent to the drive control panel ( 12) is a gunpowder starter (19)
The piston (29) is lowered by exploding the gunpowder, causing the piston (29) to hit the head (15) of the valve (17), lowering the valve (17), and lowering the drug container (8).
The inside is communicated with the communication chamber (14) in the valve case (9), and the inside of the flexible pipe (7) is roughly filled with pressurized medicine up to the tip where the sensing nozzle (2) is attached.

Next, when the fire becomes even bigger, the low melting point metal blocking the sensing nozzle (2) melts and falls due to the rapidly rising temperature, opening the nozzle (2) and pressurizing it to the tip of the flexible pipe (7). The suppressed chemical is ejected from the nozzle (2) due to the pressure and extinguishing the fire immediately.

This extinguishing operation will cause damage to the inside of the pipe (7) and the chemical container (8).
As the internal pressure decreases, the pressure switch (18) detects this and issues a signal, which is activated by the heat sensor (18) which has already been emitted.
Combined with the signal 4), the alarm is activated and the circuit breaker is activated to shut off the power supply and gas, thereby preventing the occurrence of a secondary fire.

If the heat sensor (4) detects the heat, opening the room where the fire is progressing before the fire is extinguished may cause deflagration, making it impossible to achieve initial extinguishment and causing the fire to spread over a wide area. Therefore, in such a case, lock the detected room at the same time as the sensor activates, and immediately after that, the sensing nozzle (2) detects the further rise in temperature and ejects the chemical to extinguish the fire, and the fire is completely extinguished. By configuring a system that unlocks when the temperature drops and the heat detector is restored, it is possible to prevent the spread of fire and create a more robust fire extinguishing system.

Example (2) As shown in Fig. 3, a fire extinguishing agent storage container (storage container) containing only the extinguishing agent (a) and a compressed gas (b) containing only the compressed gas such as CO2, N2 or air. The gas containers (25) are independently arranged in parallel, and the compressed gas containers (
25) Connect the communication chamber (14) in the valve case (9) attached to the top and the inside of the storage container (24) with the tube (26).
) and a cap (27) attached to the top of the storage container (24).
) through a through hole (28) drilled in the cap (
27) When a pressurized fire extinguishing system with one end of the flexible pipe (7) is used, the system uses a gunpowder starter similar to the above at the top of the valve case (9) on top of the compressed gas container (25). A pressure switch (18) communicating with the communication chamber (14) is provided on the side of the valve case (9), and the pressure switch (18) is connected to an alarm or the like. In addition, the cap at the top of the storage container (24) (
The other end of the flexible pipe (7) attached to 27) is connected to a sensing nozzle for spraying fire extinguishing agent installed in each room, etc. Further, a heat sensor is installed near the sensing nozzle, and when the sensor is activated, a signal is sent to a separate drive control panel to drive the explosive starter (19).

In the pressurized fire extinguishing system as described above, if any of the heat detectors detects fire heat, the explosive starter (19
) explodes the gunpowder (23), lowers the piston (29), and instantly pushes down the valve (17) in the valve case (9), transferring the compressed gas (b) in the compressed gas container (25) to the communication chamber (14). ), the inside of each storage container (24) is pressurized by the tube (26), and the extinguishing agent (a) is transferred to the container (
24) is filled into the flexible pipe (7) through the siphon pipe (30), and the sensing nozzle is actuated by the further increased temperature to open the nozzle,
The extinguishing agent (a) compressed to the tip of the flexible pipe (7) is ejected from the nozzle by the pressure of the compressed gas (b) to extinguish the fire. This fire extinguishing operation lowers the pressure in the compressed gas container (25), which is detected by the pressure switch (18), and an external alarm is issued and electricity and gas are shut off based on the detection signal and the detection signal from the heat sensor.

Example (3) A pressurized gas container (39) filled with a compressed gas such as CO2, NZ or air as shown in FIG. > (40
), when using a pressurized fire extinguisher built in the powder container (40), the holder has a cutting shaft (42) that vertically passes through the holder (41) attached to the top of the powder container (40) and has an acute-angled lower end. A gunpowder starter (19) is attached so as to cover the upper end protruding from the gunpowder (41), and the gunpowder (2) of the starter (19) is
3) A lead with one end connected to! ! The other end of (37) is connected to a drive control panel that receives signals from a heat sensor (not shown). Furthermore, inside the powder container (40), there is a flexible pipe which has one end opened inside the fire extinguishing agent (C) and whose end (t! (7) and a gas siphon pipe (4) that injects the compressed gas in the pressurized gas container (39) into the powder container (40).
3), and a pressure switch (not shown) that is activated by a drop in pressure inside the powder container (40) or flexible pipe (7) is installed.

If a heat detector detects a fire in such a system,
The signal activates the gunpowder starter (19), lowers the piston (29), pushes down the cutting shaft (42), opens the pressurized gas container (39) with the sharp end, and opens the powder container (4G).
) and the flexible pipe (7) are filled with compressed gas, and then when the sensing nozzle at the tip of the flexible pipe (7) is activated, the sensing nozzle opens, and the powder extinguishing agent (C) is discharged from the nozzle along with the compressed gas. The pressure switch detects when the powder is extinguished and the pressure inside the powder container (40) has decreased, and this signal and the signal from the heat sensor are used to issue an alarm to the outside or shut off electricity and gas. Let's do it.

〔Effect of the invention〕

As described above, according to the present invention, it is possible to eliminate malfunctions when extinguishing agent is ejected, and to ensure the reliable operation of fire alarms and safety devices in the event of a fire.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing one embodiment of the present invention, FIG. 2 is a cross-sectional view of essential parts showing one embodiment of the present invention, and FIG. 3 is a cross-sectional view of main parts showing another embodiment of the present invention. FIG. 4 is a sectional view showing roughly another embodiment of the present invention, and FIG. 5 is an explanatory view showing a conventional example. 1... Ceiling 2... Sensing nozzle for extinguishing agent injection 3...
...Nozzle fixing plate 4...Heat sensor 5...Fixing plate receiver 6...Screw 7...・Flexible pipe 8...
...Pressure-accumulating fire extinguishing agent storage container 9...Valve case 10...Pipe joint 11...Pipe inlet 12... Drive control panel 13... Cap 14... Communication chamber 15... Head 16... Spring 17... ... Valve 18 ... Pressure switch 19 ... Gunpowder starter 20 ... Cylinder 21 ... Valve collar 22 ...... Socket 23 ... Gunpowder 24 ... Fire extinguishing agent storage container 25 ...
...Compressed gas container 26...Tube 27...Base 28...Through hole 29...Piston 30...・・・・・・Siphon pipe 31・・・・・・・・・Control panel 32・・・・・・Warning device 33・・・・・・・Alarm device 34・・・・・・・・・Power circuit breaker 35... Indicating pressure gauge 36... Valve holder 37... Lead wire 38-...0 ring 39. ...... Pressurized gas container 40 ...... Pressurized fire extinguishing agent storage container 41 ...
...... Holder 42 ..... Cut shaft 43 ..... Gas siphon tube a ..... Extinguishing agent b ...... Compressed gas C・・・・・・・Powder fire extinguishing agent Figure 1 Figure 2 Sufu Figure 4 Procedural amendments import) June 26, 1988 Director-General of the Revision Agency Mr. "J" Koda 1986 1 Shochu'1 Application No. 128947 2 Name of the invention Automatic fire extinguishing system Address 1431 Nanoka Ichiba, Yamanashi City, Yamanashi Prefecture Name Niegy Co., Ltd. Full specification and attached drawings (Figures 2 and 3)
Specification 1, Title of the invention Automatic fire extinguishing system 2, Claims A fire extinguishing agent storage container is installed indoors or outdoors, and a plurality of conduits are branched from the container through the ceiling or floor to areas in the room where fire extinguishing is required. A sensing nozzle for injecting extinguishing agent with a mechanism that automatically opens when detecting a fire is installed at the tip of each conduit, and a pressure switch is installed in the storage container or a location near it to detect a pressure drop in the conduit. In a fire extinguishing system, a fire detector is installed in a location close to each of the above-mentioned sensing nozzles, and when a fire is detected by the fire detector, the inside of the extinguishing agent storage container and each conduit are communicated with each other. The interior is filled with a pressurized fire extinguishing agent, and the fire extinguishing agent spray sensing nozzle is roughly opened to eject the extinguishing agent, and the fire extinguishing agent is activated by both the fire detector signal and the pressure switch activation signal. An automatic fire extinguishing system characterized by activating an alarm device and/or a safety device. 3. Detailed Description of the Invention (Field of Industrial Application) The present invention is an automatic fire extinguishing system that unmannedly extinguishes an indoor fire in a group of studio apartments, for example, and remotely notifies a central control room of the occurrence of a fire in conjunction with this. It is related to. [Prior Art] In recent years, the number of studio apartments that are both functional and livable for young people has been rapidly increasing, but the current situation is that the number of fires in these studio apartments is also gradually increasing. A fire extinguishing system that operates unattended is particularly effective against such fires, and conventionally, as shown in Figure 5, a pressure-accumulating extinguishing agent storage container (chemical container) (8) is installed indoors or outdoors. , an indicating pressure gauge (35), a pressure switch (18), and a hull holder (36) are attached to the valve case (9) connected to the top of the drug container (8), and the room or place where the fire is to be extinguished. A heat-sensing sensor nozzle (2) activated by fire heat and a chemical chamber inside a chemical container (8) are connected through a flexible pipe (7), and a pressure switch (18) is installed outside. It is wired or wirelessly connected to the control v, (31), which enables the alarm (32) such as a lamp, the alarm (3) such as a beech
3) and a power supply breaker (34). When the nozzle (2) senses the heat of the fire, the chemical agent compressed to the tip of the flexible pipe (7) is ejected from the nozzle (2) due to the pressure, immediately extinguishing the fire. The pressure inside the conduit decreases due to the ejection of this medicine from the nozzle, so this is switched to the pressure switch (18
) detects this and activates the warning device (32), the alarm device (33), the power circuit breaker (34), etc. [Problem to be solved by the invention] In such a fire extinguishing system, the pressure up to the tip of each sensing nozzle is always maintained at the same pressure as in the extinguishing agent storage container, but as the number of sensing nozzles increases, the pressure between the flexible tube and the agent increases. As the number of connection points between containers and flexible tubes and sensing nozzles increases, pressure leakage from these connection points becomes a bigger problem. In addition, once the above system is installed, it is not possible to add more sensing nozzles from the same drug container or change the position of the nozzle, and in such cases, it is necessary to remove the existing drug container and install a similar system. This was extremely inconvenient for expanding the fire extinguishing system. Roughly heat-sensing type sensing nozzles sometimes detect heat other than fire heat and malfunction, so improvements have been desired from a reliability standpoint. [Means for solving the problems] In view of this, the present invention has high reliability as a result of various studies,
This is an automatic fire extinguishing system that has been developed with excellent flexibility in expanding the system.It requires a fire extinguishing agent storage container to be installed indoors or outdoors, and multiple conduits running from the container through the ceiling or floor to extinguish indoor fires. A sensing nozzle for injecting extinguishing agent with a mechanism that detects a fire and automatically opens the frontage when detecting a fire is installed at the tip of each conduit, and the pressure drop in the conduit is installed in the storage container or a location adjacent to it. In a fire extinguishing system that is equipped with a pressure switch that detects It has a mechanism that allows the fire extinguishing agent to be communicated to fill the inside of the conduit with a pressurized extinguishing agent, and roughly open the extinguishing agent injection sensing nozzle to spray out the extinguishing agent. The present invention is characterized in that the alarm device and/or the safety device are activated by both activation signals. [Function] Fire detectors are installed near each sensing nozzle, and when the fire detector detects fire heat, smoke, or flames, the inside of the fire extinguishing agent storage container and each conduit are communicated. The reason why the inside of the pipe is filled with pressurized fire extinguishing agent is because there is nothing inside the pipe installed in the ceiling or floor unless there is a temperature limit due to a fire, so it is necessary to install a sensing nozzle in accordance with the expansion or renovation of the room. This is because construction work to extend or shorten the conduit can be carried out freely in order to increase the number of conduits or change the route of the conduit. The reason why the sensing nozzle is opened separately from the detection by the sensor is to increase the certainty that it is a fire by catching the fire in two stages, thereby preventing erroneous spraying. The fire is notified to the outside by both the signal from the fire detector and the signal from the pressure switch that detects the pressure drop in the pipe due to the spray of extinguishing agent from the sensing nozzle, and activates the alarm system in the central control room. , when necessary, activate the safety device that shuts off the gas main valve and electricity.In an actual fire, the fire detector and pressure switch mentioned above are always activated, and signals from both should be generated. When only the alarm 'l1iff' or the safety device is activated, it is possible to disable the above-mentioned alarm 'l1iff' and the safety device. Incidentally, the fire extinguishing agent storage container in the system of the present invention can be used regardless of whether it is a pressure storage type or a pressurized type. (Example) The present invention will be explained in more detail with reference to Examples.Example (1) As shown in Fig. 1, in a system using an accumulating fire extinguisher, a hole cut out in the ceiling (1) of a plurality of rooms is used. Attach the nozzle fixing plate (3) to which the extinguishing agent injection sensing nozzle (2) is fixed and the fixing plate holder (5) to which the fire detector (4) is fixed with the screws (6).
), and the sensing nozzle (2) is fitted with a flexible pipe (7) as a conduit.
) is connected to the pipe inlet (11) of the pipe fitting (10) attached to the valve case (9) provided at the top of the pressure accumulation type extinguishing agent storage container (chemical container) (8), and the other is connected to the pipe inlet (11) of the pipe joint (10). The devices (4) are electrically connected in series, and one end is led to a separate drive control panel (12) containing a battery. In the figure, (35) indicates an indicator pressure gauge that indicates the internal pressure of the drug container (8). The drug container (8) also has a valve case (9) attached to the top via a cap (13) as shown in FIG.
) A communication chamber (14) with an open bottom is formed in the interior in the vertical direction, and the communication chamber (14) is passed through U4 in the vertical direction to form a pallet 1.
A valve (17) whose head (15) protrudes above the coos (9) and whose lower opening is normally closed by a spring (16).
), and roughly on the side of the valve case (9) is a pressure switch (18) that communicates with the inside of the drug container (8). Take a pipe fitting (10) with an inlet (11) (=
J-Kell. On the other hand, the above valve (17) is located at the top of the valve case (9).
Place the gunpowder starter (19) on the cylinder (20) or valve collar (2) of the starter (19) so as to cover the head (15) of the gunpowder starter (19).
It is installed by screwing into the upper part of the valve case (9) through 1). A piston (29) that slides vertically is provided inside the cylinder (20), and the screw 1
The upper end of the cylinder (29) is in contact with the internal space containing the explosive (23) of the socket (22) screwed into the two ends of the cylinder (20), and the explosive (23) is connected to the lead wire (23) from the outside. 37) and a separate drive control panel (12) shown in Figure 1.
) Explodes due to the supply of electricity from the piston (29) and pushes the piston (29) downward. In FIG. 2, (38) indicates an O-ring. The pressure switch (18) is connected by wire or wirelessly to an alarm terminal (not shown), a gas main valve, and a safety device that shuts off the primary side of electricity. This completes the installation of the fire extinguishing system in six stages, but as shown in Figures 1 and 2, if any of the fire detectors (4) in the system detects heat, smoke, or flames due to a fire, the signal will be emitted. This causes the drive control panel (12) to activate the explosive starter (
19), the gunpowder is exploded, the piston (29) is lowered, and the head (15) of the valve (17) is connected to the piston (29).
) to lower the valve (17), communicate the inside of the drug container (8) with the communication chamber (14) inside the valve case (9), and roughly sense the inside of the flexible pipe (7). Fill with the pressurized drug up to the tip where the nozzle (2) is attached. Next, the low melting point metal blocking the sensing nozzle (2) melts and falls, opening the nozzle (2), and the drug, which had been compressed to the tip of the flexible pipe (7), is pushed out of the nozzle (2) by the pressure. Extinguish the fire immediately after it erupts. Due to this fire extinguishing operation, the pressure inside the pipe (7) and the chemical container (8) decreases, so the pressure switch (18) detects this and issues a signal to the fire detector (
Combined with the signal 4), the alarm is activated and the circuit breaker is activated to cut off the power supply and waste, thereby preventing the occurrence of a secondary fire. If the fire detector (4) detects a fire, opening the room where the fire is progressing before the fire is extinguished may cause deflagration, making it impossible to achieve initial extinguishment and causing the fire to spread over a wide area. Therefore, in such a case, lock the detected room at the same time as the detector is activated, and immediately after that, the sensor λ [1 nozzle (2)] detects the temperature that rises roughly and ejects the chemical to extinguish the fire. By configuring a system that unlocks when the fire is extinguished, the temperature drops, and the heat sensor is restored, it is possible to prevent the spread of fire and create a more robust fire extinguishing system. Example (2) As shown in Figure 3, a fire extinguishing agent storage container (storage container) (24) containing only the extinguishing agent (a), CO2, N2
Compressed gas containers (25) containing only compressed gas (b) such as air are arranged independently in parallel, and there is a communication chamber (14) in the valve case (9) attached to the top of the compressed waste container (25). and the inside of the storage container (24).
26) and a cap (
When a pressurized fire extinguishing system is used, the pressurized fire extinguishing system is constructed by communicating through a through hole (28) drilled in the compressed gas container (27) and attaching one end of the flexible pipe (7) to the mouthpiece (27). ) An explosive starter (19) similar to the above is attached to the upper end of the top valve case (9), and a pressure switch (18) communicating with the inside of the storage container (24) is provided on the side of the valve case (9). Connect the pressure switch (18) to an alarm, etc. A flexible pipe (7) attached to the cap (27) on the top of the storage container (24)
) The other end is connected to the sensing nozzle for spraying fire extinguishing agent installed in each room, etc. Further, a fire detector is installed near the sensing nozzle, and when the fire detector is activated, a signal is sent to a separate drive control panel to drive the explosive starter (19). In the pressurized fire extinguishing system as described above, if any of the fire detectors detects a fire, the explosive starter (19
) explodes the gunpowder (23), lowers the piston (29), and instantly pushes down the valve (17) in the valve case (9), transferring the compressed gas (b) in the compressed gas container (25) to the communication chamber (14). ), the inside of each storage container (24) is pressurized by the tube (26), and the extinguishing agent (a) is transferred to the container (
24) Fill the flexible pipe (7) through the inner tube (30), and then the sensing nozzle is activated by the temperature that gradually rises, and the nozzle opens;
The extinguishing agent (a) compressed to the tip of the flexible pipe (7) is ejected from the nozzle by the pressure of the compressed gas (b) to extinguish the fire. This fire extinguishing operation lowers the pressure in the compressed gas container (25), which is detected by the pressure switch (18), and an external alarm is issued and electricity and gas are shut off based on the detection signal and the detection signal from the heat sensor. Example (3) A pressurized waste container (39) filled with compressed waste such as CO2, N2 or air as shown in FIG. > (40
), when using a pressurized fire extinguisher built in the powder container (40), the holder has a cutting shaft (42) that vertically passes through the holder (41) attached to the top of the powder container (40) and has an acute-angled lower end. A gunpowder starter (19) is attached so as to cover the upper end protruding from the gunpowder (41), and the gunpowder (2) of the starter (19) is
3), and the other end of the lead wire (37) is connected to a drive control panel that receives a signal from a heat sensor (not shown). Inside the rough powder container (40), one end is opened inside the fire extinguishing agent (C), and a holder (41) is placed inside the powder container (40).
Inner C1 Nybon pipe (not shown) that connects to a flexible pipe (7) that communicates with a sensing nozzle for injecting extinguishing agent.
30) and a gas siphon pipe (43) for injecting the compressed gas in the pressurized gas container (39) into the powder container (40). This is a configuration with a pressure switch installed. When the fire detector detects a fire in such a system, the signal activates the gunpowder starter (19), which lowers the piston (29) and turns it off! Press down III (42),
The pressurized gas container (39) was opened with the sharp edge of the tip, the powder container (40) and the flexible pipe (7) were filled with compressed gas, and the sensing nozzle at the tip of the flexible pipe (7) was subsequently activated. Sometimes the sensing nozzle opens and extinguishes the fire. A pressure switch detects a drop in the pressure inside the abrasive powder container (40), and based on this signal and a signal from the heat sensor, an alarm is issued to the outside or electricity and gas are shut off. (Effects of the Invention) As described above, the present invention has remarkable practical effects, such as eliminating malfunctions when extinguishing agent is ejected and ensuring the reliable operation of fire alarms and fire safety devices. . 4. Brief description of the drawings Fig. 1 is an explanatory diagram showing one embodiment of the present invention, Fig. 2 is a cross-sectional view of essential parts showing one embodiment of the present invention, and Fig. 3 is an explanatory diagram showing an embodiment of the present invention. FIG. 4 is a sectional view showing roughly another embodiment of the present invention, and FIG. 5 is an explanatory view showing a conventional example. 1... Ceiling 2... Sensing nozzle for extinguishing agent injection 3...
...Nozzle fixing plate 4...Fire detector 5...Fixing plate receiver 6...Screw 7...・Flexible pipe 8...
...Pressure-accumulating fire extinguishing agent storage container 9...Valve case 10...Pipe joint 11...Pipe inlet 12... Drive control panel 13... Cap 14... Communication chamber 15... Head 16... Spring 17... ... Valve 18 ... Pressure switch 19 ... Gunpowder starter 20 ... Cylinder 21 ... Valve color 22... Socket 23... Gunpowder 24... Fire extinguishing agent storage container 25...
...Compressed gas container 26...Tube 27...Base 28...Through hole 29...Piston 30...・・・・・・Siphon pipe 31・・・・・・・・・Control panel 32・・・・・・Warning device 33・・・・・・・Alarm device 34・・・・・・・・・Power circuit breaker 35... Indicating pressure gauge 36... Valve holder 37... Lead wire 38... O-ring 39. ...... Pressurized gas container 40 ...... Pressurized extinguishing agent storage R container 41...
...... Holder 42 ...... Cutting shaft 43 ... Gas Saibon pipe a ... Fire extinguishing agent b ... Compression Gas C・・・・・・・Powder extinguishing agent Figure 2

Claims (1)

[Claims] A fire extinguishing agent storage container is installed indoors or outdoors, and multiple conduits are branched from the container through the ceiling or floor to areas in the room where fire extinguishing is required, and fire heat is sensed at the tip of each conduit and the system automatically fires. In a fire extinguishing system, a fire extinguishing system is provided with a sensing nozzle for injecting fire extinguishing agent with a mechanism that opens automatically, and a pressure switch for detecting a pressure drop in the conduit in the storage container or a location adjacent thereto, which is located close to each of the sensing nozzles. A heat sensor is installed at each location, and when the heat sensor detects a rise in temperature due to a fire, the inside of the extinguishing agent storage container is communicated with each conduit, and the inside of the conduit is filled with pressurized extinguishing agent. Furthermore, it has a mechanism capable of opening the extinguishing agent injection sensing nozzle at a temperature higher than the above temperature to inject the extinguishing agent, and an alarm device and/or Automatic fire extinguishing system characterized by activation of safety devices.