JP2011115339A - Multi-nozzle device and gas fire extinguishing system equipped therewith - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce noise and a turbulent flow without reducing the jet pressure and speed of fire extinguishing gas. <P>SOLUTION: This multi-nozzle device 23 is provided with: the main nozzle part 30 provided to gas piping 25b and compressing the fire extinguishing gas to jet the same; and a multi-nozzle 31 having a plurality of the nozzle parts 35, which are connected to the main nozzle part 30 on the leading end side thereof and equipped with flow channels having jet orifices on the leading end sides thereof, arranged thereto. The multi-nozzle 31 has the base space communicating with the main nozzle part 30 and a plurality of the nozzle parts 35, which are formed into an almost cylindrical shape and almost the same in length, communicating with the base space. The fire extinguishing gas jetted from the main nozzle part 30 is expanded in the base space within the multi-nozzle 31 to be supplied to a plurality of the nozzle parts 35 and rectified in the respective flow channels to be ejected from the respective jet orifices 35a, thereby reducing the noise. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a multi-nozzle device for performing a fire extinguishing operation by supplying a gas into a room, and a gas fire extinguishing system including the multi-nozzle device.

Conventionally, in a room or clean room equipped with semiconductor manufacturing equipment etc. equipped with a large number of precision equipment such as large computers and servers, communication equipment equipped with various communication equipment, etc. Protect equipment by extinguishing fire to protect the equipment. When extinguishing a fire with water or a chemical digestive agent, the equipment may be damaged or malfunctioned or malfunctioned. Therefore, a fire extinguishing gas is generally used as a digestive agent.
For example, in the fire extinguishing system described in Patent Document 1, gas fire extinguishing equipment is used to inject and fill a fire extinguishing gas composed of an inert gas such as nitrogen gas, carbon dioxide gas, and halogen gas or an incombustible gas. .
Such a gas fire extinguishing equipment is effective for fire extinguishing in a room where precision equipment such as a large computer and communication equipment is installed. In this gas fire extinguishing equipment, high-pressure fire extinguishing gas is ejected at high speed from a nozzle that opens in the room so that a large amount of fire extinguishing gas can be filled in the target room in a short time.

  By the way, what is shown, for example in FIG. 8 is employ | adopted as a nozzle used for the conventional gas fire extinguishing system. For example, the nozzle 1 is disposed in a room in which a communication device or the like is installed, and a fire extinguishing gas is supplied from a gas supply source such as a gas cylinder through the gas pipe 2, and the nozzle 1 is attached to the tip of the gas pipe 2. The nozzle 1 is formed with a small-diameter jet orifice (orifice) 3 whose diameter is reduced by narrowing the tip opening of the gas pipe 2. And the gas supplied to the nozzle 1 from the gas piping 2 is compressed by the jet outlet 3, is blown out, expands, and is filled in the room.

JP 2000-60984 A

  In the conventional gas fire extinguishing system, it is necessary to eject a large amount of fire extinguishing gas in a short time to fill the room for quick fire extinguishing. Therefore, the gas ejection speed from the nozzle 1 is set to a very high speed, a shock wave is generated, and noise is generated. In addition, the gas compressed at the outlet 3 in the gas pipe 2 expands rapidly in the vicinity of the outlet 3 immediately after being injected into the room, so that a very large noise is generated. In addition, the fire extinguishing gas ejected at high speed in the vicinity of the jet outlet 3 generates turbulent flow by interfering with indoor air, preventing smooth filling of the fire extinguishing gas, and noise based on this turbulent flow (so-called turbulent noise) ) May occur.

  In view of such a situation, an object of the present invention is to provide a multi-nozzle device and a gas fire extinguishing system including the multi-nozzle device that can reduce turbulent flow and noise caused by the ejection of fire extinguishing gas.

A multi-nozzle device according to the present invention is a multi-nozzle device for injecting a fire-extinguishing gas into a room, and is provided in a pipe for supplying the fire-extinguishing gas, compressing the fire-extinguishing gas and ejecting the main nozzle unit, The present invention is characterized in that a multi-nozzle is provided, in which a plurality of nozzle portions each having a flow path having a flow path having a jet port on the front end side is provided.
According to the multi-nozzle device according to the present invention, the fire-extinguishing gas supplied through the pipe is compressed and ejected by the main nozzle portion, so that the speed of the fire-extinguishing gas is increased and noise is generated by shock waves. While suppressing the generation of noise due to the rapid expansion of the fire extinguishing gas by flowing into the nozzle, the fire extinguishing gas is rectified by dividing it into the flow paths of the plurality of nozzle parts, and from the nozzle outlet of each nozzle part Increase the rectification effect of fire extinguishing gas that blows into the room to reduce the generation of noise and turbulence.

The multi-nozzle is provided with an expansion chamber communicating with the main nozzle portion, and the fire extinguishing gas ejected from the main nozzle portion to the multi-nozzle is expanded in the expansion chamber and supplied to the plurality of nozzle portions. It is characterized by.
According to the multi-nozzle device according to the present invention, the fire extinguishing gas is compressed and ejected from the main nozzle portion and flows into the expansion chamber of the multi-nozzle, and the fire extinguishing gas is divided and distributed from the expansion chamber to the plurality of nozzle portions. As a result, the fire extinguishing gas can be rectified to reduce the generation of noise and turbulence.

Moreover, it is preferable that the plurality of nozzle portions are each formed in a substantially cylindrical shape and have substantially the same length.
As a result, the fire extinguishing gas ejected from the main nozzle portion urges rectification by flowing through a substantially cylindrical flow path at each of the plurality of nozzle portions of the multi-nozzle, and the fire extinguishing gas is ejected from the outlet of each nozzle portion. In doing so, the rectifying effect of the fire extinguishing gas can be enhanced, and noise generation can be reduced.

Moreover, it is preferable that several nozzle parts are set to the length from which a flow path differs.
When the flow paths of the plurality of nozzle portions are set to different lengths and the respective outlets are arranged at positions that are back and forth in the longitudinal direction of the flow path, when the fire-extinguishing gas is ejected from each outlet Since the generated noise band can be distributed over a wide range from the high sound range to the low sound range, the noise can be reduced.

Further, it is preferable that the plurality of nozzle portions are divided into a plurality of portions by a splitter and arranged so that the fire extinguishing gas flowing through each nozzle portion is rectified by the splitter.
As a result, the fire extinguishing gas ejected from the main nozzle part promotes rectification by flowing through the flow paths in the plurality of nozzle parts divided by the multi-nozzle splitter, and the fire extinguishing gas is discharged from the outlet of each nozzle part. When jetting, the rectifying effect of the fire extinguishing gas can be enhanced, and noise generation can be reduced.
In particular, since the splitter is formed in a streamline shape in cross section, the fire extinguishing gas flowing through the nozzle section partitioned by the splitter flows along the streamline shape of the splitter, thereby further enhancing the rectification effect. When the fire-extinguishing gas is ejected from the ejection port, the rectification effect can be further enhanced, and noise generation can be further reduced.

A gas fire extinguishing system according to the present invention includes a fire extinguishing gas supply source, and the multi-nozzle device described in any one of the above, which jets the fire extinguishing gas supplied from the supply source through a pipe into the room. .
According to the gas fire extinguishing system according to the present invention, since the fire extinguishing gas supplied from the supply source is promoted to be rectified by the multi-nozzle device, the rectifying effect can be enhanced by ejecting from the ejection port of each nozzle portion. Noise generation can be reduced.
In addition, if a pressure relief hole is provided to discharge to the outside when the pressure of the fire extinguishing gas supplied to the room is excessive, it is possible to suppress an increase in internal pressure and to adversely affect the high pressure fire extinguishing gas. Can be prevented.

  According to the multi-nozzle device and the gas fire extinguishing system using the same according to the present invention, when the fire extinguishing gas is compressed and ejected at the main nozzle portion, the ejection speed of the fire extinguishing gas increases and noise is generated due to the shock wave and expansion. By suppressing the generation of noise due to the rapid expansion of the fire extinguishing gas by flowing the gas into the multi-nozzle, it is rectified by dividing it into the flow paths of the plurality of nozzle parts, and from the nozzle outlet of each nozzle part The rectification effect of the fire-extinguishing gas to be ejected can be enhanced to reduce the generation of noise and turbulence.

It is a principal part block diagram which shows the gas fire extinguishing system by embodiment of this invention. It is a principal part disassembled perspective view which shows the multi-nozzle apparatus by 1st embodiment used with the gas fire extinguishing system shown in FIG. It is a center longitudinal cross-sectional view of the multi-nozzle apparatus shown in FIG. It is a principal part disassembled perspective view which shows the multi-nozzle apparatus by 2nd embodiment of this invention. It is a center longitudinal cross-sectional view of the multi-nozzle apparatus shown in FIG. It is a principal part disassembled perspective view which shows the multi-nozzle apparatus by 3rd embodiment of this invention. It is a center longitudinal cross-sectional view of the multi-nozzle apparatus shown in FIG. It is a principal part longitudinal cross-sectional view which shows the conventional nozzle.

Hereinafter, a gas fire extinguishing system according to an embodiment of the present invention and a multi-nozzle device used therefor will be described.
FIG. 1 shows a gas fire extinguishing system according to an embodiment of the present invention.
As shown in FIG. 1, the gas fire extinguishing system 10 according to the present embodiment includes a facility 12 in which various precision devices 11 such as a large computer and communication equipment are installed, and a fire extinguisher that supplies a fire extinguishing gas into the facility 12. The gas supply mechanism 13 is schematically configured. In the facility 12, a room 15 (room) in which various precision devices 11 such as large computers and communication devices are installed is provided, and these precision devices 11 are operated in the room 15.
Below the floor surface 16 provided in the room 15, an underfloor region 17 made up of a space is provided to constitute a double floor. In addition, a ceiling area 19 made of a space is provided above the ceiling 18 of the room 15 to form a double ceiling. The ceiling area 19 and the underfloor area 17 communicate with the space of the room 15 through communication paths 20 and 20 provided at one end of the ceiling 18 and the floor surface 16, for example.

Next, the fire extinguishing gas supply mechanism 13 will be described.
A multi-nozzle device 23 according to the present embodiment for injecting a fire extinguishing gas into each room 15, the underfloor region 17, and the ceiling region 19 is attached to one side wall 12 a of the facility 12.
In the fire extinguishing gas supply mechanism 13, a fire extinguishing gas supply source 24 including a pressure vessel such as a gas cylinder for storing the fire extinguishing gas in a high pressure state is provided as a supply source. As the fire extinguishing gas, for example, an inert gas such as nitrogen gas, carbon dioxide gas, or halogen gas or a nonflammable gas is used. In this embodiment, nitrogen gas is preferably used.
The gas pipe 25 extending from the fire extinguishing gas supply source 24 is, for example, branched into three, and each of the branch pipes 25a, 25b, 25c is provided in the side wall 12a of the room 15, the underfloor area 17, and the ceiling area 19, respectively. 23.
The gas pipe 25 before branching is provided with a control valve 27 for controlling the opening and closing of the gas pipe 25, but may instead be provided in each branch pipe 25a, 25b, 25c. For example, when a fire occurs in the room 15, the control valve 27 is sensed by a sensor such as a fire alarm (not shown) provided in the room 15 to open the control valve 27 and let the fire extinguishing gas pass through each multi-nozzle device 23. It is made to eject into the room 15, the underfloor area 17, and the ceiling area 19, respectively.
In the facility 12, a pressure avoidance port 28 is provided on the side wall 12 b on the side facing the side wall 12 a and provided with the communication path 20. The pressure avoidance port 28 adjusts the internal pressure of the room 15 by releasing the pressure to the outside when the extinguishing gas pressure or the atmospheric pressure in the room 15 becomes excessive. As a result, it is possible to prevent a person and various precision instruments 11 from being adversely affected by the fire extinguishing gas pressure filling the room 15.

Next, the multi-nozzle device 23 will be described with reference to FIGS. 2 and 3 as a first embodiment of the present invention. The multi-nozzle devices 23 provided in the room 15, the underfloor region 17, and the ceiling region 19 all have the same configuration. The multi-nozzle device 23 provided in the room 15 will be described as a representative. The multi-nozzle device 23 includes a main nozzle portion 30 provided at the tip of the branch pipe 25b (gas pipe 25) and a multi-nozzle 31 attached to the tip side.
In the multi-nozzle device 23 shown in FIGS. 2 and 3, the main nozzle portion 30 provided at the tip of the cylindrical branch pipe 25b (gas pipe 25) has, for example, a two-stage cylindrical shape with a diameter reduced toward the tip side. A branch pipe 25b is fitted into the enlarged cylindrical portion 30a, and a small-diameter jet port (orifice) 32 is formed in the reduced-diameter cylindrical portion 30b by narrowing the opening.

The multi-nozzle 31 is generally configured by a base 33 and a main body 34. The base 33 has, for example, a fitting portion 33a that is formed into a substantially small-diameter cylindrical shape and that has a reduced-diameter cylindrical portion 30b that forms the ejection port 32 of the main nozzle portion 30, and a base that is expanded in diameter from the fitting portion 33a. A space 36 is provided.
The main body 34 provided on the distal end side of the base 33 has, for example, a substantially rectangular tube shape. In the main body 34, for example, a plurality of nozzle portions 35 each having a substantially rectangular tube shape are arranged in close contact in the vertical and horizontal directions to form a bundle. Each nozzle portion 35 has a base end portion communicating with the base space 36 and is connected to the jet port 32 of the main nozzle 30 via the base space 36 and the fitting portion 33a. The base space 36 constitutes an expansion chamber in which the fire extinguishing gas ejected from the main nozzle portion 30 is expanded.
The plurality of nozzle portions 35 provided in the multi-nozzle 31 have the same length dimension, and the jet outlet 35a at the tip thereof is formed substantially flush. Moreover, although each nozzle part 35 was made into the square cylinder shape, arbitrary polygonal cylinder shapes, such as a hexagonal cylinder shape and an octagonal cylinder shape, are employable. Alternatively, it may be a cylindrical shape, and the cross-sectional shape of the nozzle portion 35 is arbitrary.

  The fire extinguishing gas compressed and ejected at the ejection port 32 of the main nozzle part 30 accelerates the gas flow, flows to the multi-nozzle 31 and expands in the base space 36, but is divided by the plurality of nozzle parts 35. Then, it flows through the flow path of each nozzle portion 35 and is ejected from the ejection port 35a to the outside. For this reason, excessive expansion of the fire extinguishing gas in the base space 36 is suppressed to reduce noise, and the fire extinguishing gas is divided by the plurality of nozzle portions 35 and rectified and flows in each flow path. Therefore, the fire extinguishing gas ejected from each nozzle portion 35 flows out at a high speed, and the rectifying effect is enhanced to prevent turbulent flow and reduce noise.

The multi-nozzle device 23 including the multi-nozzle 31 according to the present embodiment has the above-described configuration. Next, the operation of the gas fire extinguishing system 10 including the multi-nozzle device 23 will be described.
When a fire occurs in the room 15 equipped with the equipment 11 in the facility 12, this is detected by a sensor such as a fire alarm and a signal is input to the control valve 27 of the fire extinguishing gas supply mechanism 13 to open the fire. Gas is supplied from the fire extinguishing gas supply source 24 to each multi-nozzle device 23 via the gas pipe 25. A fire extinguishing gas is jetted from each multi-nozzle device 23 through the multi-nozzle 31 to the ceiling area 19, the room 15, and the underfloor area 17 to fill the room.

That is, in the multi-nozzle device 23 provided in the room 15, the fire extinguishing gas is supplied from the gas pipe 25 to the main nozzle unit 30 through the branch pipe 25 b. The fire extinguishing gas is compressed by the jet outlet 32 of the main nozzle portion 30 and passes through the jet outlet 32 to be accelerated and jetted at a high speed. When reaching the base space 36 of the multi-nozzle 31, the fire extinguishing gas expands, but the base 33 Excessive expansion is suppressed by the base space 36 formed therein. And fire extinguishing gas is divided | segmented by each flowing in into the some nozzle part 35 from the base space 36, and is injected outside, distribute | circulating the linear flow path of each nozzle part 35, and being rectified.
Therefore, even if the fire extinguishing gas passes through the ejection port 32 of the main nozzle portion 30, expansion is suppressed by the base space 36 formed in the base portion 33 of the multi-nozzle 31, thereby suppressing generation of noise. The fire extinguishing gas flows into the plurality of nozzle portions 35 provided in the main body 34 of the multi-nozzle 31, so that the fire extinguishing gas in the base space 36 is divided and rectified and ejected from each ejection port 35 a. In addition, it is possible to suppress the generation of noise caused by expansion, turbulence, and shock waves of the fire extinguishing gas.

The fire extinguishing gas is jetted into the room 15 with a rectifying effect enhanced by the multi-nozzle 31, thereby suppressing expansion and generation of turbulent flow (due to interference with air) while maintaining the jetting pressure and speed of the fire extinguishing gas. Thus, the generation of loud noise can be suppressed. Therefore, it is possible to suppress the energy of noise caused by excessive expansion, turbulent flow, and generation of shock waves caused by excessive ejection speed generated when the fire extinguishing gas is ejected.
In addition, the fire extinguishing gas is ejected from the main nozzle part 30 through the plurality of nozzle parts 35 of the multi-nozzle 31, so that a high ejection speed can be secured and the room 15 can be filled with the fire extinguishing gas. Thereby, it is possible to quickly extinguish the fire in the room 15 and protect the precision device 11 such as a communication device or a computer.

In the above description, the multi-nozzle device 23 provided in the room 15 has been described. However, a fire-extinguishing gas with reduced noise is ejected from the multi-nozzle device 23 provided in the ceiling region 19 and the underfloor region 17 by the same action. Is done.
Further, the internal pressure rises due to the fire extinguishing gas filled in the room 15, the ceiling area 19 and the underfloor area 17, and when the pressure exceeds the set pressure, the pressure relief opening 28 can be opened to communicate with the atmosphere. As a result, the fire extinguishing gas in the facility 12 is exhausted to lower the internal pressure, and the worker and the equipment 11 are not adversely affected.

  As described above, according to the multi-nozzle device 23 and the gas fire extinguishing system 10 including the multi-nozzle device 23 according to the present embodiment, expansion, turbulent flow, and shock waves of the fire extinguishing gas ejected into the facility 12 by the multi-nozzle device 23 when a fire occurs. Generation, excessive jetting speed can be suppressed, and the nozzles 35 can be rectified and jetted to reduce noise and turbulence.

Next, a multi-nozzle device 23 according to another embodiment of the present invention will be described. However, the same or similar members and parts as those of the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted.
4 and 5 show a multi-nozzle device 23 according to a second embodiment of the present invention. The multi-nozzle 38 in the multi-nozzle device 23 according to the second embodiment includes a base 33 having a base space 36 therein, and a main body 39 provided on the front side of which a plurality of nozzles 40 are arranged. The plurality of nozzle portions 40 have, for example, a substantially rectangular tube shape, and the base end portions are provided at the same position, that is, flush with the base space 36, but their lengths are random or unequal. There is a length, and the tip discharge port 40a is disposed at any different position in the length direction.

Therefore, according to the multi-nozzle device 23 according to the second embodiment, when the fire-extinguishing gas is ejected from the main nozzle portion 30 through the multi-nozzle 38, the fire-extinguishing gas whose speed has increased through the ejection port 32 of the main nozzle 30 is Although it expand | swells in the base space 36 of the multi-nozzle 38 via the fitting part 33a, it ejects through each nozzle part 40, The length of each nozzle part 40 differs. Therefore, the fire extinguishing gas ejected from each nozzle portion 40 has a different noise band depending on the length of each nozzle portion 40. In the nozzle portion 40 having a relatively long length, the noise generation band is in a low sound range, but in the nozzle portion 40 having a short length, noise in a relatively high sound range is generated.
Therefore, by arranging a plurality of nozzle portions 40 having different lengths, the noise generation band can be dispersed and the peak sound pressure in the high frequency band can be reduced.

In the multi-nozzle device 23 according to the second embodiment described above, the nozzle portions 40 having different lengths in the multi-nozzles 38 are formed and arranged at random lengths or unequal lengths. Arrangement is arbitrary, and a plurality of nozzle portions 40 having the same length or adjacent to each other are arranged in one direction, and the length of the nozzle portions 40 is sequentially changed in a direction perpendicular to the nozzle portion 40, thereby arranging in a stepped manner. You may do (refer FIG. 4).
In the second embodiment described above, the base end portions of the nozzle portions 40 are provided flush with each other at the same position communicating with the base space 36. However, instead of this configuration, the base end portions are not flush with each other. It may be provided at random positions. In this case, the opening 40a at the tip may be provided at a random length position or may be arranged flush with each other.

  As described above, according to the multi-nozzle device 23 according to the second embodiment, the fire extinguishing gas flowing from the main nozzle part 30 to the multi-nozzle 38 is divided into a plurality of nozzle parts 40 and rectified, and the flow path length is increased. Since it is made to eject from a plurality of different nozzle parts 40, the generated noise can be reduced by dispersing from the high sound range to the low sound range.

6 and 7 show a multi-nozzle device 23 according to a third embodiment of the present invention.
The multi-nozzle 42 in the multi-nozzle device 23 according to the third embodiment has a main body 43 formed in a substantially rectangular parallelepiped box shape, for example. A substantially cylindrical fitting portion 44 for fitting the reduced diameter cylindrical portion 30 b of the main nozzle 30 is connected to the base end surface 43 a of the main body 43 of the multi-nozzle 42.
In the main body 43 of the multi-nozzle 42, for example, a plurality of substantially plate-like splitters 45 arranged in a substantially horizontal direction are arranged at predetermined intervals in the vertical direction, and both side portions thereof are arranged on opposite side walls 43b and 43b of the main body 43. It is fixed. The front end surface of the main body 43 that faces the base end surface 43a is an opening 46, and the openings 46 are divided in the vertical direction by a plurality of splitters 45 to form the ejection ports 46a.

In the longitudinal sectional view of the multi-nozzle 42 shown in FIG. 7, a base space 36 is defined between the splitter 45 in the main body 43 and the base end surface 43 a provided with the fitting portion 44, and a plurality of splitters formed on the front side thereof. A plurality of wide flow channels partitioned in layers in the vertical direction by 45 form a nozzle portion 47.
Here, as shown in the longitudinal section of FIG. 7, the splitter 45 is formed in, for example, an airfoil streamline, and the fire extinguishing gas ejected from the main nozzle 30 is divided by the nozzle portion 47 partitioned by the splitter 45. Then, it is rectified by flowing along the surface of the splitter 45 and is ejected from the ejection port 46a.

Since the multi-nozzle device 23 according to the third embodiment has the above-described configuration, the fire extinguishing gas flows through the branch pipes 25b (25a, 25c) of the gas pipe 25 and is compressed through the outlet 32 of the main nozzle part 30. As a result, the ejection speed increases and a shock wave is generated. The fire extinguishing gas having increased speed flows into the multi-nozzle 42 and expands in the base space 36 formed by expanding the diameter to generate noise.
Further, the fire extinguishing gas is divided into a plurality of layers from the base space 36 by the splitter 45 in the multi-nozzle 42 and flows through the nozzle portion 47. However, since the upper and lower surfaces of the splitter 45 are formed in a streamline shape, the rectifying effect is obtained. The fire extinguishing gas is stratified and rectified and is ejected from each ejection port 46a of the opening 46. The fire extinguishing gas is rectified by the splitter 45 to suppress turbulent flow and reduce noise.
Therefore, since the fire extinguishing gas ejected from the multi-nozzle 42 into the chamber 15 is rectified, turbulent flow is suppressed, noise energy is reduced, and generation of noise can be suppressed.

  As described above, according to the multi-nozzle device 23 according to the third embodiment, the fire extinguishing gas that has flowed into the main body 43 of the multi-nozzle 42 and has been expanded slightly is divided into a plurality of layers by the plurality of splitters 45. When flowing through the plurality of nozzle portions 47, rectification is promoted by the splitter 45 and fire extinguishing gas is ejected, and noise generated by expansion, turbulent flow, and shock waves in the main nozzle portion 30 can be suppressed.

  In the multi-nozzle 42 according to the third embodiment described above, the splitter 45 is disposed in the horizontal direction in the main body 43 and the plurality of nozzle portions 47 that are layered in the vertical direction are disposed. However, the splitter 45 is not necessarily horizontal. It is not necessary to arrange in the direction, and a plurality of nozzle portions arranged in the vertical direction and layered in the horizontal direction may be arranged. Further, the splitters 45 in the main body 43 are not limited to the configuration arranged in only one direction, and may be arranged in a lattice shape to form a plurality of lattice-shaped nozzle portions 47, for example.

In the gas fire extinguishing system 10 according to each of the above-described embodiments, the fire extinguishing gas is jetted and filled in the room 15, the ceiling area 17, and the underfloor area 19 in a state where noise is reduced, but the present invention is limited to this. There is nothing. It suffices if the multi-nozzle device 23 is provided at least in the room 15 in which the equipment 11 is provided, and the fire-extinguishing gas with reduced noise is injected and filled. Needless to say, the facility 12 may not have the ceiling region 17 constituting the double ceiling and the underfloor region 19 constituting the double floor.
In addition to the cause of noise generation caused by the fire extinguishing gas ejection from the nozzle 30, resonance occurs in the piping itself when a high-speed fire extinguishing gas flow passes through the gas piping 25, 25 a, 25 b, 25 c, and the vibration is generated in the facility. 12 propagates in the air in the air and contributes to the generation of noise. In order to suppress pipe vibration due to such resonance, the outer peripheral surfaces of the pipes 25, 25a, 25b, and 25c are coated with a material having sound absorbing performance made of an appropriate material such as metal, synthetic resin, rubber, or the like that is different from the pipe. Sound absorbing performance may be added.

  In each of the above-described embodiments, the fire extinguishing gas supply mechanism 13 employed in the facility 12 having the room 15 in which a large computer, a communication device, and the like are disposed is described as the gas fire extinguishing system. However, the gas fire extinguishing system according to the present invention is as described above. It is needless to say that the present invention is not limited to such a facility 12 and can be applied to other appropriate facilities. For example, the gas fire extinguishing system 10 and the multi-nozzle device 23 having the multi-nozzles 31, 38, 42 according to the present invention are employed in a clean room or the like equipped with semiconductor manufacturing equipment or other equipment in facilities that dislike dust as the equipment 11. May be.

10 Gas fire extinguishing system 11 Equipment 12 Facility 13 Fire extinguishing gas supply mechanism 15 Room (room)
23 Multi-nozzle device 24 Fire extinguishing gas supply source 25 Gas pipe 25a, 25b, 25c Branch pipe (gas pipe)
30 Main nozzle part 31, 38, 42 Multi nozzle 32 Jet 35, 40, 47 Nozzle 35a, 40a, 46a Jet 36 Base space 45 Splitter

Claims (6)

A multi-nozzle device for injecting a fire extinguishing gas into a room;
A main nozzle part that is provided in a pipe for supplying a fire extinguishing gas and compresses the fire extinguishing gas and jets it;
A multi-nozzle device comprising: a multi-nozzle having a plurality of nozzle portions arranged on the front end side of the main nozzle portion and provided with a flow path having a jet outlet on the front end side.   The multi-nozzle is provided with an expansion chamber communicating with the main nozzle portion, and fire extinguishing gas ejected from the main nozzle portion to the multi-nozzle is expanded in the expansion chamber and supplied to the plurality of nozzle portions. The multi-nozzle device according to claim 1, wherein   3. The multi-nozzle device according to claim 1, wherein each of the plurality of nozzle portions is formed in a substantially cylindrical shape and has substantially the same length.   The multi-nozzle device according to claim 1 or 2, wherein the plurality of nozzle portions have different lengths of flow paths.   The multi-nozzle device according to claim 1, wherein the plurality of nozzle portions are divided into a plurality of portions by a splitter and arranged so that the fire-extinguishing gas flowing through the nozzle portions is rectified by the splitter. A source of fire extinguishing gas,
A gas fire extinguishing system comprising the multi-nozzle device according to any one of claims 1 to 5, wherein fire extinguishing gas supplied through a pipe from the supply source is ejected into a room.

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