JP2019034272A - Fluid lead-out device, smoke exhausting and fire extinguishing method using the same, and portable type smoke exhausting and fire extinguishing apparatus using the same - Google Patents

Abstract

To provide a fluid lead-out device capable of spreading a fluid jetted from a jet-flow port over a prescribed range by suppressing reduction in the flow rate.SOLUTION: A fluid lead-out device 1 comprises: a flow passage tube 10 in which a fluid flows; a jet-flow port 11 for jetting the fluid flowing in the flow passage tube 10; and a diffusion member 20 disposed in the jet-flow port 11. The diffusion member 20 includes a flow direction change part 22 for changing a flow direction of the fluid, and the fluid jetted from the jet-flow port 11 is diffused according to rotation of the diffusion member 20.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a fluid derivation device particularly suitable for a flue gas extinguishing method and a portable flue gas extinguishing device that forcibly discharges smoke and hot air generated in a fire compartment such as a building to the outside of the fire compartment to extinguish the fire.

In building fires, especially fire-resistant building fires, the biggest factors hindering fire extinguishing and lifesaving activities in fire compartments are concentrated smoke and hot air in the fire compartment. Concentrated smoke and hot air (heated air) in the fire compartment prevent fire (lifesaving) members from entering the fire compartment, making it difficult to find fire points and rescuers, It is a threat.
Some buildings are obligated to install smoke removal equipment under the Building Standards Law (theaters, movie theaters, hospitals, schools, hotels, department stores, etc. that meet the standards stipulated by the Building Standards Law) Many proposals have been made for smoke exhausting equipment fixedly installed in such buildings (for example, Patent Documents 1 and 2).
On the other hand, if a fire breaks out in a residential building or office building where a smoke evacuation facility is not installed, a firefighter (lifesaving) member carries a portable smoke evacuator near the fire compartment. Operate the smoke device to forcibly blow air into the fire compartment from the opening of the fire compartment entrance, etc., and concentrate the concentrated smoke and heated air out of the fire compartment with smoke and heated air from the exhaust port of the fire compartment. A smoke exhausting method is used.
In general, a portable blower device is used as the fluid outlet device used in the smoke exhaustion method as described above. Firefighting (lifesaving) members carry portable blower equipment close to the fire compartment for fire fighting and rescue activities. In addition, there is a fan in which a fan for blowing / smoke (blower device) and a dedicated duct connected thereto are mounted on a multipurpose work vehicle (Patent Document 3).
Portable blower devices used in fire fighting and rescue activities are generally large in volume and weigh several tens of kilograms, making it difficult for a member to carry alone. Also, since elevators cannot be used in the event of a fire, transporting the smoke evacuation device to the fire section on the upper and lower floors is a heavy burden on the crew.

The portable blower device generates a blown airflow by the rotation of the blower blades, and the cross-sectional shape of the generated blower airflow is the same circle as the rotation locus of the blower blades. On the other hand, the entrances (openings) of fire compartments such as living rooms and office rooms are usually rectangular with an aspect ratio of 2: 1.
FIG. 10 shows the state of use of the blower device in a fire area.
FIG. 10A shows a case where the blower device a is used close to the entrance c of the fire area b.
By using the blower device a close to the inlet c, all the air flow from the blower device a can be supplied into the fire compartment b from the inlet c.
However, the blowing area d at the inlet c covers only a part of the inlet c.
Therefore, the air blown from the blower device a flows backward from the portion of the inlet c that is not covered by the air blowing area d, and the smoke and heated air in the fire area b are not easily discharged from the exhaust port e such as a window.
FIG. 10B shows a case where the blower device a is used away from the entrance c of the fire area b.
By using the blower device a away from the inlet c, the blowing area d can cover the entire area of the inlet c.
However, in the part of the ventilation area | region d which remove | deviated from the entrance c, the ventilation from the blower apparatus a does not enter into the fire division b.

FIG. 11 shows parameters in a state where the air blowing area d covers the entire area of the inlet c.
If the radius of the blowing area d is R, the width of the inlet c is L, and the height is 2L, the area of the blowing area d is π × R ² and the area of the inlet c is 2L ² . Here, since R ² = (5/4) L ² , the area ratio of the inlet c to the blowing region d is 2L ² / π (5/4) L ² , that is, 51%.
That is, under the conditions shown in FIG. 11, the air blowing efficiency is reduced by about 50%. Further, since the blower device a is disposed away from the inlet c, it is necessary to use a stronger blower device a in order to forcibly blow the air into the fire compartment b with a predetermined wind pressure.
In addition, when the front space of the entrance c is narrow (such as a middle-high-rise building with a narrow corridor), the blower device a cannot be used as shown in FIG. 10B.
In order to solve such problems, Patent Document 4 presents a portable smoke exhaust device that uses the compressed air of a CAFS vehicle, is light and small, is easy to carry, and has high blowing efficiency into the fire compartment. ing.
The portable smoke evacuation apparatus of Patent Document 4 is mainly configured by an injection nozzle group including a plurality of injection nozzles that inject compressed air and a nozzle arrangement member in which the injection nozzle group is arranged. The nozzle arrangement member is formed of a tube material so that compressed air can be supplied to each injection nozzle, and a plurality of horizontal tube portions are provided, and a plurality of injection nozzles are arranged at predetermined intervals in these horizontal tube portions. A contour line connecting the centers of the plurality of injection nozzles located on the outer edge side of the injection nozzle group has a rectangular shape that matches the shape of the opening of the fire compartment.

Japanese Patent Laid-Open No. 11-19237 JP 2002-536093 A JP 2003-81000 A Japanese Patent No. 5587234

In patent document 4, the function for fire extinguishing is not provided like the conventional blower type positive pressure smoke exhaust apparatus. Therefore, it is necessary for firefighters to quickly enter the fire section b and extinguish it at the same time as smoke is exhausted by blowing air to the fire section b. However, the approach to the fire zone b during the hot season is a dangerous action, and from the viewpoint of ensuring the safety of the members, a device that can realize fire extinguishing at the same time as smoke is ideal.
Moreover, although patent document 4 has high ventilation efficiency compared with the conventional blower type smoke exhaust apparatus, in order to obtain a uniform wind pressure with respect to an air supply port, it is necessary to provide a fixed quantity of injection nozzles. However, this leads to an increase in cost.
In order to realize a lower-cost portable flue gas fire extinguishing device, a fluid derivation device that can expand the fluid ejected from the jet port to a predetermined range while suppressing a decrease in the flow velocity without providing a large number of ejection nozzles. desired.

An object of this invention is to provide the fluid derivation | leading-out apparatus which can expand the fluid which ejects from a jet nozzle to the predetermined range, suppressing the fall of the flow velocity.
It is another object of the present invention to provide a flue gas extinguishing method and a portable flue gas extinguishing device that can introduce a fluid expanded in a predetermined range and easily discharge smoke and heated air from a second opening.
Another object of the present invention is to provide a flue gas extinguishing method and a portable flue gas extinguishing device that can enhance the diffusion effect and extend the reach distance and easily discharge smoke and heated air.

The fluid derivation device according to the first aspect of the present invention includes a flow channel pipe through which a fluid flows, a jet port for ejecting the fluid flowing through the flow channel tube, and a diffusion member disposed in the jet port, and the diffusion The member has a flow direction changing portion that changes the flow direction of the fluid, and diffuses the fluid ejected from the jet port by the rotation of the diffusion member.
According to a second aspect of the present invention, in the fluid derivation device according to the first aspect, a high-density region is formed in the fluid by the flow direction changing unit, and an extension line of the tube axis of the flow channel pipe is virtually assumed. When the jet axis is used, the high-density region is formed in a radial direction from the virtual jet axis with respect to a virtual jet cross section orthogonal to the virtual jet axis, and the high-density region is obtained by rotation of the diffusion member. It turns in one direction around the virtual jet axis.
According to a third aspect of the present invention, in the fluid lead-out device according to the first or second aspect, a first nozzle is provided in the flow channel tube, the first nozzle is disposed upstream of the diffusion member, The fluid ejected from the first nozzle is guided to the diffusion member.
According to a fourth aspect of the present invention, in the fluid lead-out device according to the third aspect, a second nozzle is provided in the first nozzle, a gas is ejected from the second nozzle, and the second nozzle is ejected from the first nozzle. It is characterized by ejecting the fluid which is a gas-liquid mixed phase flow by mixing gas and liquid.
According to a fifth aspect of the present invention, in the fluid lead-out device according to any one of the first to fourth aspects, the guide for regulating diffusion of the fluid ejected from the jet port downstream of the diffusion member. A flow member is provided.
According to a sixth aspect of the present invention, in the fluid lead-out device according to the fifth aspect, the cross-sectional shape of the upstream flow guide member opening of the flow guide member and the downstream flow guide member opening of the flow guide member The opening area of the downstream flow guide member opening is larger than that of the upstream flow guide member opening.
According to a seventh aspect of the present invention, in the fluid lead-out device according to the sixth aspect, the upstream flow guide member opening is connected to the jet port, and the downstream flow guide member opening is rectangular. It is characterized by.
According to an eighth aspect of the present invention, in the fluid lead-out device according to the fifth aspect, the flow guide member includes at least a pair of opposed flow guide plate materials, and the pair of flow guide plate materials serve as the jet ports. It is connected.
According to a ninth aspect of the present invention, in the fluid lead-out device according to the eighth aspect, the downstream end of the flow guide plate is enlarged from the upstream end of the flow guide plate, and the flow guide plate The width is gradually increased from the upstream end toward the downstream end.
According to a tenth aspect of the present invention, in the fluid derivation device according to any one of the first to ninth aspects, the diffusion member is rotated by the fluid flowing through the flow path tube. .
The present invention according to claim 11 is the fluid derivation device according to any one of claims 1 to 10, wherein the diffusion member has a cylindrical portion body disposed inside the jet port, The flow direction changing portion is formed on the inner peripheral surface of the cylindrical portion main body.
The present invention according to claim 12 is the fluid derivation device according to any one of claims 1 to 10, wherein the diffusion member has a cylindrical body disposed inside the jet port, The flow direction changing portion is formed downstream of the cylindrical portion main body.
According to a thirteenth aspect of the present invention, in the fluid derivation device according to the eleventh or twelfth aspect, a through-hole extending from the inner peripheral surface to the outer peripheral surface is formed in the cylindrical body.
According to a fourteenth aspect of the present invention, in the fluid lead-out device according to the thirteenth aspect, the outer peripheral opening in the outer peripheral surface of the through hole is made larger than the inner peripheral opening in the inner peripheral surface of the through hole. It is characterized by that.
According to a fifteenth aspect of the present invention, in the fluid derivation device according to the eleventh or twelfth aspect, the cylindrical portion main body has a hollow shaft portion, and the hollow shaft is provided on an inner peripheral side of the cylindrical portion main body. The flow direction changing portion is arranged on the outer peripheral side of the portion, and the fluid flowing in the cylindrical portion main body is between the first fluid flowing in the hollow shaft portion and the cylindrical portion main body and the hollow shaft portion. The second fluid flows, the flow direction of the first fluid is not changed, and the flow direction of the second fluid is changed.
According to a sixteenth aspect of the present invention, in the fluid derivation device according to the fifteenth aspect, the cylindrical portion main body and the hollow shaft portion are connected by the flow direction changing portion.
According to a seventeenth aspect of the present invention, in the fluid lead-out device according to the fifteenth aspect, the outer diameter of the downstream hollow shaft opening of the hollow shaft portion is the outer diameter of the upstream hollow shaft opening of the hollow shaft portion. It is characterized by being larger than.
The present invention according to claim 18 is the fluid lead-out device according to claim 3 or claim 4, wherein an air hole is formed in the flow path tube, and the negative pressure generated by the fluid ejected from the first nozzle is used. Air is sucked into the channel pipe from the air hole.
A flue gas fire extinguishing method according to a nineteenth aspect of the present invention is a flue gas fire extinguishing method using the fluid lead-out device according to any one of the first aspect to the eighteenth aspect of the present invention. Introducing the fluid supplied from a compressed air source and a water supply source mounted on a vehicle, and introducing the fluid ejected from the jet port into the fire compartment from a first opening in the fire compartment; Smoke and heated air in the fire compartment are exhausted from the second opening in the fire compartment.
The exhaust gas fire extinguishing method according to claim 20 of the present invention is an exhaust gas fire extinguishing method using the fluid lead-out device according to claim 4, wherein the gas is any one of air, nitrogen, and carbon dioxide, The fluid in the gas-liquid mixed phase flow includes fire extinguishing water or a fire extinguishing agent.
The portable flue gas fire extinguishing device of the present invention described in claim 21 is a portable flue gas fire extinguishing device using the fluid lead-out device according to any one of claims 1 to 18, wherein the flow path A fire hose for introducing the fluid supplied from a compressed air source or a water supply source mounted on a fire truck is connected to the pipe, and the fluid ejected from the jet port is connected to the first opening in the fire compartment. It introduce | transduces into the said fire division, The smoke and heating air in the said fire division are discharged | emitted from the 2nd opening part in the said fire division.
A portable flue gas fire extinguishing apparatus according to a twenty-second aspect of the present invention is a portable flue gas fire extinguishing apparatus using the fluid lead-out device according to the fourth aspect, wherein the gas is made of air, nitrogen, and carbon dioxide. In any case, the fluid in the gas-liquid mixed phase flow includes fire-extinguishing water or a fire-extinguishing agent.

According to the fluid derivation device of the present invention, the fluid ejected from the jet port can be expanded to a predetermined range while suppressing the decrease in the flow velocity.
Moreover, according to the smoke-extinguishing method and the portable smoke-extinguishing device of the present invention, it is possible to introduce a fluid expanded to a predetermined range, and to easily discharge smoke and heated air from the second opening.
Moreover, according to the smoke-extinguishing method and the portable smoke-extinguishing device of the present invention, the diffusion effect can be enhanced and the reach distance can be increased, so that smoke and heated air can be easily discharged.

Sectional drawing which shows the structure of the fluid derivation | leading-out apparatus by one Example of this invention. 1 is a perspective view of the diffusing member shown in FIG. Image diagram explaining jet flow by the diffusion member FIG. 1 is a plan view and a side sectional view of the flow guide member shown in FIG. A perspective view of a portable flue gas fire extinguishing device using a fluid outlet device according to the present embodiment Explanatory drawing which shows the flue gas fire extinguishing method using the fluid derivation device by a present Example The photograph which shows the composition of the fluid derivation device by other examples of the present invention. Photograph showing an operation confirmation experiment by the fluid derivation device according to the embodiment shown in FIG. FIG. 6 is a perspective view of a diffusing member according to still another embodiment of the present invention. The figure which shows the use condition in the fire area of the conventional blower device The figure which shows the parameter in the state in which the conventional ventilation area covers the whole entrance area

  In the fluid derivation device according to the first embodiment of the present invention, the diffusion member has a flow direction changing unit that changes the flow direction of the fluid, and diffuses the fluid ejected from the jet port by the rotation of the diffusion member. It is. According to the present embodiment, the fluid ejected from the jet port can be expanded to a predetermined range while suppressing the decrease in the flow velocity.

  According to the second embodiment of the present invention, in the fluid derivation device according to the first embodiment, a high-density region is formed in the fluid by the flow direction changing unit, and an extension line of the tube axis of the flow path tube is virtually assumed. When the jet axis is used, the high density region is formed in a radial direction from the virtual jet axis with respect to the virtual jet cross section orthogonal to the virtual jet axis, and the high density region is centered on the virtual jet axis by the rotation of the diffusion member. It turns in one direction. According to this embodiment, the reach distance of the fluid expanded to a predetermined range can be extended by turning the high-density region.

  According to a third embodiment of the present invention, in the fluid derivation device according to the first or second embodiment, the first nozzle is provided in the flow path pipe, the first nozzle is disposed upstream of the diffusion member, and the first The fluid ejected from the nozzle is guided to the diffusing member. According to the present embodiment, by increasing the flow velocity of the fluid guided to the diffusion member, the diffusion effect can be enhanced and the reach distance can be extended.

  According to a fourth embodiment of the present invention, in the fluid derivation device according to the third embodiment, the second nozzle is provided in the first nozzle, the gas is ejected from the second nozzle, and the gas is ejected from the first nozzle. And a liquid are mixed to eject a fluid in a gas-liquid mixed phase flow. According to the present embodiment, by using a gas-liquid mixed phase flow, the diffusion effect can be enhanced and the reach distance can be extended.

  According to a fifth embodiment of the present invention, in the fluid derivation device according to any one of the first to fourth embodiments, a flow guide member that regulates diffusion of the fluid ejected from the jet port is provided downstream of the diffusion member. It is provided. According to the present embodiment, by restricting the diffusion of the fluid by the flow guide member, it is possible to match the shape of the target space or the target object, and to allow the fluid to reach the target space or the entire area of the target object without waste. it can.

  A sixth embodiment of the present invention is a fluid derivation device according to the fifth embodiment, in which a cross section of an upstream flow guide member opening of a flow guide member and a downstream flow guide member opening of the flow guide member The shape is different, and the opening area of the downstream side diversion member opening is larger than that of the upstream side diversion member opening. According to the present embodiment, it is possible to regulate the diffusion of the fluid according to the shape of the target space or the target object without hindering the diffusion effect by the diffusion member.

  According to a seventh embodiment of the present invention, in the fluid derivation device according to the sixth embodiment, the upstream flow guide member opening is connected to the jet port, and the downstream flow guide member opening is rectangular. It is. According to the present embodiment, when the shape of the target space or the target object is a rectangular shape, it can be matched to the shape of the target space or the target object, and the fluid can reach the entire target space or the target object without waste. be able to.

  According to an eighth embodiment of the present invention, in the fluid derivation device according to the fifth embodiment, the flow guide member includes at least a pair of opposed flow guide plate materials, and the pair of flow guide plate materials serve as jet nozzles. Connected. According to the present embodiment, the pair of flow guide plates can match the shape of the target space or the target object, and the fluid can reach the entire target space or the target object without waste.

  In the fluid derivation device according to the eighth embodiment, the ninth embodiment of the present invention expands the downstream end portion of the flow guide plate material from the upstream end portion of the flow guide plate material, and the width of the flow guide plate material. Is gradually increased from the upstream end toward the downstream end. According to the present embodiment, it is possible to regulate the diffusion of the fluid according to the shape of the target space or the target object without hindering the diffusion effect by the diffusion member.

  According to a tenth embodiment of the present invention, in the fluid derivation device according to any one of the first to ninth embodiments, the diffusion member is rotated by the fluid flowing through the flow path tube. According to the present embodiment, it is possible to rotate the diffusion member without providing a power source, and it is possible to expand the fluid ejected from the jet port to a predetermined range while suppressing a decrease in the flow velocity.

  In an eleventh embodiment of the present invention, in the fluid derivation device according to any one of the first to tenth embodiments, the diffusing member has a cylindrical portion body disposed inside the jet port, and the cylindrical portion A flow direction changing portion is formed on the inner peripheral surface of the main body. According to the present embodiment, the cylinder body can be rotated in the jet port, and the fluid ejected from the jet port can be diffused by the flow direction changing unit.

  According to a twelfth embodiment of the present invention, in the fluid derivation device according to any one of the first to tenth embodiments, the diffusing member has a cylindrical portion body disposed inside the jet port, and the cylindrical portion A flow direction changing portion is formed downstream of the main body. According to the present embodiment, the cylinder body can be rotated in the jet port, and the fluid ejected from the jet port can be diffused by the flow direction changing unit.

  In a thirteenth embodiment of the present invention, in the fluid derivation device according to the eleventh or twelfth embodiment, a through hole extending from the inner peripheral surface to the outer peripheral surface is formed in the cylindrical body. According to the present embodiment, the fluid in the tubular body can be guided from the through hole between the outer peripheral surface of the tubular body and the inner peripheral surface of the jet port, and the rotational friction of the tubular body can be reduced.

  In a fourteenth embodiment of the present invention, in the fluid derivation device according to the thirteenth embodiment, the outer peripheral opening on the outer peripheral surface of the through hole is made larger than the inner peripheral opening on the inner peripheral surface of the through hole. It is. According to the present embodiment, the fluid in the cylinder body can easily flow out of the through hole.

  A fifteenth embodiment of the present invention is the fluid derivation device according to the eleventh or twelfth embodiment, wherein the cylindrical portion main body has a hollow shaft portion, and the hollow shaft portion is formed on the inner peripheral side of the cylindrical portion main body. The flow direction changing portion is disposed on the outer peripheral side of the first fluid, and the fluid flowing in the cylindrical portion main body becomes a first fluid that flows through the hollow shaft portion and a second fluid that flows between the cylindrical portion main body and the hollow shaft portion. The flow direction of the fluid is not changed, and the flow direction of the second fluid is changed. According to the present embodiment, the first fluid maintains a flow along the virtual jet axis, the second fluid flows at an angle with respect to the virtual jet axis, and the first fluid is in the direction of the virtual jet axis. Is higher than the second fluid, and the second fluid is pulled by the first fluid, so that the reach distance of the fluid diffused by the second fluid can be extended.

  The sixteenth embodiment of the present invention is the fluid derivation device according to the fifteenth embodiment, wherein the cylinder body and the hollow shaft are connected by the flow direction changer. According to the present embodiment, by using the connecting member necessary for the arrangement of the hollow shaft portion as the flow direction changing portion, useless resistance can be eliminated and fluid resistance can be given to the flow direction changing portion.

  According to a seventeenth embodiment of the present invention, in the fluid derivation device according to the fifteenth embodiment, the outer diameter of the hollow shaft opening on the downstream side of the hollow shaft portion is the outer diameter of the hollow shaft opening on the upstream side of the hollow shaft portion. It is larger than the diameter. According to the present embodiment, the diffusion effect can be enhanced.

  According to an eighteenth embodiment of the present invention, in the fluid derivation device according to the third or fourth embodiment, air is formed at the negative pressure generated by the fluid ejected from the first nozzle by forming an air hole in the flow path tube. Air is sucked into the channel pipe from the hole. According to the present embodiment, the flow velocity of the fluid ejected from the jet port can be further increased by sucking air into the flow channel tube.

  A flue gas extinguishing method according to a nineteenth embodiment of the present invention uses the fluid outlet device according to any one of the first to eighteenth embodiments, and a compressed air source mounted on a fire engine on a flow path pipe, The fluid supplied from the water supply source is introduced, the fluid ejected from the spout is introduced into the fire compartment from the first opening in the fire compartment, and the smoke in the fire compartment from the second opening in the fire compartment In addition, the heated air is discharged. According to the present embodiment, it is possible to introduce a fluid expanded in a predetermined range to the first opening, and it is easy to discharge smoke and heated air from the second opening.

  The flue gas extinguishing method according to the twentieth embodiment of the present invention uses the fluid derivation device according to the fourth embodiment, and the gas is one of air, nitrogen, and carbon dioxide, and is a gas-liquid mixed phase flow. The fluid contains fire extinguishing water or a fire extinguishing agent. According to the present embodiment, smoke and heated air can be discharged and fire extinguishing can be performed.

  A portable flue gas fire extinguishing apparatus according to a twenty-first embodiment of the present invention uses the fluid lead-out device according to any of the first to eighteenth embodiments, and the flow path pipe is compressed by a fire engine. A fire hose for introducing a fluid supplied from an air source or a water supply source is connected, and a fluid ejected from a spout is introduced into the fire compartment through a first opening in the fire compartment, and a second in the fire compartment. The smoke and heated air in the fire compartment are discharged from the opening. According to the present embodiment, it is possible to introduce a fluid expanded in a predetermined range to the first opening, and it is easy to discharge smoke and heated air from the second opening.

  A portable flue gas fire extinguishing apparatus according to a twenty-second embodiment of the present invention uses the fluid lead-out apparatus according to the fourth embodiment, and the gas is any one of air, nitrogen, and carbon dioxide, and a gas-liquid mixed phase flow The above fluid contains fire extinguishing water or a fire extinguishing agent. According to the present embodiment, smoke and heated air can be discharged and fire extinguishing can be performed.

A fluid derivation device according to an embodiment of the present invention will be described below.
FIG. 1 is a cross-sectional view showing a configuration of a fluid derivation device according to this embodiment.
The fluid derivation device 1 according to the present embodiment includes a flow channel pipe 10 through which a fluid flows, a jet port 11 through which the fluid flowing through the flow channel tube 10 is ejected, a diffusion member 20 disposed in the jet port 11, and a downstream of the diffusion member 20. The flow guide member 30 is provided.

A first nozzle 41 is provided in the flow channel tube 10. The first nozzle 41 is disposed upstream of the diffusing member 20.
A second nozzle 42 is provided in the first nozzle 41.
The first nozzle 41 is formed at one end of the multiphase flow generator 51. One end of a liquid supply pipe 52 is connected to the other end side of the multiphase flow generation unit 51.
A liquid connection medium 53 is provided at the other end of the liquid supply pipe 52. The liquid supply pipe 52 is provided with a liquid valve 54 for controlling the supply of liquid.
The second nozzle 42 is formed at one end of the gas supply pipe 55. A gas connection medium 56 is provided at the other end of the gas supply pipe 55. The gas supply pipe 55 is provided with a gas valve 57 that controls the supply of gas.
A gas is ejected from the second nozzle 42, and a fluid in which a gas and a liquid are mixed to form a gas-liquid mixed phase flow is ejected from the first nozzle 41. In this way, by using a gas-liquid mixed phase flow, the diffusion effect can be enhanced and the reach distance can be extended.
The fluid ejected from the first nozzle 41 is guided to the diffusing member 20. By increasing the flow velocity of the fluid guided to the diffusing member 20 by the first nozzle 41, the diffusion effect can be enhanced and the reach distance can be extended.

An air hole 12 is formed in the channel tube 10. Air is sucked into the flow path pipe 10 from the air hole 12 with a negative pressure generated by the fluid ejected from the first nozzle 41. Thus, by sucking air into the flow channel tube 10, the average flow velocity of the fluid ejected from the jet port 11 can be further increased.
The diffusion member 20 is rotated in the jet port 11 by the fluid flowing through the flow channel tube 10, and diffuses the fluid ejected from the jet port 11. In this way, by rotating the diffusion member 20 without providing a power source, the fluid ejected from the jet port 11 can be expanded to a predetermined range while suppressing a decrease in the flow velocity.

When the fluid lead-out device 1 according to the present embodiment is used as the portable flue gas extinguishing device 2 (see FIG. 5), the liquid connected to the liquid connection medium 53 is the liquid supplied from the water supply source 61 mounted on the fire engine 60. A fire hose 62 that introduces gas supplied from a compressed air source 63 mounted on the fire engine 60 is connected to the gas connection medium 56.
The liquid supplied from the water supply source 61 is fire extinguishing water or a fire extinguishing agent, and the gas supplied from the compressed air source 63 is any of air, nitrogen, and carbon dioxide.

FIG. 2 is a perspective view of the diffusing member shown in FIG.
2A is a perspective view seen from the upstream side of the diffusing member, and FIG. 2B is a perspective view seen from the downstream side of the diffusing member.
The diffusing member 20 has a cylindrical body 21 that is disposed inside the jet port 11. A flow direction changing portion 22 that changes the flow direction of the fluid is formed on the inner peripheral surface 21 s of the cylindrical portion main body 21.
By rotating the cylinder part main body 21 in the jet port 11, the fluid ejected from the jet port 11 can be diffused by the rotating flow direction changing unit 22.
A through-hole 23 extending from the inner peripheral surface 21s to the outer peripheral surface 21t is formed in the cylindrical body 21. The outer peripheral opening in the outer peripheral surface 21t of the through hole 23 is made larger than the inner peripheral opening in the inner peripheral surface 21s of the through hole 23.
In this way, by forming the through hole 23 in the cylinder body 21, the fluid in the cylinder body 21 is allowed to pass between the through hole 23 and the outer peripheral surface 21 t of the cylinder body 21 and the inner peripheral surface of the jet port 11. As a result, the rotational friction of the cylindrical body 21 can be reduced. In addition, by making the outer peripheral opening of the through hole 23 larger than the inner peripheral opening of the through hole 23, the fluid in the cylinder body 21 can easily flow out of the through hole 23.

The tubular body 21 has a hollow shaft 24, and the tubular body 21 and the hollow shaft 24 are connected by a flow direction changing portion 22. Therefore, the flow direction changing portion 22 is arranged on the outer peripheral side of the hollow shaft portion 24 on the inner peripheral side of the cylindrical portion main body 21.
In the hollow shaft portion 24, the outer diameter of the downstream hollow shaft opening 24d is larger than the outer diameter of the upstream hollow shaft opening 24u.
Thus, by having the hollow shaft portion 24, the fluid flowing in the cylindrical portion main body 21 is the first fluid flowing in the hollow shaft portion 24 and the first fluid flowing between the cylindrical portion main body 21 and the hollow shaft portion 24. The flow direction of the first fluid is not changed, and the flow direction of the second fluid is changed by the flow direction changing unit 22. Therefore, the first fluid maintains the flow along the virtual jet axis X, the second fluid flows at an angle θ with respect to the virtual jet axis X, and the first fluid is the first in the virtual jet axis X direction. Since the flow rate is higher than that of the second fluid and the second fluid is pulled by the first fluid, the reach distance of the fluid diffused by the second fluid can be extended.
Further, by using the connecting member necessary for the arrangement of the hollow shaft portion 24 as the flow direction changing portion 22, useless resistance can be eliminated and fluid resistance can be given to the flow direction changing portion 22.
Further, the diffusion effect can be enhanced by making the outer diameter of the downstream hollow shaft opening 24d larger than the outer diameter of the upstream hollow shaft opening 24u.

FIG. 3 is an image diagram illustrating a jet flow by the diffusing member.
3A is an image diagram of the fluid ejected from the jet port, and FIG. 3B to FIG. 3F are image diagrams of changes in the high-density region in the virtual jet cross section in the time period T. FIG. In FIG. 2, the six flow direction changing units 22 are provided. However, in FIG. 3, the flow direction changing unit 22 is described as one.
When the extension line of the pipe axis of the flow channel pipe 10 is the virtual jet axis X, the flow velocity v is set to a virtual jet cross section H that is separated from the jet port 11 by a certain distance and orthogonal to the virtual jet axis X. A high density region J is formed by the jet.
The high-density region J is formed in the radial direction from the virtual jet axis X with respect to the virtual jet cross section H orthogonal to the virtual jet axis X, and the diffusing member 20 rotates, so that the virtual jet flow is generated by the flow direction changing unit 22. It turns in one direction around the axis X.

The points on the virtual cylindrical surface K in the high-density region J are A, B, C, and D with respect to the virtual cylindrical surface K having a radius r centered on the virtual jet axis X.
When the time when the high-density region J reaches the point A on the virtual jet section H is t = 0, the flow velocity at the point A becomes the flow velocity v of the jet at the virtual jet section H at t = 0, and points B, C, D The flow rate of is zero.
FIG. 3B shows that the high-density region J in the virtual jet cross section H at t = 0 is at the point A.
FIG. 3C shows that the high-density region J in the virtual jet section H at t = 1 / 4T is at the point B.
FIG. 3D shows that the high-density region J in the virtual jet cross section H at t = 2 / 4T is at the point C.
FIG. 3E shows that the high-density region J in the virtual jet section H at t = 3 / 4T is at the point D.
FIG. 3 (f) shows that the high-density region J in the virtual jet section H at t = 4 / 4T is at the point A.
At time t = T, point A reaches point A ′, point B reaches point B ′, point C reaches point C ′, point D reaches point D ′, and from point A to point A ′ Travel distance is v · T, travel distance from point B to point B 'is v · 3 / 4T, travel distance from point C to point C' is v · 2 / 4T, travel from point D to point D ' The moving distance is v · 1 / 4T.
For example, the wind speed on the line from the point A to the point A ′ has a flow velocity v at t = 0, and thereafter, the flow velocity of the accompanying flow at the point A gradually decreases until the next high-density region J comes. When the time period T is long, the accompanying flow may disappear once, so the time period T is set so that the accompanying flow does not disappear.

When a high-density region J continuous in the radial direction from the virtual jet axis X to the virtual cylindrical surface K in the virtual jet cross section H is assumed to be a single line, the trajectory of the virtual line is screw-shaped with the virtual jet axis X as the center. become. When the swirl speed of the jet is sufficiently high, the interval between the screw spirals is short, that is, the next high-density region J comes before the accompanying flow generated by the passage of the high-density region J is greatly attenuated. If it sees, flow velocity will become almost constant.
In this way, by turning the high-density region J, the reach distance of the fluid expanded to a predetermined range can be extended.

4 is a plan view and a side sectional view of the flow guide member shown in FIG.
4A is an upstream plan view of the flow guide member, FIG. 4B is a side sectional view of the diffusion member, and FIG. 4C is a downstream plan view of the flow guide member.
In the flow guide member 30, the upstream flow guide member opening 31u has a circular shape, the downstream flow guide member opening 31d has a rectangular shape, and the upstream flow guide member opening 31u and the downstream flow guide member opening 31d. The cross-sectional shape is different. Further, the opening area of the downstream flow guide member opening 31d is larger than that of the upstream flow guide member opening 31u.
Between the upstream flow guide member opening 31u and the downstream flow guide member opening 31d, a flow guide plate 32 is formed.
The flow guide member 30 connects the upstream flow guide member opening 31 u to the jet port 11, and restricts diffusion of the fluid ejected from the jet port 11 by the flow guide plate 32.
In this way, by restricting the diffusion of the fluid by the flow guide member 30, it is possible to match the shape of the target space or the target object, and it is possible to allow the fluid to reach the entire target space or the target object without waste.
In addition, by increasing the opening area of the downstream flow guide member opening portion 31d from the upstream flow guide member opening portion 31u, the shape of the target space or the target object is prevented without hindering the diffusion effect of the diffusion member 20. In addition, the diffusion of the fluid can be regulated.
Further, when the shape of the target space or the target object is a rectangular shape, it can be matched with the shape of the target space or the target object, and the fluid can reach the entire target space or the target object without waste.

FIG. 5 is a perspective view of a portable flue gas fire extinguishing apparatus using the fluid outlet apparatus according to the present embodiment.
The portable flue gas fire extinguishing device 2 according to the present embodiment has a fluid outlet device 1 attached to a water cannon 3.
The water cannon 3 includes a leg portion 65 for allowing the water cannon 3 to stand on its own, and a water cannon-side liquid connection medium 66 for supplying liquid to the liquid supply pipe 52.
The fluid derivation device 1 forms at one end a flow channel pipe 10 through which a fluid flows, a jet port 11 through which the fluid flowing through the flow channel tube 10 is ejected, a diffusion member 20 disposed in the jet port 11, and a first nozzle 41. A multiphase flow generation unit 51, a liquid supply pipe 52 connected to the other end of the multiphase flow generation unit 51, a liquid connection medium 53 provided at the other end of the liquid supply pipe 52, and a liquid valve for controlling the supply of liquid 54, a gas supply pipe 55 that forms the second nozzle 42 at one end, a gas connection medium 56 provided at the other end of the gas supply pipe 55, and a gas valve 57 that controls the supply of gas, An air hole 12 is formed in 10. In addition, it is preferable to provide the flow guide member 30 shown in FIG.
As shown in FIG. 1, a fire hose 62 for introducing liquid supplied from a water supply source 61 mounted on the fire engine 60 is connected to the liquid connection medium 53 via a water gun-side liquid connection medium 66. The gas connection medium 56 is connected to a fire hose 64 for introducing gas supplied from a compressed air source 63 mounted on the fire truck 60.

FIG. 6 is an explanatory diagram illustrating a flue gas extinguishing method using the fluid derivation device according to this embodiment.
The fluid outlet device 1 is installed at an appropriate position near the first opening 71 of the fire compartment 70.
The air compressor (compressed air source) 63 of the CAFS vehicle mounted on the fire engine 60 and the fluid outlet device 1 are connected by a fire hose 64, and the water supply source 61 and the fluid outlet device 1 of the fire engine 60 are connected to the fire hose. Connect at 62.
A mixed phase flow of air and water is forcibly sent from the first opening 71 of the fire section 70 into the fire section 70, and smoke and heated air are discharged from the second opening 72 of the fire section 70. The first opening 71 is usually an entrance of a building section such as a living room or an office room, and has a rectangular shape with a predetermined aspect ratio (usually an aspect ratio of 2: 1). As the second opening 72, a window of a building section is often used, but an opening portion of another part may be used as the second opening 72. Alternatively, a part of the wall of the building section may be destroyed to form the second opening 72.

The compressor mounted on the CAFS vehicle has an air flow rate of about 3000 L / min to 4500 L / min and an air supply pressure of about 0.6 MPa to 0.9 MPa. If such a compressor is used, several hundred liters of water per minute can be divided into fine water droplets that can follow the airflow. By introducing such a large amount of fine water droplets into the fire section 70 by a strong jet, a high fire extinguishing effect is brought about. Thereby, it is possible for the fire brigade member to suppress the fire from the outside without entering the dangerous fire section 70, and the fire brigade member can extinguish more safely.
As described above, the flue gas extinguishing method according to the present embodiment uses the fluid derivation device 1 and introduces the fluid supplied from the compressed air source 63 and the water supply source 61 mounted on the fire engine 60 to the flow pipe 10. Then, the fluid ejected from the jet port 11 is introduced into the fire compartment 70 from the first opening 71 in the fire compartment 70, and smoke and heated air in the fire compartment 70 from the second opening 72 in the fire compartment 70. Is discharged. And the fluid extended to the predetermined range can be introduce | transduced with respect to the 1st opening part 71, and it is easy to discharge smoke and heated air from the 2nd opening part 72. FIG.
Then, the gas is any one of air, nitrogen, and carbon dioxide, and the fluid in a gas-liquid mixed phase flow contains fire extinguishing water or a fire extinguishing agent, so that smoke and heated air can be discharged and fire extinguishing can be performed.

FIG. 7 is a photograph showing the configuration of a fluid derivation device according to another embodiment of the present invention. In addition, the same code | symbol is attached | subjected to the same function member, and only a different point from the said Example is demonstrated below.
In the present embodiment, the jet port 11 in which the diffusion member 20 is disposed is attached to the end of the flow channel tube 10. As in this embodiment, the jet port 11 can be attached and detached as a separate member from the flow channel tube 10.
In this embodiment, the flow guide member 30 is composed of at least a pair of flow guide plates 33 facing each other,
A pair of flow guide plate members 33 are connected to the jet port 11. Therefore, the pair of flow guide plates 33 can match the shape of the target space or the target object, and the fluid can reach the entire target space or the target object without waste.
The flow guide plate 33 has the downstream end 33d enlarged from the upstream end 33u, and the width of the flow guide plate 33 is gradually increased from the upstream end 33u toward the downstream end 33d. Further, the pair of flow guide plate members 33 has a gap between the opposed downstream end portions 33d wider than the gap between the opposed upstream end portions 33u. Accordingly, it is possible to regulate the diffusion of the fluid in accordance with the target space or the shape of the target object without hindering the diffusion effect by the diffusion member 20.

FIG. 8 is a photograph showing an operation confirmation experiment by the fluid derivation device according to the embodiment shown in FIG.
As shown in FIG. 8, the pair of flow guide plates 33 can match the shape of the target space or the target object.
Also, in FIG. 8, it can be seen that the high density region J described in FIG. 3 is formed.

FIG. 9 is a perspective view of a diffusion member according to still another embodiment of the present invention.
FIG. 9A is a perspective view seen from the upstream side of the diffusing member, and FIG. 9B is a perspective view seen from the downstream side of the diffusing member. In addition, the same code | symbol is attached | subjected to the same function member, and only a different point from the said Example is demonstrated below.
The diffusion member 20 according to the present embodiment further forms a flow direction changing portion 25 downstream from the cylindrical portion main body 21.
In the diffusing member 20 according to the present embodiment, the hollow shaft portion 24 extends downstream to form the truncated cone-shaped protruding portion 26. A downstream hollow shaft opening 24d is formed at the center of the frustoconical protrusion 26, and a plurality of flow direction changing portions 25 are formed around the downstream hollow shaft opening 24d.
Similar to the flow direction changing unit 22, the flow direction changing unit 25 is configured with respect to the virtual jet axis X so that the fluid flowing through the flow direction changing unit 25 has a flow having an angle θ with respect to the virtual jet axis X. A through hole 23 having an angle θ is formed.
Thus, the cylinder main body 21 can rotate in the jet port 11, and the fluid ejected from the jet port 11 can be diffused by the flow direction changing unit 22 and the flow direction changing unit 25.
In this embodiment, the flow direction changing unit 25 is provided in addition to the flow direction changing unit 22, but the flow direction changing unit 25 may be provided instead of the flow direction changing unit 22.

  The fluid derivation device according to the present invention is particularly suitable for a portable flue gas extinguishing device that forcibly discharges and extinguishes smoke and heated air generated in a fire section such as a building outside the fire section. It can also be applied to.

DESCRIPTION OF SYMBOLS 1 Fluid derivation | leading-out device 2 Portable smoke-extinguishing device 3 Water discharge gun 10 Channel pipe 11 Jet port 12 Air hole 20 Diffusion member 21 Cylindrical body 21s Inner peripheral surface 21t Outer peripheral surface 22 Flow direction change part 23 Through-hole 24 Hollow shaft part 24d Downstream hollow shaft opening 24u Upstream hollow shaft opening 25 Flow direction changing portion 26 Frustum-shaped protrusion 30 Current guide member 31d Downstream current guide member opening 31u Upstream current guide member opening 32 Current guide plate material 33 Flow guide plate material 41 First nozzle 42 Second nozzle 51 Multiphase flow generating section 52 Liquid supply pipe 53 Liquid connection medium 54 Liquid valve 55 Gas supply pipe 56 Gas connection medium 57 Gas valve 60 Fire engine 61 Water supply source 62 Fire hose 63 Compression Air source (air compressor)
64 Fire hose 65 Leg 70 Fire compartment 71 1st opening 72 2nd opening A, B, C, D Point A ', B', C ', D' Point H Virtual jet cross section J High density area K Virtual cylinder Surface T Time period X Virtual jet axis

Claims (22)

A channel tube through which fluid flows;
A jet outlet for ejecting the fluid flowing through the flow path pipe;
A diffusion member disposed at the jet outlet,
The diffusion member has a flow direction changing portion that changes the flow direction of the fluid,
The fluid derivation device characterized by diffusing the fluid ejected from the jet port by the rotation of the diffusion member. In the fluid, a high-density region is formed by the flow direction changing unit,
When an extension line of the pipe axis of the flow path pipe is a virtual jet axis,
The high-density region is formed in a radial direction from the virtual jet axis with respect to a virtual jet cross section orthogonal to the virtual jet axis,
2. The fluid derivation device according to claim 1, wherein the high-density region swirls in one direction around the virtual jet axis by the rotation of the diffusion member. A first nozzle is provided in the flow channel pipe,
Disposing the first nozzle upstream of the diffusing member;
The fluid derivation device according to claim 1, wherein the fluid ejected from the first nozzle is guided to the diffusion member. A second nozzle is provided in the first nozzle;
A gas is ejected from the second nozzle,
4. The fluid derivation device according to claim 3, wherein the fluid is ejected from the first nozzle into a gas-liquid mixed phase flow by mixing the gas and the liquid. 5. The fluid derivation device according to claim 1, further comprising a flow guide member that regulates diffusion of the fluid ejected from the jet port downstream of the diffusion member. 6. The upstream side diversion member opening of the diversion member and the downstream diversion member opening of the diversion member are made different in cross-sectional shape,
The fluid outlet device according to claim 5, wherein an opening area of the downstream flow guide member opening is larger than that of the upstream flow guide member opening. Connecting the upstream flow guide member opening to the jet port;
The fluid outlet device according to claim 6, wherein the downstream side flow guide member opening has a rectangular shape. The flow guide member is composed of at least a pair of flow guide plates facing each other,
The fluid lead-out device according to claim 5, wherein a pair of the flow guide plate members are connected to the jet port. From the upstream end of the flow guide plate material, expand the downstream end of the flow guide plate material,
9. The fluid derivation device according to claim 8, wherein the width of the flow guide plate is gradually increased from the upstream end toward the downstream end. The fluid derivation device according to claim 1, wherein the diffusion member is rotated by the fluid flowing through the flow channel pipe. The diffusing member has a cylindrical body disposed inside the jet port,
The fluid derivation device according to any one of claims 1 to 10, wherein the flow direction changing portion is formed on an inner peripheral surface of the cylindrical portion main body. The diffusing member has a cylindrical body disposed inside the jet port,
The fluid derivation device according to any one of claims 1 to 10, wherein the flow direction changing portion is formed downstream of the cylindrical portion main body. The fluid derivation device according to claim 11 or 12, wherein a through hole extending from an inner peripheral surface to an outer peripheral surface is formed in the cylindrical body. The fluid outlet device according to claim 13, wherein an outer peripheral opening in the outer peripheral surface of the through hole is made larger than an inner peripheral opening in the inner peripheral surface of the through hole. The tube body has a hollow shaft portion,
The flow direction changing part is arranged on the outer peripheral side of the hollow shaft part on the inner peripheral side of the cylindrical part body,
The fluid flowing in the cylindrical body is
A first fluid that flows through the hollow shaft portion, and a second fluid that flows between the cylindrical body and the hollow shaft portion,
The flow direction of the first fluid is not changed,
13. The fluid derivation device according to claim 11 or 12, wherein a flow direction of the second fluid is changed. The fluid derivation device according to claim 15, wherein the cylindrical body and the hollow shaft portion are connected by the flow direction changing portion. The fluid derivation device according to claim 15, wherein an outer diameter of a downstream hollow shaft opening of the hollow shaft portion is larger than an outer diameter of an upstream hollow shaft opening of the hollow shaft portion. Forming air holes in the channel tube;
5. The fluid lead-out device according to claim 3, wherein air is sucked into the channel pipe from the air hole with a negative pressure generated by the fluid ejected from the first nozzle. A flue gas extinguishing method using the fluid lead-out device according to any one of claims 1 to 18,
Introducing the fluid supplied from a compressed air source and a water supply source mounted on the fire engine into the flow path pipe,
Introducing the fluid ejected from the jet port into the fire compartment from a first opening in the fire compartment, and discharging smoke and heated air in the fire compartment from the second opening in the fire compartment; Exhaust smoke extinguishing method characterized by A flue gas extinguishing method using the fluid lead-out device according to claim 4,
The gas is any one of air, nitrogen, and carbon dioxide,
The flue gas fire extinguishing method, wherein the fluid in the gas-liquid mixed phase flow contains fire extinguishing water or a fire extinguishing agent. A portable flue gas fire extinguishing device using the fluid lead-out device according to any one of claims 1 to 18,
A fire hose for introducing the fluid supplied from a compressed air source or a water supply source mounted on the fire truck is connected to the flow path pipe,
Introducing the fluid ejected from the jet port into the fire compartment from a first opening in the fire compartment, and discharging smoke and heated air in the fire compartment from the second opening in the fire compartment; A portable smoke-extinguishing device characterized by A portable flue gas fire extinguishing device using the fluid lead-out device according to claim 4,
The gas is any one of air, nitrogen, and carbon dioxide,
The portable flue gas fire extinguishing apparatus, wherein the fluid in the gas-liquid mixed phase flow contains fire extinguishing water or a fire extinguishing agent.