JP2004050128A - Method and apparatus for generating mist, fire extinguishing system applying these, fire extinguishing sprinkler, agricultural use chemical dispenser, agricultural use watering system, burner, missile evesion apparatus, and cooling apparatus for machine tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an extinguishing system which spatters liquid for extinguishing fire to long distance without damaging to a building or the like in extinguishing fire. <P>SOLUTION: An apparatus 1 for generating mist has a liquid chamber 2, a gaseous chamber 3, a mist chamber 4, an acceleration chamber 5 and a flow rate regulation valve 6. A plurality of micro pores 7 are formed in a partition between the liquid chamber 2 and the mist chamber 4, and a plurality of micro pores 8 are formed in a partition between the mist chamber 4 and the acceleration chamber 5. Furthermore, a narrow gap 9 is formed between the gaseous chamber 3 and the acceleration chamber 5. Here, the relationship between the velocity vector, Vliquid of liquid droplets introduced into the mist chamber 4 and the velocity vector Vgus of air current is Vgus ≥ Vliquid. Inside the mist chamber 4, air current strongly collides with the liquid droplets, and the liquid droplets are divided into minute water particles, then mist is generated. At this time, gaseous pressure is about 8 bars, therefore, neither house nor property is damaged when it is used for extinguishing fire. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a mist generating method, a mist generating device, and a fire extinguishing system, a fire extinguishing sprinkler, an agricultural chemical spraying device, an agricultural irrigation system, a burner, and a missile avoiding device to which the mist generating method and the mist generating device are applied.
[0002]
[Prior art]
Conventionally, a fire extinguishing system called an impulse fire extinguishing system is known. This impulse fire extinguishing system extinguishes fire by injecting fine particles of water or a fire extinguishing agent into a burning substance at a high speed. The fire extinguisher used in this impulse fire extinguishing system is portable and can quickly arrive at the fire site.Although it is a small amount of fire extinguishing liquid, by spraying the fire extinguishing liquid with high-pressure air, fine water droplets fired are There is a feature that it can penetrate deep into a fire source and extinguish a fire instantly (for example, JP-A-2000-93535).
[0003]
[Problems to be solved by the invention]
However, since the impulse fire gun uses high-pressure compressed air, 150 kgf / cm ² ~ 300kg / cm ² There is a problem that a high-pressure cylinder is required. Further, when extinguishing a fire, water and a fire extinguishing agent impact on the target object, so that there is a problem that a house or the like is damaged. On the other hand, as one method of avoiding such damage, measures to reduce the air pressure can be considered. However, when the air pressure is reduced, there is also a problem that the fire extinguishing operation is hindered because the flight distance becomes short.
[0004]
Therefore, the present invention aims to provide a fire extinguishing system capable of causing a fire extinguishing liquid to fly far without damaging a building or the like during fire extinguishing. A first object is to provide a novel mist generation method applicable to various fields.
[0005]
A second object of the present invention is to provide a novel mist generation device applicable to various fields.
[0006]
A third object of the present invention is to provide a fire extinguishing system that can fly a fire extinguishing liquid to a distant place without damaging a building or the like during fire extinguishing.
[0007]
A fourth object of the present invention is to provide a fire extinguishing sprinkler having a high fire extinguishing efficiency.
[0008]
In addition, a fifth object of the present invention is to provide an agricultural chemical spraying device having a high chemical spraying efficiency.
[0009]
In addition, a sixth object of the present invention is to provide an agricultural irrigation system that can save agricultural water.
[0010]
In addition, a sixth object of the present invention is to provide a burner having high combustion efficiency.
[0011]
In addition, a seventh object of the present invention is to provide a missile avoidance device for avoiding an infrared tracking missile.
[0012]
In addition, an eighth object of the present invention is to enhance a cooling effect in a machine tool.
[0013]
[Means for Solving the Problems]
In order to achieve the first object, the mist generation method of the present invention is directed to a method of dividing a liquid into droplets by a nozzle having a large number of pores and discharging the divided liquid into a predetermined space. By ejecting a stream from a direction intersecting or opposing the flight direction of the droplet, the gas stream collides with the droplet to divide the droplet and generate a mist composed of fine liquid particles. It is characterized.
[0014]
According to the mist generation method of the present invention, fine mist can be easily generated. This fine mist, when used to extinguish a fire, wraps the flame tightly. Therefore, the air blocking effect is high, and it is useful for quick fire suppression. In addition, since it is a fine mist, it is not necessary to use a high-pressure gas to blow it away. Therefore, there is no damage to buildings and equipment during fire extinguishing. Further, by spraying a spraying agent such as a pesticide or a plant active agent by the method of the present invention, it is possible to spray a small amount of the drug on a wide range of crops. Thereby, environmental destruction can be prevented by reducing the use amount of the medicine, and adverse effects on the human body can be suppressed. Furthermore, if the flammable liquid is converted into mist by the method of the present invention, a burner with high combustion efficiency can be realized. In addition, by spraying the coolant liquid mist generated by the method of the present invention behind the jet fighter, the combustion gas injected into the air is cooled, and a camouflage effect is exerted on the infrared tracking type missile.
[0015]
Here, in the mist generation method of the present invention, when the flow velocity and the flight direction of the droplet are set as a vector Vliquid and the flow velocity and the flight direction of the gas are set as Vgus, the magnitude of Vgus may be made larger than Vliquid. desirable.
[0016]
By doing so, it is possible to increase the kinetic energy of the gas, increase the ability to separate droplets generated by collision, and generate finer mist.
[0017]
Further, in the mist generation method of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid, and the flow velocity and the flying direction of the gas are set as Vgus, the direction of Vgus is set to Vliquid as much as possible in the system. The direction should be opposite from the front.
[0018]
By doing so, the kinetic energy of the gas can be more efficiently hit against the droplet, and the effect of making the droplet finer increases.
[0019]
In the mist generation method of the present invention, when the flow velocity and the flying direction of the droplet are vector Vliquid, and the flow velocity and the flying direction of the gas are Vgus, the direction of Vgus is set to Vliquid as much as possible in the system. The tracking direction can also be used.
[0020]
In such a case, the kinetic energy of the gas that attempts to break the droplets is relatively small. Therefore, it is preferable to adopt this method when it is not necessary to make the droplets too small.
[0021]
Further, a mist generation device of the present invention made to achieve the second object has a nozzle having a large number of fine holes for spraying a liquid, a chamber in which a liquid is sprayed inside by the nozzle, On the other hand, a gas inlet for introducing a gas flow from a direction intersecting or opposing the flight direction of the droplet is provided.
[0022]
According to the mist generation device of the present invention, by spraying the liquid onto the chamber via the nozzle, a large number of droplets are generated in the chamber. Then, when a gas is introduced into the chamber from the gas inlet, the gas flow collides with or intersects with the flying direction of the droplet, and breaks the droplet to generate a fine mist.
[0023]
In the mist generation device of the present invention, similarly to the mist generation method, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid and the flow velocity and the flying direction of the gas are set as Vgus, the magnitude of Vgus is set to be smaller than Vliquid. Also, by increasing the size, the effect of making the droplets finer is enhanced.
[0024]
Further, in the mist generating device of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid and the flow velocity and the flying direction of the gas are set as Vgus, the direction of Vgus is set to Vliquid as much as possible in the system. By arranging the nozzle and the gas inlet so as to face each other from the front, the effect of making the droplets finer can also be enhanced.
[0025]
Further, in the mist generating device of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid and the flow velocity and the flying direction of the gas are set as Vgus, the direction of Vgus is set to Vliquid as much as possible in the system. When the nozzle and the gas introduction port are arranged so as to follow in the direction of tracking, excessive miniaturization can be prevented.
[0026]
Further, a fire extinguishing system according to the present invention made to achieve the third object has a liquid tank containing a fire extinguishing liquid, a pressure cylinder containing compressed air, and a fire extinguishing fire discharging the fire extinguishing liquid. A gun, a liquid supply path for supplying a fire-extinguishing liquid from the liquid tank to the fire extinguisher, a gas supply path for supplying gas from the pressure cylinder to the fire extinguishing gun, provided in the fire extinguishing gun, The liquid supplied from the liquid supply path is introduced in the form of liquid droplets, and the compressed air supplied from the gas supply path is caused to collide with the liquid in a direction intersecting or facing the flight direction of the liquid droplets. A mist chamber that divides droplets to generate a mist composed of fine liquid particles, and a mist provided in the fire extinguisher, wherein the mist generated in the mist chamber is compressed by the pressure cylinder. Characterized in that it comprises a acceleration section for discharging put care.
[0027]
According to the fire extinguishing system of the present invention, the fire extinguishing liquid (water or fire extinguishing agent) in the liquid tank is supplied from the liquid tank to the fire extinguishing gun through the liquid supply path, and the compressed air in the pressure cylinder is converted into gas. The liquid is supplied to the fire extinguisher via the supply path, and the liquid is introduced into the mist chamber in the form of droplets, and the compressed air is crossed or opposed to the flight direction of the droplets in the mist chamber. Introduce so as to collide from the direction to be performed. As a result, in the mist chamber, the air stream collides with the droplets, and the droplets are divided to generate mist composed of fine liquid particles. In the pressurizing section, the mist generated in this way is put on compressed air supplied from a pressure cylinder and discharged from a fire extinguisher. According to the fire extinguishing system of the present invention, the fire extinguishing liquid can be blown off as fine mist, so that low-pressure compressed air is sufficient. Due to the fine mist, in the fire extinguishing effect, the flame is firmly wrapped, the supply of oxygen is cut off, and heat is removed by the heat of vaporization, resulting in rapid fire suppression. Further, since the gas for transportation is not at a high pressure, an effect of not damaging a building where fire has occurred or internal equipment, etc. is also exhibited. Furthermore, unlike the impulse-type fire extinguishing system, this air is sent continuously to the fire site unlike the impulse fire extinguishing system, so it also has the effect of supplying oxygen to those who are left behind at the fire site I do. Note that this oxygen does not act in a direction that promotes a fire. This is because the flame is covered by the mist-like fire extinguishing liquid. Air, as a source of oxygen to humans, will spread to the surroundings, not to the flames covered by the mist, and will help save lives. In addition, since the amount of water used in the fire extinguishing activity can be reduced, it is easy to return the building to the current state after the fire extinguishing.
[0028]
In the fire extinguishing system of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid and the flow velocity and the flying direction of the gas are set as Vgus, the magnitude of Vgus is made larger than Vliquid, The extinguishing of the fire extinguishing liquid can be further enhanced.
[0029]
Further, in the fire extinguishing system of the present invention, when the flow velocity and the flying direction of the droplet are defined as a vector Vliquid, and the flow velocity and the flying direction of the gas are defined as Vgus, the direction of Vgus is set to Vliquid as much as possible in the system. The effect of making the fire extinguishing liquid finer can also be enhanced by setting the direction opposite to the front.
[0030]
Further, a more specific fire extinguishing system of the present invention, which has also been made to achieve the third object, comprises a liquid tank containing a fire extinguishing liquid, a pressure cylinder containing compressed air, and the fire extinguishing fire. A fire extinguisher that discharges liquid, a liquid hose that supplies the fire extinguishing liquid from the liquid tank to the fire extinguishing gun, a gas hose that supplies the compressed air from the pressure cylinder to the fire extinguishing gun, A liquid inlet provided in the gun and provided at a connection portion with the liquid hose; a gas inlet provided in the fire extinguisher and connected to the gas hose; and a liquid inlet provided in the fire extinguisher and provided in the fire gun. A liquid chamber that communicates with a gas chamber provided in the fire extinguisher and that communicates with the gas inlet; and water in the liquid chamber drops through many pores. The droplet is divided by causing the compressed air in the gas chamber, which is provided in the fire rifle and the mist chamber to be introduced into the fire gun, to collide with the direction in which the droplet flies in a direction that intersects or opposes the flight direction of the droplet. The compressed air is introduced from the gas chamber to the mist chamber so as to generate a mist composed of fine liquid particles, and at least one or more gas inlets are provided in the fire extinguisher, and A mist accelerating unit that sucks out mist generated in the mist chamber and accelerates the mist by compressed air.
[0031]
According to the more specific fire extinguishing system of the present invention, the fire extinguishing liquid in the liquid tank is supplied to the fire extinguisher via the liquid hose, and the compressed air in the pressure cylinder is supplied through the gas hose together with the fire extinguishing gun. Supply to fire extinguisher. Then, the liquid is introduced into the mist chamber via the liquid inlet and the liquid chamber in the form of droplets. On the other hand, compressed air is introduced into the mist chamber via the gas inlet, the gas chamber, and the gas inlet. Then, the airflow formed in the mist chamber by the compressed air collides from a direction intersecting or opposing the flight direction of the droplet, and divides the droplet to generate a mist composed of fine liquid particles. The mist is accelerated by the compressed air in the mist accelerating unit, and is discharged far away. Despite the high digestive power provided by the fine mist, at the scene of a fire, damage to buildings and equipment can be reduced, and oxygen can be supplied to people who have escaped late.
[0032]
In this more specific fire extinguishing system of the present invention, a part of the compressed air supplied through the gas inlet is branched and supplied to the mist accelerating unit, so that the compressed air for discharge and The compressed air for mist generation can be shared.
[0033]
Further, in a more specific fire extinguishing system of the present invention, when the compressed air supplied to the mist accelerating unit is provided with a gas accelerating unit that accelerates by using a throttle upstream of the mist accelerating unit, the compressed air Pressure can be reduced even more.
[0034]
Further, in a more specific fire extinguishing system of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid, and the flow velocity and the flying direction of the gas are set as Vgus, the magnitude of Vgus is made larger than Vliquid. If this is the case, the effect of obtaining a finer mist is enhanced.
[0035]
Further, in a more specific fire extinguishing system of the present invention, when the flow velocity and the flying direction of the droplet are set as a vector Vliquid, and the flow velocity and the flying direction of the gas are set as Vgus, the direction of Vgus is set as much as possible in the system. It is also possible to make the mist finer by setting the direction opposite to Vliquid from the front.
[0036]
Further, a fire extinguisher sprinkler of the present invention made to achieve the fourth object has a liquid supply source for supplying a fire extinguishing liquid, a gas supply source for supplying a gas, and a liquid supply source for supplying a gas. Liquid into liquid droplets, and the liquid supplied from the gas supply source collides from a direction opposite to the flight direction of the liquid droplets to divide the liquid droplets and separate the fine liquid particles from the liquid droplets. A mist generating unit that generates a mist.
[0037]
According to the fire extinguisher sprinkler of the present invention, it is possible to create a state in which the fine mist falls down from the ceiling, and it is possible to efficiently extinguish the fire by surrounding the flame. In addition, since the amount of water used in the fire extinguishing activity can be reduced, it is easy to return the building to the current state after the fire extinguishing.
[0038]
Further, the agricultural chemical spraying apparatus of the present invention made to achieve the fifth object, a liquid supply source for supplying a spray liquid to be sprayed on crops, a gas supply source for supplying gas, The spray liquid supplied from the liquid supply source is introduced in the form of droplets, and the droplets are divided by colliding the gas supplied from the gas supply source from a direction opposite to the flight direction of the droplets. A mist generating unit that generates a mist composed of fine liquid particles, and a spray unit that sprays the mist generated by the mist generating unit.
[0039]
According to the agricultural chemical spraying apparatus of the present invention, since the spray liquid to be sprayed on the crop can be sprayed on the crop in the form of fine mist, the effect of spraying can be enhanced, and the amount of the sprayed chemical can be reduced. Can be reduced. In the case of pesticides, reducing the amount of pesticides used can reduce the amount of residues in crops, thereby protecting the health of general consumers and contributing to the increase in yield while protecting the health of farmers. it can.
[0040]
Further, the agricultural irrigation system of the present invention made to achieve the sixth object has a liquid supply source for supplying water, a gas supply source for supplying gas, and water supplied from the liquid supply source. Mist made of fine liquid particles by breaking the droplets by introducing the gas supplied from the gas supply source from the gas supply source in a direction opposite to the flight direction of the droplets. And a spraying unit for spraying the mist generated by the mist generating unit.
[0041]
ADVANTAGE OF THE INVENTION According to the agricultural watering system of this invention, watering can be performed without damaging a crop by spraying water as a mist. In addition, there is also an advantage that a mist is formed to exhibit a cooling effect in a greenhouse or the like.
[0042]
According to another aspect of the present invention, there is provided a burner including a liquid supply source for supplying a flammable liquid, a gas supply source for supplying a gas, and a flammable liquid supplied from the liquid supply source. Liquid particles are introduced in the form of liquid droplets, and the liquid supplied from the gas supply source collides from a direction opposite to the flight direction of the liquid droplets, thereby dividing the liquid droplets into fine liquid particles. And a mist discharging unit that discharges the mist generated by the mist generating unit.
[0043]
According to the burner of the present invention, the combustible liquid (heavy oil, kerosene, or the like) is mist-shaped, so that the combustion efficiency can be increased. As a result of increasing the combustion efficiency, it is possible to reduce the amount of fuel used. Therefore, if this burner is installed in a large-scale incinerator operated by a local government or the like, the waste disposal cost can be reduced. In addition, crude oil can be used as fuel, and fuel cost can be reduced.
[0044]
According to another aspect of the present invention, there is provided a missile avoidance device for supplying a coolant liquid, a gas supply source for supplying a gas, and a coolant supplied from the liquid supply source. The liquid is introduced in the form of liquid droplets, and the liquid supplied from the gas supply source collides from a direction opposite to the flight direction of the liquid droplets, thereby dividing the liquid droplets to form fine liquid particles. It has a mist generating section for generating mist, and mist spraying means for spraying the mist generated by the mist generating section toward the rear of the body, and is mounted on a jet machine.
[0045]
According to the missile avoiding device of the present invention, a camouflage effect is exerted on an infrared tracking type missile flying toward a heat source by atomizing a coolant liquid such as water into a mist and spraying it toward the rear of the aircraft.
[0046]
In order to achieve the eighth object, a cooling device for a machine tool according to the present invention includes a liquid supply source for supplying a coolant liquid, a gas supply source for supplying a gas, and a liquid supply source for supplying the gas. The liquid coolant is introduced in the form of liquid droplets, and the liquid supplied from the gas supply source collides from a direction opposite to the flight direction of the liquid droplets, thereby dividing the liquid droplets to form fine liquid particles. And a mist spraying means for spraying the mist generated by the mist toward the processing site.
[0047]
According to the cooling device for a machine tool of the present invention, it is possible to cool a work, a processing tool, and the like with the mist-formed coolant liquid. Since the amount of the coolant used at this time can be suppressed, an effect that the cleaning of the machine tool or the like is facilitated is also exerted.
[0048]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a mist generation method and a mist generation device as an embodiment of the present invention will be described. FIG. 1 shows a mist generating device according to a first embodiment. As shown in the drawing, the mist generation device 1 includes a liquid chamber 2, a gas chamber 3, a mist chamber 4, an acceleration chamber 5, and a flow rate control valve 6, and a partition between the liquid chamber 2 and the mist chamber 4. Has a large number of pores 7 formed therein, a large number of pores 8 formed in a partition wall between the mist chamber 4 and the acceleration chamber 5, and a narrow gap between the gas chamber 3 and the acceleration chamber 5. 9 are formed.
[0049]
The liquid in the liquid chamber 2 is introduced into the mist chamber 4 at a speed and direction indicated by a vector Vliquid through a pore 7 formed in a partition wall between the liquid chamber 2 and the mist chamber 4, and the liquid Become. On the other hand, the gas in the gas chamber 3 is introduced into the mist chamber 4 via the gap 9 at the speed and direction indicated by the vector Vgus. Then, this air current collides with the droplet from a direction intersecting the flying direction of the droplet, and divides the droplet to form a mist composed of fine water particles. Further, the gas in the gas chamber 3 is introduced into the acceleration chamber 5 through a gap between the flow rate adjusting valve 6 and the acceleration chamber 5. At this time, the gas is accelerated. As the gas passes through the acceleration chamber 5 at a high speed in this manner, the mist generated in the mist chamber 4 is sucked into the acceleration chamber 5 through the pores 8 in the partition wall between the mist chamber 4 and the acceleration chamber 5. Then, it is discharged from the discharge port 10 on the gas.
[0050]
Here, in this embodiment, Vgus is larger than Vliquid, as can be seen from the length of the arrow shown. As a result, in the mist chamber 4, the airflow strongly collides with the droplet, and the droplet can be divided into extremely fine water particles. The internal pressure of the liquid chamber 2 is about 8 bar. Further, the internal pressure of the gas chamber 3 is also about 8 bar. And the internal pressure in the mist chamber 4 becomes about 6 bar. Then, the internal pressure of the acceleration chamber 5 becomes less than 5 bar.
[0051]
Next, a second embodiment will be described. FIG. 2 shows a mist generating device according to a second embodiment. As shown in the figure, the mist generating device 11 includes a liquid chamber 12, a gas chamber 13, and a mist generating space 14, and a large number of pores 15 are formed in a front end wall of the liquid chamber 12, and gas mist is generated. A large number of pores 16 are also formed in the rear end wall of the T-shaped head of the chamber 13. Here, as shown in the figure, in the mist generating device 11 of this embodiment, the air flow collides with the liquid droplets from the front in the mist generating space 14.
[0052]
Further, when comparing the velocity vector Vliquid of the droplet and the velocity vector Vgus of the airflow, Vgus is larger than Vliquid. Therefore, the droplets are impacted from the front with the high-speed airflow, and are divided into very fine water particles. The generated mist is ejected into the atmosphere from the outlet 17 of the mist generating space 14. At this time, the airflow plays a role of blowing out mist from the mist generation space 14.
[0053]
Next, a third embodiment will be described. FIG. 3 shows a mist generating device according to a third embodiment. As shown in the figure, the mist generating device 21 includes a liquid chamber 22, a gas chamber 23, and a mist generating space 24. A large number of pores 26 are also formed on the rear end wall of the mushroom-shaped head of the chamber 23. Here, as shown in the figure, in the mist generating device 21 of this embodiment, an air stream collides with the liquid droplets from the front in the mist generating space 24.
[0054]
Further, when comparing the velocity vector Vliquid of the droplet and the velocity vector Vgus of the airflow, Vgus is larger than Vliquid. Therefore, the droplets are impacted from the front with the high-speed airflow, and are divided into very fine water particles. The generated mist is ejected into the atmosphere from the outlet 27 of the mist generating space 24. At this time, the airflow plays a role of blowing out mist from the mist generation chamber 24.
[0055]
Next, an embodiment of a fire extinguishing system to which the present invention is applied will be described. This fire extinguishing system includes a cylinder unit 30, hoses 41 and 42, and a fire extinguishing gun 50, as shown in FIG. The cylinder unit 30 includes a pressure cylinder 31, a water tank 32, and a carrier 33 on which these are mounted. The pressure cylinder 31 has a capacity of 6.5 liters and stores compressed air therein. The water tank 32 has a capacity of 50 liters and stores water therein. The compressed air stored in the pressure cylinder 31 has a low pressure of 7 to 8 bar (0.7 to 0.8 MPa). By sending the compressed air in the pressure tank 31 to the water tank 32, water can be sent from the water tank 32 to the fire gun 50 via the water hose 31. Further, the compressed air in the pressure cylinder 31 is further sent out to the fire extinguishing gun 50 via the air hose 42. Here, since the pressure of both water and air is 0.7 to 0.8 MPa (and low pressure), the hoses 41 and 42 do not need to be high pressure hoses.
[0056]
As shown in FIG. 5, the fire extinguishing gun 50 includes a main body 51, a first base 52 extending forward from the main body 51, a screw cap 53 for fixing the first base 52 to the main body 51, A second base 54 attached to the end of the first base 52, a threaded cap 55 for fixing the second base 54 to the first base 52, and a detachable top end of the second base 54. A cap 56 with a nozzle to be screwed in, a grip 57 extending below the main body 51, and a trigger lever 58 swingably mounted above the main body are provided.
[0057]
As shown in FIG. 6, a water inlet 61 for fixing the water hose 41, an air inlet 62 for fixing the air hose 42, and an inlet 61 attached to the center of swing of the trigger lever 58, as shown in FIG. , 62 are provided with through holes for switching between an open state and a closed state, and the valve shafts 63, 63 mounted in front of the inlets 61, 62. 1 block 64 and this No. No. 1 attached to the front of one block 61. 2 block 65 and this No. No. 2 while being inserted into the center of the second block 65. No. 1 attached to one block 64 3 block 66 and this No. No. 3 fixed to the tip side of the block 66. 4 block 67 and this No. A sleeve component 68 is sandwiched between the four blocks 67 and the rear end of the second base 54 and is fitted and fixed to the first base 53.
[0058]
No. In one block 64, flow paths 71 and 72 are formed, which communicate with the water inlet 61 and the air inlet 62, respectively. The flow path 71 for water is no. It penetrates straight through one block 64. As shown in FIG. A first portion 73 extending forward in the first block 64, and the first portion 73 extends from the first portion 73. A second portion 74 branched in the center direction of the one block 64, an air chamber 75 formed ahead of the second portion 74, A third portion 76 branched in the outer peripheral direction of one block 64, a fourth portion 77 extending further forward from the third portion 76, and a ring-shaped recess 78 formed at the front end of the fourth portion 77. ing.
[0059]
No. The two blocks 65 have a stepped hole formed at the center thereof with a large-diameter hole 79 and a front hole 80 narrower than the large-diameter hole 79, and have a cylindrical structure.
[0060]
No. As shown in FIG. 8A, the three blocks 66 include a first dent 81 formed at the front end side, a second dent 82 formed at the center of the first dent 81, and a second dent 82 formed at the center of the first dent 81. A throttle valve fitting hole 83 formed at the center of the rear wall of the second recess 82, a third recess 84 formed behind the throttle valve fitting hole 83, and a second recess 82, A plurality of through holes 85 formed around the throttle valve fitting hole 84; a plurality of air ejection through holes 86 formed near the outer periphery of the rear wall of the first recess 81; A ring-shaped depression 87 is formed at the opening of the through hole 86 for ejection. As shown in FIG. 8B, a large number of oblique grooves 88 are formed in the circumferential direction at an oblique angle of 30 degrees on the front end face of the outer peripheral side wall surface of the ring-shaped depression 87.
[0061]
No. As shown in FIG. 7, the fourth block 67 has a conical through hole 89 which becomes a throttle valve accommodating space at the center and narrows toward the front end side.
[0062]
And, as shown in FIGS. No. 1 block 64, No. 3 block 66 and No. 3 It is stored in a throttle valve storage space formed by the four blocks 67. No. No. 1 block 64 ring-shaped recess 78, In the space formed by the large-diameter hole 79 of the second block 65, No. 1 block 64 and No. The spray plate member 91 is accommodated in the two blocks 65 so as to be sandwiched between the front and rear. As shown in FIG. 9, the spray plate member 91 includes a small-diameter short cylindrical portion 92, the large-diameter short cylindrical portion 93, and a ring plate portion 94 that fills between the short cylindrical portions 92 and 93. It is a thing. The ring plate 94 has a number of small holes 95 penetrating therethrough.
[0063]
Further, as shown in FIG. 10, the sleeve component 68 has a large number of pores 96 formed in a predetermined range from the rear end side.
[0064]
With the components described above, a water chamber 101, an air chamber 102, a mist chamber 103, and a discharge channel 104 are formed inside the fire extinguishing gun 50 as shown in FIG. The air chamber 102 surrounds the periphery of the water chamber 101, and has a ring shape in which a front end portion of the air chamber 102 covers the mist chamber 103.
[0065]
Then, the water supplied to the fire extinguisher 50 via the water hose 41 fills the water chamber 101 through the water inlet 61 and passes through the fine holes 95 of the spray plate member 91, so that the water is supplied to the mist chamber 103. Sprayed.
[0066]
On the other hand, the compressed air supplied from the air hose 42 to the fire extinguisher 50 via the air inlet 62 is The first chamber 73 fills the air chamber 102 through the first part 73, the third part 76, and the fourth part 77 which constitute the flow path 72 of the block 64. The liquid is discharged into the mist chamber 103 through an oblique narrow groove-shaped passage formed by the oblique groove 88 formed in the three blocks 66 and the spray plate member 91. At this time, the compressed air forms a spiral flow in the mist chamber 103 due to the effect that the oblique groove 88 is formed obliquely at 30 degrees to the tangent line.
[0067]
As a result, the water droplets sprayed into the mist chamber 103 are divided by being collided with compressed air having a spiral flow from a direction perpendicular to the flight direction, and changed into fine mist-like particles. As a result, a mist composed of fine water particles is generated in the mist chamber 103.
[0068]
The remainder of the air flowing into the main body 51 from the air hose 42 via the air inlet 62 is supplied to the first portion 73, the second portion 74, and the air chamber 75 constituting the air flow path 72, and to the No. No. 3 via the depression 87 of the block 3 and the through holes 86 for air ejection. It flows into the cone-shaped through hole 89 in the four blocks 67. Then, as a result of the outlet being throttled by the throttle valve 90 housed in the cone-shaped through-hole 89, the flow velocity is increased and flows into the center hole of the sleeve component 68 constituting the inner wall of the mist chamber 103. .
[0069]
Then, the pressure inside the sleeve component 68 becomes relatively negative due to the increase in the flow velocity, and the mist generated in the mist chamber 103 is sucked into the inner space of the sleeve component 68 through the pores 96 of the sleeve member. , Which are discharged vigorously on the airflow toward the discharge port. Thus, according to the mist extinguishing system of the present embodiment, as a result of the fine mist being discharged at a high speed, the mist reaches a distance exceeding 17 meters. This is because the fine mist causes each water particle to become a small mass, so that the water particles can be scattered far by an air flow with low-pressure air of about 7 to 8 bar.
[0070]
The mist discharged far away effectively extinguishes the fire. One of the reasons is that the flame is wrapped in a state in which many fine water particles are collected as mist, so that the air blocking effect as well as the cooling effect is enhanced. Also, since only low-pressure compressed air of about 7 to 8 bar is used, the impact of the mist on buildings, furniture, and the like is small, and they are not destroyed. Further, since the air is sent to the fire site together with the mist, the air also serves as a supply source of the air to those who are left behind in the room in the event of a building fire or the like. In addition, although air is sent in, the mist covers the flame and does not serve as an oxygen supply source for the flame. As the above effects, according to the mist fire extinguishing system of the present embodiment, an effective fire extinguishing activity can be performed.
[0071]
Actually, a fire extinguishing experiment was performed by assembling wood of 35 mm x 35 mm x 900 mm at a pitch of 150 mm and using a wooden prism having a total size of 900 mm x 900 mm x 900 mm. After igniting with 6 liters of gasoline and waiting for 3 minutes, a large lump of flame was created. When this flame was extinguished by the fire extinguishing system of the present embodiment, the fire was completely extinguished in 15 seconds. The amount of water used at this time was 0.7 liter / sec. Also, during and after the fire was extinguished, the wooden prism itself did not collapse even though it was simply made of wood.
[0072]
As described above, one embodiment of the present invention has been described, but the present invention is not limited to the above-described embodiment, and can be embodied in various modes without departing from the gist thereof.
[0073]
For example, in the fourth embodiment, a fire extinguishing liquid may be used instead of water.
[0074]
Further, instead of the small fire extinguishing system mounted on a carrier as in the fourth embodiment, the present invention can be implemented as a large fire extinguishing system mounted on a fire fighting vehicle. In particular, when such a vehicle-mounted type is used, it is effective for a tunnel fire. That is, in the case of a tunnel fire, it is necessary to supply oxygen to the person left in the tunnel, but if the present invention is applied and air is used as a gas, as described above for the building fire, This is because the effect is exhibited also as the oxygen supply device.
[0075]
Further, a mist generating device of the type shown in FIG. 2 achieves a high fire extinguishing ability and a saving of water consumption by being arranged on the ceiling of a building, and also causes damage to people and objects. Can be implemented as no fire extinguisher sprinkler.
[0076]
In addition, the present invention is not limited to fire extinguishing, if applied to a spraying system for agricultural pesticides and plant active agents for agricultural use, protects the health of agricultural workers by suppressing the amount of pesticides used, and protects crops. Can prevent damage, and in spite of that, can realize the spraying of pesticides with high sterilizing and insecticidal effects. Further, the mist generated by the present invention can also be used as an agricultural watering device.
[0077]
Further, the present invention can be applied to a burner by using a combustible material as a liquid. In this case, the gas may be a combustible gas. Since the mist is easily realized, the combustion efficiency can be increased. Therefore, application to a fuel injection portion of a jet engine is effective.
[0078]
In addition, the present invention is also effective as an infrared tracking missile prevention system for a jet fighter. This is to mount the mist generation system of the present invention on a jet fighter, generate mist with water and air, and spray it from the tail of the fighter, thereby cooling the combustion gas ejected from the engine in the air. This is because it is possible to make it difficult to detect the missile sensor.
[0079]
【The invention's effect】
As described above, according to the present invention, there is a need to provide a mist generation method applicable to various fields.
[0080]
Further, according to the present invention, a novel mist generation device applicable to various fields can be provided.
[0081]
Further, according to the present invention, it is possible to provide a fire extinguishing system capable of causing a fire extinguishing liquid to fly far without damaging a building or the like during fire extinguishing.
[0082]
Further, according to the present invention, it is possible to provide a fire extinguishing sprinkler having high fire extinguishing efficiency.
[0083]
In addition, according to the present invention, it is possible to provide a pesticide spraying device having high chemical spraying efficiency.
[0084]
In addition, according to the present invention, an agricultural irrigation system that can save agricultural water can be provided.
[0085]
In addition, according to the present invention, a burner with high combustion efficiency can be provided.
[0086]
In addition, according to the present invention, a missile avoidance device for avoiding an infrared tracking missile can be provided.
[0087]
In addition, according to the present invention, the cooling effect in the machine tool can be enhanced.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view illustrating a configuration of a mist generating device according to a first embodiment.
FIG. 2 is a cross-sectional view illustrating a configuration of a mist generation device according to a second embodiment.
FIGS. 3A and 3B show a configuration of a mist generating device according to a third embodiment, wherein FIG. 3A is a plan view and FIG.
FIG. 4 is a front view showing the overall appearance of a fire extinguishing system as a fourth embodiment.
FIG. 5 is a front view showing the appearance of a fire extinguishing gun included in a fire extinguishing system according to a fourth embodiment.
FIG. 6 is a horizontal sectional view showing the inside of a fire extinguisher constituting a fire extinguishing system according to a fourth embodiment.
FIG. 7 is an enlarged view of FIG. 6;
FIGS. 8A and 8B show the structure of components constituting a fire extinguishing system according to a fourth embodiment, wherein FIG. 8A is a cross-sectional view and FIG. 8B is an end view.
FIGS. 9A and 9B show a structure of components constituting a fire extinguishing system according to a fourth embodiment, wherein FIG. 9A is a cross-sectional view and FIG. 9B is a plan view.
FIG. 10 is a cross-sectional view illustrating a structure of components constituting a fire extinguishing system according to a fourth embodiment.
[Explanation of symbols]
1 ... Mist generator
2 ... Liquid chamber
3 ... Gas chamber
4: Mist chamber
5 ・ ・ ・ Acceleration chamber
6 ... Velocity adjusting valve
7 ... pore
8 ... pore
9 gap
10 ・ ・ ・ Discharge port
11 ・ ・ ・ Mist generator
12 ・ ・ ・ Liquid chamber
13 ... gas chamber
14 ・ ・ ・ Mist generation space
15 ... pore
16 ... pore
17 ・ ・ ・ Exit
21 ...
22 ・ ・ ・ Liquid chamber
23 ・ ・ ・ Gas chamber
24 ・ ・ ・ Mist generation space
25 ... pore
26 ... pore
27 ・ ・ ・ Exit
30 ・ ・ ・ Cylinder unit
31 ・ ・ ・ Pressure cylinder
32 ・ ・ ・ Water tank
33 ・ ・ ・ Carrier
41 ...
42 ...
50 ... Fire gun
51 ... body
52... First base
53 ・ ・ ・ Cap with screw
54 ... second base
55 ... cap with screw
56 ・ ・ ・ Cap with nozzle
57 ... grip
58 ・ ・ ・ Trigger lever
61 ・ ・ ・ Water inlet
62 ・ ・ ・ Air inlet
63 ・ ・ ・ Valve shaft
64 ... No. 1 block
65 ... No. 2 blocks
66 ... No. 3 blocks
67 ... No. 4 blocks
68 ・ ・ ・ Sleeve parts
71 ・ ・ ・ Flow path for water
72 ... air flow path
73 ... first part
74 second part
75 ・ ・ ・ Air chamber
76 ··· Third part
77: Fourth part
78 ・ ・ ・ Ring-shaped depression
79 ・ ・ ・ Large-diameter hole
80 ... front hole
81: first depression
82... Second depression
83 ・ ・ ・ Throttle valve fitting hole
84 ... third depression
85 ... through hole
86 ... through hole for air ejection
87 ・ ・ ・ Ring-shaped depression
88 ・ ・ ・ Diagonal groove
89 ・ ・ ・ Conical through hole
90 ・ ・ ・ Throttle valve
91 ・ ・ ・ Spray plate member
92 ... Small cylindrical part with small diameter
93 ・ ・ ・ Large diameter short cylindrical part
94 ・ ・ ・ Ring plate part
95 ・ ・ ・ pore
96 ・ ・ ・ pore
101 ・ ・ ・ Water chamber
102 ・ ・ ・ Air chamber
103 ・ ・ ・ Mist chamber
104 ・ ・ ・ Discharge channel

Claims (22)

Dividing a liquid into droplets by a nozzle having a large number of pores and discharging the liquid into a predetermined space, and discharging a gas flow into this space from a direction intersecting or opposing the flight direction of the droplet. A mist comprising fine liquid particles is generated by causing the gas stream to collide with the droplet to divide the droplet. The mist generation method according to claim 1,
A mist generation method, wherein the magnitude of Vgus is made larger than Vliquid when the flow velocity and flight direction of the droplet are vector Vliquid and the flow velocity and flight direction of the gas are Vgus. In the mist generating method according to claim 1 or 2,
When the flow velocity and the flight direction of the droplet are vector Vliquid, and the flow velocity and the flight direction of the gas are Vgus, the direction of Vgus should be the direction facing the Vliquid from the front as far as possible in the system. Characteristic mist generation method. In the mist generating method according to claim 1 or 2,
When the flow velocity and the flight direction of the droplet are a vector Vliquid, and the flow velocity and the flight direction of the gas are Vgus, the direction of the Vgus is a direction that tracks the Vliquid as much as possible in the system. Mist generation method. A nozzle having a number of pores for spraying a liquid,
A chamber into which a liquid is sprayed by the nozzle,
A mist generating device, comprising: a gas introduction port for introducing a gas flow into the chamber from a direction intersecting or opposing a flight direction of the droplet. The mist generation device according to claim 5,
A mist generating apparatus characterized in that when the flow velocity and the flying direction of the droplet are vector Vliquid, and the flow velocity and the flying direction of the gas are Vgus, the magnitude of Vgus is larger than Vliquid. The mist generation device according to claim 5 or 6,
When the flow velocity and the flight direction of the droplet are vector Vliquid, and the flow velocity and the flight direction of the gas are Vgus, the direction of Vgus is set so as to face the Vliquid from the front as far as possible in the system. A mist generating device, wherein the nozzle and the discharge port are arranged. The mist generation device according to claim 5 or 6,
When the flow velocity and the flight direction of the droplet are a vector Vliquid, and the flow velocity and the flight direction of the gas are Vgus, the direction of the Vgus is set as the direction to track the Vliquid as much as possible in the system. A mist generating device, wherein a nozzle and the discharge port are arranged. A liquid tank containing a fire extinguishing liquid,
A pressure cylinder containing compressed air;
A fire extinguisher that discharges the fire extinguishing liquid,
A liquid supply path for supplying a fire extinguishing liquid from the liquid tank to the fire extinguisher,
A gas supply path for supplying gas from the pressure cylinder to the fire gun;
Provided in the fire extinguisher, the liquid supplied from the liquid supply path is introduced in the form of droplets, and the compressed air supplied from the gas supply path intersects or faces the flight direction of the droplets. A mist chamber that divides droplets by colliding from a direction to generate a mist composed of fine liquid particles,
A fire extinguishing system, comprising: an accelerating unit provided in the fire extinguisher, for discharging mist generated in the mist chamber on compressed air supplied from the pressure cylinder. The fire extinguishing system according to claim 9,
A fire extinguishing system, wherein the magnitude of Vgus is made larger than Vliquid when the flow velocity and flying direction of the droplet are set as a vector Vliquid, and the flow velocity and flying direction of the gas are set as Vgus. The fire extinguishing system according to claim 9 or claim 10,
When the flow velocity and flight direction of the droplet are vector Vliquid, and the flow velocity and flight direction of the gas are Vgus, the direction of Vgus should be a direction facing the Vliquid from the front as far as possible in the system. Characteristic fire extinguishing system. A liquid tank containing a fire extinguishing liquid,
A pressure cylinder containing compressed air;
A fire extinguisher that discharges the fire extinguishing liquid,
A liquid hose for supplying the fire extinguishing liquid from the liquid tank to the fire gun;
A gas hose for supplying the compressed air from the pressure cylinder to the fire gun;
A liquid inlet provided in the fire gun and provided at a connection portion with the liquid hose;
A gas inlet provided in the fire gun and connected to the gas hose;
A liquid chamber provided in the fire gun and communicating with the liquid inlet;
A gas chamber provided in the fire gun and communicating with the gas inlet;
A mist chamber into which water in the liquid chamber is introduced as droplets through a number of pores,
A mist formed of fine liquid particles, which is provided in the fire extinguisher and crushes the compressed air in the gas chamber from a direction that intersects or opposes the flight direction of the droplets to divide the droplets. To generate the compressed air from the gas chamber to the mist chamber, at least one or more gas inlets,
A fire-extinguishing system provided in the fire-extinguishing gun, wherein the fire-extinguishing system further comprises a mist accelerating unit that sucks out mist generated in the mist chamber and accelerates the compressed air. The fire extinguishing system according to claim 12,
A fire extinguishing system, wherein a part of the compressed air supplied through the gas inlet is branched and supplied to the mist accelerating unit. The fire extinguishing system according to claim 12 or claim 13,
A fire extinguishing system, comprising: a gas accelerating unit that accelerates compressed air supplied to the mist accelerating unit by using a throttle upstream of the mist accelerating unit. In the fire extinguishing system according to any one of claims 12 to 14,
A fire extinguishing system, wherein the magnitude of Vgus is made larger than Vliquid when the flow velocity and flying direction of the droplet are set as a vector Vliquid, and the flow velocity and flying direction of the gas are set as Vgus. In the fire extinguishing system according to any one of claims 12 to 14,
When the flow velocity and flight direction of the droplet are vector Vliquid, and the flow velocity and flight direction of the gas are Vgus, the direction of Vgus should be a direction facing the Vliquid from the front as far as possible in the system. Characteristic fire extinguishing system. A liquid supply for providing a fire fighting liquid;
A gas supply source for supplying gas;
The liquid supplied from the liquid supply source is introduced in the form of liquid droplets, and the liquid supplied from the gas supply source is caused to collide with the liquid in a direction opposite to the flight direction of the liquid droplets, thereby dividing the liquid droplets. And a mist generating unit for generating a mist composed of fine liquid particles. A liquid source for supplying a spray liquid to be sprayed on the crop;
A gas supply source for supplying gas;
The spray liquid supplied from the liquid supply source is introduced in the form of droplets, and the gas supplied from the gas supply source is caused to collide with the droplet in a direction opposite to the flight direction of the droplets, thereby forming droplets. A mist generation unit that generates a mist composed of fine liquid particles by dividing,
A spraying means for spraying the mist generated by the mist generating section. A liquid source for supplying water;
A gas supply source for supplying gas;
The liquid supplied from the liquid supply source is converted into droplets and introduced, and the gas supplied from the gas supply source is caused to collide with the droplet in a direction opposite to the flight direction of the droplet, thereby dividing the droplet. A mist generating unit that generates a mist composed of fine liquid particles
A spraying means for spraying the mist generated by the mist generation unit. A liquid source for supplying a flammable liquid;
A gas supply source for supplying gas;
The flammable liquid supplied from the liquid supply source is introduced in the form of liquid droplets, and the gas supplied from the gas supply source is caused to collide with the liquid in a direction opposite to the flight direction of the liquid droplets. A mist generation unit that divides the droplets to generate a mist composed of fine liquid particles,
A mist discharger configured to discharge the mist generated by the mist generator. A liquid supply for supplying a coolant liquid;
A gas supply source for supplying gas;
The coolant liquid supplied from the liquid supply source is introduced in the form of droplets, and the gas supplied from the gas supply source is caused to collide with the droplet in a direction opposite to the flight direction of the droplets, thereby forming droplets. A mist generation unit that generates a mist composed of fine liquid particles by dividing,
Mist spraying means for spraying the mist generated by the mist generating section toward the rear of the aircraft, and a missile avoiding device mounted on the jet machine. A liquid supply for supplying a coolant liquid;
A gas supply source for supplying gas;
The coolant liquid supplied from the liquid supply source is introduced in the form of droplets, and the gas supplied from the gas supply source is caused to collide with the droplet in a direction opposite to the flight direction of the droplets, thereby forming droplets. A mist generation unit that generates a mist composed of fine liquid particles by dividing,
Mist spraying means for spraying the mist generated by the mist generation section toward a processing portion.

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