KR100969238B1 - Smoke screen generator - Google Patents

Abstract

The present invention does not require a device such as a heating device or a pressure accumulator, and provides a smoke generating device which can block the field of vision at the moment (short time) by smoke and threaten by pronunciation. It is an object of the present invention to provide a smoke generating device capable of improving the diffusibility of smoke screens by an angle in the direction, and to provide a smoke generating device capable of generating a required amount of smoke in a limited space within a limited space. Therefore, the apparatus of the present invention is equipped with an ignition device and a combustion chamber accommodating the fumes by igniting the combustion fumes produced by the ignition device and the gas researches that eject the gas smoke generated by the combustion of the fumes to the outside. In this study, pressure retaining members are installed to maintain the pressure of gas smoke.

Smoke Generator, Smoke Retardant

Description

Smoke screen generator {Smoke screen generator}

The present invention mainly warns or threatens a thief, an intruder, or the like by virtue and pronunciation (sound), and obstructs vision by acting. The present invention relates to a smoke generating device which suppresses or delays and suppresses or prevents criminal acts such as stealing protective materials.

Background Art Conventionally, devices for producing smoke have been used for emergency, rescue, crime prevention, disaster prevention drills, stage production, prevention of plant injury, and the like.

As emergency use and rescue use, there exists the signal line of Unexamined-Japanese-Patent No. 9-126698, for example. In this signal cylinder, ignition of a smelting agent is disclosed to forcefully smoke from one direction of the cylinder.

Moreover, as a disaster prevention drill or the prevention of a plant injury, there exists a smoke apparatus of Unexamined-Japanese-Patent No. 6-211587, for example. In this smoke apparatus, it is disclosed that the liquid is heated and held, and the smoke is vigorously smoked from a plurality of heaters.

Moreover, as a crime prevention use, there exists the security smoke screen device of the Japanese Utility Model Publication No. 6-25987, for example. This crime prevention smoke screen device has the gas ejector of the gas tank filled with carbon dioxide gas in double structure. In addition, a plurality of gas discharge holes are provided in the gas end pipe disposed in the gas ejector inner cylinder along the entire length in the longitudinal direction, and the gas ejection slit extending in the longitudinal direction extends in the upper part of the outer cylinder. In addition, it has been disclosed that the high-pressure gas is spontaneously and evenly ejected into a wide film smoke screen.

However, like the above-mentioned signal tube, there is a problem that the minute study is limited to the direction of smoke in one direction, which is disadvantageous to the spread of the smoke and requires time to block the view.

In addition, as described above, the method of continuously maintaining the liquid by heating and maintaining the smoke from a plurality of heating vaporizers has a problem that the amount of smoke per unit time is small and the time is required to obtain a desired amount of smoke.

In addition, as in the above-described security screen device for crime prevention, the method of ejecting a large film screen in a moment through a gas ejection slit through a gas ejection slit by maintaining the gas at a high pressure in the gas tank also has a limited ejection direction and smoke. There is a problem that since the film is a film, time is required for diffusion of the smoke screen.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problem, and its object is not to require a device such as a heating device or a accumulator, and to block the field of view by fuming instantaneously (short time), To provide a smoke generating device capable of threatening.

Another object of the present invention is to provide a smoke generating device capable of improving smoke spreading properties by the number of minute studies and the angle of the smoke direction.

Another object of the present invention is to provide a smoke generating device that is capable of generating a required amount of smoke in a limited space in a short time.

In addition, another object of the present invention is to improve the smoke diffusion properties (enhancing the momentum of gas smoke ejection) from the powder study and to make the limited space within a short period of time without a difference in concentration (little) To provide a smoke generating device.

Another object of the present invention is to provide a smoke generating device capable of concentrating gas smoke on a protective object.

Smoke growth of the smoke associated with the present invention is provided with an ignition device, a combustion smoke produced by the ignition device, and a combustion chamber for ejecting the gas smoke generated by the combustion of the smoke product to the outside. In the study, a pressure holding member for maintaining the pressure of the gas smoke is provided.

In the smoke generating apparatus according to the present invention, the powder study is provided on one side of the combustion chamber and on the other side different from the one side thereof.

In the smoke generating apparatus according to the present invention, the powder research is provided on one side of the combustion chamber.

The smoke growth value according to the present invention is provided with a gas smoke flow passage control member for changing the flow path of the gas smoke ejected from the dust study by surrounding the outer periphery of the combustion chamber.

In the smoke generating apparatus according to the present invention, the gas smoke flow passage control member has a cylindrical member mounted in the combustion chamber and a conical skirt member whose diameter is expanded toward the open end side of the cylindrical member.

Smoke growth growth value according to the present invention is provided in the combustion chamber and the combustion chamber containing the ignition device, the fuming agent which burns and smokes by the ignition device, and the dust research that ejects the gas smoke generated by the combustion of the smoker. It is provided adjacent and has a blowing chamber which has a spray study which blows out gas smoke to the outside, and the spray study provided in a combustion chamber is provided with the pressure holding member which maintains the pressure of gas smoke.

In the smoke generating apparatus according to the present invention, the powder research provided in the ejection chamber is provided on one side of the ejection chamber and on the other side different from one side thereof.

In the smoke generating apparatus according to the present invention, the powder research provided in the ejection chamber is provided on one side of the combustion chamber.

The smoke-growing growth value according to the present invention is provided with a gas smoke flow passage control member which surrounds the outer periphery of the spray chamber to change the flow path of the gas smoke ejected from the spray study.

In the smoke generating apparatus according to the present invention, the gas smoke flow passage control member has a cylindrical member mounted in the blowing chamber and a conical skirt member whose diameter is enlarged toward the open end side of the cylindrical member.

In the smoke generating apparatus according to the present invention, the dust study has an ejection angle of 45 ° to 135 ° with respect to one side or the other side.

In the smoke-generating apparatus according to the present invention, the spectroscopic research has a development sphere area on one side and a deployment sphere area on the other side.

In the smoke generating apparatus according to the present invention, there is one combustion chamber.

In the smoke generating apparatus according to the present invention, the pressure holding means is a nozzle or a nozzle closure.

In the smoke generating device according to the present invention, the smoke retardant has a combustion rate of 6000 mm / sec under a pressure of 5 to 6 MPa.

In the smoke generating apparatus according to the present invention, the smoke is pronounced when the gas smoke is ejected in the powder study.

In the smoke generating apparatus according to the present invention, the level of pronunciation is 100 to 140 dB.

1 is a cross-sectional view of a smoke generating device according to a first embodiment of the present invention.

FIG. 2 is a side view illustrating the smoke generating device of FIG. 1.

3 is a bottom view of the smoke generating device of FIG. 1.

4 is a cross-sectional view of the smoke generating device according to the second embodiment of the present invention.

5 is a side view illustrating the smoke generating device of FIG. 4.

6 is a bottom view illustrating the smoke generating device of FIG. 4.

7 is a schematic diagram of Experiment 1;

8 is a relationship diagram between combustion chamber internal pressure and combustion time in Experimental Example 1. FIG.

9 is a smoke state of Experimental Example 1.

10 is a flowchart of gas smoke of Experimental Example 1;

11 is a fume state of Experimental Example 2;

12 is a flowchart of Experimental Example 2 gas smoke.

13 is a fume state diagram of Experimental Example 3;

14 is a flowchart of gas smoke of Experimental Example 3;

15 is a fume state diagram of Experimental Example 4. FIG.

16 is a fume state diagram of Experimental Example 5. FIG.

17 is a flowchart of gas smoke of Experimental Example 5. FIG.

FIG. 18 is a relationship diagram between combustion chamber internal pressure (nozzle opening area) and sound pressure level in Experimental Example 6. FIG.

19 is a cross-sectional view of a smoke generating device according to a third embodiment of the present invention.

20 is a cross-sectional view of a smoke generating device according to a fourth embodiment of the present invention.

FIG. 21 is a bottom view illustrating the smoke generating device of FIG. 20.

22 is a side view illustrating the smoke generating device of FIG. 20.

23 is a fume state diagram of Experimental Example 7. FIG.

24 is a fume state diagram of Experimental Example 8. FIG.

25 is a fume state diagram of Experimental Example 9. FIG.

26 is a fume state diagram of Experimental Example 10. FIG.

27 is a smoke state diagram of Experimental Example 11. FIG.

28 is a fume state diagram of Experimental Example 12. FIG.

29 is a principle diagram of an optical sensor measuring instrument for measuring the visual cut-off time.

30 is a bottom view of the smoke generating device according to the fifth embodiment of the present invention.

To practice the invention  Best form for

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

(1st embodiment)

1 to 3 show a smoke generating device 1 according to the first embodiment of the present invention.

The smoke generating device 1 according to the present embodiment is composed of an ignition device 2, a smelting agent 6 which burns and smokes by the ignition device 2, and a combustion chamber 10 containing the smelting agent 6. It is.

The ignition device 2 is filled in the ignition tool 3, the ignition case 4 surrounding the ignition tool 3, and the ignition mechanism 4, and amplifies the energy from the ignition tool 3. It consists of the ignition agent 5 which propagates a combustion to the smoke agent 6, and is provided in the center part of the combustion chamber 10 in order to distribute the combustion flame from the ignition agent 5 to the smoke agent 6 uniformly.

The ignition tool 3 has a heating element 3a that generates heat by energization and an ignition agent 3b that ignites by this heating element 3a. Here, tricinate was used as an ignition agent. The ignition tool 3 is joined to the cap 7 and mounted on the opening of the ignition case 4.

The ignition case 4 is a cylinder body having a bottom open at one side made of aluminum, and the flame of the ignition agent 5 combusted by the flame from the ignition tool 3 propagates uniformly with respect to the smoke agent 6. Usually, the plurality of ignition holes 4a are provided on the circumference. The ignition hole 4a is affixed with an aluminum tape 4b in a manner of blocking the ignition hole 4a in order to maintain the internal pressure at the time of moisture proof and ignition of the ignition agent.

The fuming agent 6 is formed into a tablet form of a composition of zinc oxide, ammonium perchlorate, vinyl chloride, and calcium carbonate. The tablet fuming agent 6 is adjusted so that the combustion rate may be about 6,000 mm / sec under a pressure of 5 MPa depending on the composition ratio and the particle size of each composition. In addition, the combustion end time is set by the particle size 8a, 8b of the combustion chamber 10, and the dimension of refinement | purification so that it may be about 0.5 second.

The combustion chamber 10 has a chamber 8 of a low-cylinder body having a first powder 8a on the circumferential side and a second powder 8b on the bottom, and a through hole for the ignition tool 3 in the center. It has the disk-shaped cap 7 provided with 7a), and is sealed by welding the outer periphery of the cap 7 to the inner periphery of the chamber 8, and fixing it by a caulking part. The chamber 8 is formed of stainless steel with a plate thickness of about 1 mm.

The combustion chamber 10 has a nozzle closer 9a for controlling the combustion speed of the smoke agent 6, preventing the first dust study 8a and the second dust study 8b and maintaining the airtightness of the combustion chamber 10. , 9b) is arranged.

As a result, the nozzle closures 9a and 9b prevent the gas pressure generated by the combustion of the ignition agent from entering the combustion chamber, so that the pressure in the combustion chamber is increased until the combustion agent 6 can start combustion at a predetermined combustion rate. And induces the smoke 6 to burn.

The holding pressure can be arbitrarily set according to the cross-sectional areas of the powders 8a and 8b and the mechanical strength of the nozzle closure.

Here, the first branch study 8a on the circumferential side and the second branch study 8b on the bottom will be described in detail.

In this example, the first branch study 8a provided on the circumferential side and the second branch study 8b provided on the bottom face are provided at an angle of about 90 °.

The 1st study 8a and the 2nd study 8b were made into about 3 mm in diameter and 8 holes together.

As a result, the combustion flame (smoke, etc.) of the combustion chamber 10 passes through the first powder study 8a and the second fire research 8b and is ejected at an angle of about 90 ° to hit the smoke screen.

In order to diffuse the smoke widely, the 1st powder research 8a is installed in the circumference, and it is set as the structure which blows a smoke radially (360 degree direction).

Moreover, in a limited space, the smoke blown out from the 1st study 8a will collide with the wall which forms the space. When the apparatus is installed in the wall surface which forms the space, The flow of gas that burns the wall causes smoke to diffuse into the space.

At the same time, the second part study 8b is also provided on the bottom surface of the chamber 8.

As a result, since the ejection opening of the smoke increases, the direction of ejection of the smoke can be increased as the smoke from the first research 8a and the smoke from the second research 8b, thereby improving the spreading of the smoke.

Thus, in this embodiment, since the 1st branch research 8a provided on the circumferential side and the 2nd branch research 8b provided on the bottom surface are the last exits which smoke blows out of an apparatus, after passing through, It is open to the atmosphere without any resistance. Therefore, the amount of smoke to be ejected becomes a ratio of the total opening area for each first study 8a and second study 8b. For example, if the ratio of the total opening area of the first branch study 8a and the second branch study 8b is 4: 6, 40% of the total amount of smoke is ejected in the circumferential direction and 60% in the axial direction. .

In addition, the 1st study 8a and the 2nd fire research 8b set the opening area of a nozzle so that the internal pressure of the combustion chamber 10 may be 5-6 MPa. Moreover, it is possible to control the ratio of the amount of smoke in each powder direction to the shape of the target space, and to control by the ratio of the opening area of the 1st powder 8a and the 2nd powder 8b.

Next, the operation of the smoke generating device 1 according to the present embodiment will be described.

The smoke generating device 1 according to the present embodiment is provided, for example, on the ceiling of a safe room.

For example, when the abnormality detection sensor detects an illegal intruder such as a robbery, an operation signal (ignition current) is sent to the smoke generating device 1.

In the smoke generating apparatus 1, a constant electric current flows into the ignition tool 3, and the ignition agent ignites by this, and the ignition agent 5 burns by the flame and the impact.

The flame of the complexing agent 5 propagates from the ignition hole 4a of the complexing case 4 to the smelting agent 6, and the internal pressure of the combustion chamber 10 rises by the smoke of this combustion gas.

Then, the nozzle closures 9a and 9b which are blocking the first powder 8a and the second powder 8b by the internal pressure of the combustion chamber 10 reach the elastic limit and break.

In addition, the gas smoke generated by the combustion of the smoke agent 6 is ejected from the first powder research 8a and the second powder research 8b.

In addition, the gas smoke generated by the combustion of the smoke agent 6 is accompanied by pronunciation because it passes the first and second study 8a and 8b at a speed exceeding the speed of sound.

Thereby, the smoke screen which blocks a visual field in a safe room spreads.

In addition, although the case where illegal intruders, such as a robber, etc. were detected by the abnormality detection sensor was demonstrated here, when a security guard confirmed illegal intruders, such as a robbery, a human hand switches the activation switch to contact the smoke generating device 1 By pressing, it is possible to operate.

In addition, although this embodiment demonstrated the case where the 1st branch research 8a and the 2nd branch research 8b were prepared, either branch research was closed and the branch research was provided only on 1 side, and gas smoke was removed. It is also possible to emit from one direction.

In addition, a powder study may be provided at the boundary between the bottom plate and the side plate of the chamber 8 to release gas smoke from the lower edge of the smoke generating device 1.

(2nd embodiment)

4 to 6 show a smoke generating device 20 according to the second embodiment of the present invention.

The smoke generating device 20 according to the present embodiment includes the ignition device 22 and the smoke generator 26 which burns and smokes by the ignition device 22, the combustion chamber 30 which accommodates this smoke agent 26, and the combustion chamber ( It is comprised by the blowing chamber 31 arrange | positioned adjacent to 30).

In the smoke generating device 20 according to the present embodiment, the ejection chamber 31 is disposed adjacent to the combustion chamber 30, and the gas smoke is emitted from the ejection chamber 31 without emitting from the combustion chamber 30. It differs from the smoke generating apparatus 1 which concerns on 1st Embodiment.

The low-temperature chamber 28 made of stainless steel having a plate thickness of about 1.5 mm constituting the combustion chamber 30 penetrates the ignition tool 23 at the center to form the ejection chamber 31 adjacent to the combustion chamber 30. Flange part 28c which protrudes further outward from this cover part 28b by the low cover part 28b which protrudes outward from the junction part 28x with the disk-shaped cap 27 which provided the ball 27a. Equipped with.

On the side wall of the chamber 28, a powder research 28a corresponding to the first powder research 8a in the first embodiment is provided. In the powder research 28a, the combustion speed of the smoke agent 26 is controlled. The nozzle closure 29a for preventing the dust study 28a and maintaining the airtightness of the combustion chamber 30 and the filter 29b for collecting the debris generated after the combustion of the fume 26 are disposed in an overlapping manner. have.

As a result, the nozzle closure 29a prevents the gas pressure generated by the combustion of the ignition agent from entering the combustion chamber, and maintains the pressure in the combustion chamber until the smoke generator 26 can start combustion at a predetermined combustion rate. While the smoke agent 26 is to be burned.

The pressure to be retained can also be arbitrarily set in accordance with the cross-sectional area of the first powder work 28a and the mechanical strength of the nozzle closure.

In addition, in the combustion chamber 30, the combustion material 26 and the cushioning materials 30a and 30b which support this combustion material 26 are arrange | positioned up and down so that the combustion material 26 may be enclosed, and the volume adjusting spacer ( 30c) is arrange | positioned at the cushioning material 30a side.

The ejection chamber 31 has a cylindrical cover member 32 surrounding the lid portion 28b of the chamber 28 and the dust chamber 28a side of the chamber 28 and the dust chamber 28a of the combustion chamber 30. A cylindrical separating member 33 arranged to surround the study 28a apart from the predetermined intervals and supporting the separating member 33 and a cover portion of the chamber 28 together with the covering member 32 ( It consists of the partition member 34 fixed to 28b).

The ejection chamber 31 has a first chamber 31a in communication with the dust chamber 28a of the combustion chamber 30, a second chamber 31b in communication with the first chamber 31a, and this second chamber ( The third chamber 31c which contacts 31b) is formed.

Here, the first chamber 31a draws the gas smoke ejected from the study 28a of the combustion chamber 30 to the second chamber 31b, and the second chamber 31b is a hole of the partition member 34. 34a) is used to lead gas smoke to the third chamber 31c, and the third chamber 31c is provided with gas smoke from the first branch chamber 32a provided on the side wall and the second branch chamber 32b provided on the bottom surface. Emits.

The first branch research 32a provided on the side wall and the second branch research 32b provided on the bottom face are the first branch research 8a provided on the circumferential side in the first embodiment and the second section provided on the bottom face. Like the study 8b, both are provided at an angle of about 90 °.

Here, the 1st branch study 32a and the 2nd branch study 32b are explained in full detail.

In the first part study 32a, in order to spread | diffuse smoke extensively, it is set in the cylinder and it is set as the structure which ejects smoke radially (360 degree direction).

In addition, the first minute study 32a set the diameter of about 8 mm and the number of holes to 20 in view of the container strength. Moreover, in a limited space, the smoke blown out from the 1st research 32a hits the wall which forms the space. Here, when the smoke screen planetary device is installed on either of the walls forming the space, the gas flows on the wall is generated, whereby the smoke diffuses into the space.

At the same time, the second research 32b is also provided on the bottom of the jet chamber 31.

As a result, the direction of the jet of smoke is increased, and the direction of the smoke is changed to improve the diffusibility of the smoke as the smoke from the first study 32a and the smoke from the second study 32b.

In the above-described first embodiment, since there is no resistance to the gas smoke passing through the first branch study 8a and the second branch study 8b, the first branch study 8a and the second branch study 8b. The amount of smoke is distributed according to the ratio of the opening area.

On the other hand, in this embodiment, when the gas smoke in the combustion chamber 30 passes through each of the following resistors, it is perpendicular | vertical to the surface of the 2nd research 32b (on the surface of 1st research 32a). The flow of gas smoke is formed in a parallel manner, so that smoke tends to come out in the second branch work 32b, and it is difficult for the smoke to come out in the direction of the first branch work 32a.

Here, the gas smoke passage passes through the study 28a of the combustion chamber 30 → the first chamber 31a → the second chamber 31b → the third chamber 31c → the first chamber 32a and the second minute. Study 32b.

Therefore, as described in Experimental Example 5 to be described later, when the number of the first sub-studies 32a having a diameter of 8 mm and the second sub-studies 32b having a diameter of 6 mm were each 20, respectively, most of the smoke amount was the second. The phenomenon which ejects from the powder research 32b (axial direction), and does not eject much in the 1st research 32a arises.

In addition, the amount of smoke from the first study 32a and the second study 32b fixed the opening area of the first study 32a to 8 mm in diameter and 20 smoke holes, and the second minutes When the aperture diameter of the study 32b is 6 mm in diameter, increasing the number of smoke holes in the second study 32b increases the amount of smoke from the second study 32b than the first study 32a. There is a relationship. In this case, when the number of the second study 32b exceeds 12, most of the smoke is ejected from the second study 32b, and the smoke from the first study 32a becomes insignificant.

In addition, the 2nd minute study 32b made diameter about 6 mm in the dimension of each component.

Since the internal pressure control of the combustion chamber 30 is carried out by the powder research 28a, and the opening area of the second powder research 32b does not affect the pressure resistance control, the number of the second powder research 32b is the maximum allowable in dimensions. Up to about 30 people can be installed, and the optimum number can be installed according to the shape of the target space.

Next, the operation of the smoke generating device 20 according to the present embodiment will be described.

The smoke generating device 20 according to the present embodiment is installed, for example, on the ceiling of a safe room.

For example, when the abnormality detection sensor detects an illegal intruder such as a robbery, an operation signal (ignition current) is sent to the smoke generating device 20.

First, the constant current flows through the ignition tool 22, and the ignition agent 23b ignites, and the ignition agent 25 burns by the flame and the impact.

The flame of the ignition agent 25 propagates from the ignition hole 24a of the ignition case 24 to the smelting agent 26, and the internal pressure of the combustion chamber 30 rises by the smoke of this combustion gas.

And the nozzle closer 29a which blocks the powder 28a by the internal pressure of a combustion chamber reaches an elastic limit, and it breaks.

In addition, the gas smoke generated by the combustion of the fume 26 passes through the powder research 28a from the filter 29b and the nozzle closure 29a, and is blocked by the separating member 33 of the jet chamber 31. It flows from the 1st chamber 31a into the 2nd chamber 31b, passes through the hole 34a of only one partition member 34, and flows into the 3rd chamber 31c, Smoke is ejected from the 2nd research 32b.

In addition, the gas smoke generated by the combustion of the smoke agent 26 is accompanied by pronunciation in order to pass through the powder research 28a at a speed exceeding the speed of sound.

Thereby, the smoke screen which blocks a visual field in a safe room spreads.

In addition, although the case where the illegal intruder, such as a robber, etc. were detected by the abnormality detection sensor was demonstrated, when a security guard confirmed the illegal intruder, such as a robbery, when a security guard presses the start switch which contacts the smoke generating device 20 by hand. The same operation is possible.

Moreover, in this embodiment, although the case where the 1st branch research 32a and the 2nd branch research 32b was provided was demonstrated, either branch research was closed and the branch research was provided only on one side, and a gas was provided. It is also possible to release smoke from one direction.

In addition, a dust study may be provided at the boundary between the bottom plate and the side plate of the spray chamber 31 to release gas smoke from the lower edge of the smoke generating device 20.

Next, the result of having performed various experiments with respect to the smokescreen production apparatus 20 which concerns on 2nd Embodiment is shown.

Experimental Example 1

As shown in FIG. 7, the smoke screen which concerns on this embodiment in the position of 30 cm from the ceiling side in the center part of the room 50 of width 5.3m x depth 2.1m x height 2.3m (about 26m <3>). The generator 20 was installed.

In addition, the number of the 1st study 32a and the 2nd study 32b of the apparatus of this experiment example 1 is 20 pieces and 8 pieces, respectively. At this time, the sound pressure measurement sensor 51 was installed to measure the sound pressure level.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoker was finished in about 0.5 seconds, and the smoke was ejected out from the first study 32a and the second study 32b approximately 1 to 2 seconds after the smoke began to burn. The relationship between time and internal combustion chamber pressure is shown in FIG. 8, and after about 0.5 second, it turns out that internal combustion chamber pressure becomes atmospheric pressure and the pressure in a combustion chamber is opened. Therefore, after about 0.5 second, it can be judged that the combustion of a smoke retarder was complete | finished.

In addition, the fuming conditions immediately after the operation, 0.2 seconds later and 0.5 seconds later are shown in Figs. 9A, 9B and 9C, respectively.

And the spewed smoke spread | diffused in the space for several tens of seconds evenly around the apparatus, without big bias in the amount of smoke from each powder study 32a, 32b. The flow of smoke at this time is as shown in FIG.

At this time, the test operator entered the diffused smoke screen and checked the degree of visibility and the degree of freedom of action.

This test operator was able to confirm the effect of depriving the vision for several tens of seconds and suppressing the behavior.

In addition, the sound pressure level of the operation sound generated from the combustion to the ejection of the smoke is about 120 to 130 dB, and when used for security purposes, it was found that the threat of smoke and the threat of sound are possible.

Experimental Example 2

In the same manner as in Experiment 1, the smoke generating device 20 according to the present embodiment was installed in the center of the chamber 50.

Here, the number of the first branch study 32a and the second branch study 32b was 20 and three, respectively.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the fuming agent was finished in about 0.5 seconds, and the smoke was ejected only from the powder researches 32a and 32b in about 1 to 2 seconds after the fuming agent started to burn.

In addition, the fuming conditions immediately after the operation, 0.2 seconds later and 0.5 seconds later are shown in Figs. 11A, 11B, and 11C, respectively.

Since the smoke emitted has a large amount of smoke from the first powder research 32a, and a large amount of gas is blown out in the circumferential direction of 360 °, the force in the circumferential direction increases, and as shown in FIG. Spread.

At this time, the field of view and the degree of freedom were confirmed as in Experimental Example 1. As a result, it was possible to confirm the effect that the field of view was blocked after tens of seconds.

Experimental Example 3

In the same manner as in Experiment 1, the smoke generating device 20 according to the present embodiment was installed in the center of the room 50.

Here, the number of the first branch studies 32a and the second branch studies 32b was 20 and 12, respectively.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoker was finished in about 0.5 seconds, and the smoke was blown out from the powder studies 32a and 32b approximately 1 to 2 seconds after the smoker started to burn.

In addition, the fuming conditions immediately after the operation, after 0.2 second and after 0.5 second, are shown in Figs. 13A, 13B and 13C, respectively.

And the blown-out smoke spread | diffused while the same flow of FIG. 14 generate | occur | produced because the amount of smoke from the 2nd powder research 32b was large, and the amount of gas ejected in the axial direction was large.

At this time, the field of view and the degree of freedom were confirmed as in Experimental Example 1. As a result, it was possible to confirm the effect that the field of view was blocked after tens of seconds and behavior was suppressed.

Experimental Example 4

As shown in FIG. 15, in the same room 50 as Experimental example 1, the number of 1st research 32a and the 2nd research 32b produced the smokescreen which concerns on 20 and 10 this embodiment, respectively. The apparatus 20 was installed near the wall center center of about 1.2 m in height.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoker was terminated in about 0.5 seconds, and the smoke was ejected out of the powder study approximately 1 to 2 seconds after the smoker started to burn.

And since the smoke emitted was large in the amount of smoke from the 2nd powder research 32b, and the amount of gas ejected in the axial direction was large, it spread | diffused while the flow as shown in FIG.

At this time, the field of view and the degree of freedom were confirmed as in Experimental Example 1. As a result, it was possible to confirm the effect that the field of view was blocked after tens of seconds and behavior was suppressed.

Experimental Example 5

As shown in FIG. 16, the smoke generating device 20 concerning this embodiment was provided in the center of room 50 similarly to Experimental example 1. As shown in FIG.

Here, the number of the first branch study (diameter 8 mm) 32a and the second branch study (diameter 6 mm) 32b was set to 20 pieces each.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the fuming agent was terminated as about 0.5 second, and the smoke was ejected out from the study 32a and 32b in approximately one to two seconds after the combustion agent began to burn.

And the blown-out smoke spread | diffused while generating like FIG. 17, since the amount of smoke from the 2nd powder research 32b became large and the amount of gaseous smoke ejected in the axial direction was large.

At this time, the field of view and the degree of freedom were confirmed as in Experimental Example 1. As a result, after tens of seconds, the effect was completely blocked and behavior was suppressed.

Experimental Example 6

In the same manner as in Experiment 1, the smoke generating device 20 according to the present embodiment was installed in the center of the room 50.

Here, the smoke generating device 20 according to the present embodiment fixes the number of the first sub-studies 32a having a diameter of 8 mm and the second sub-studies 32b having a diameter of 6 mm to 20 and 8, respectively. The opening area of the study 28a was varied in the range of about 53 mm 2 to about 275 mm 2 and the sound pressure level during operation was measured by a sound pressure sensor.

The result is shown in FIG.

As is apparent from FIG. 18, the internal pressure of the combustion chamber 30 changes in the range of 2.6 to 14.4 MPa, the sound pressure level at that time is 91 to 138 dB, and the internal pressure of the combustion chamber 30 rises (= minute study 28a). It was confirmed that the opening area of N) was decreased.

In addition, Table 1 shows the sound pressure level of the device, and it can be confirmed that a warning or threat due to pronunciation can be caused.

TABLE 1

soundtrack Sound pressure level (dB) Jet erosion 140-150 20 mm gun 140 Rock drill (no silencer) 120 Rock drill (with silencer) 110 Horn 100-110 Difficulty speaking 90-95 Guard Mill 90 Passage of car (ten) 80 Ordinary conversation 65

19 shows a smoke generating device 40 according to a third embodiment of the present invention.

The smoke generating device 40 according to the present embodiment is provided with a gas smoke flow passage control member 41 on the outside of the combustion chamber 10, and is different from the smoke generating device 1 according to the first embodiment.

The gas smoke flow passage control member 41 is fixed to the chamber 8 by a welding portion 44. The gas smoke flow passage control member 41 is formed of a cylindrical member 42 made of stainless steel with a plate thickness of 1.5 mm. It is attached to the inner surface of the cylindrical member 42, and has the conical skirt member 43 which diameter extends from the opening end 43a of one side of the cylindrical member 42 toward the opening end 43e of the other side. At the opening end 43a on one side of the skirt member 43, a wall surface 43b is formed in contact with the chamber 8 when the welding member 44 is fixed to the chamber 8. In addition, a conical skirt portion 43d is formed at the lower end portion 43c of the wall surface 43b and the other opening end 43e.

Next, the operation of the smoke generating device 40 according to the present embodiment will be described.

The smoke generating device 1 according to the present embodiment is installed, for example, on the ceiling of a safe room.

For example, when an abnormality detection sensor detects an illegal intruder such as a robbery, an operation signal (ignition current) is sent to the smoke generating device 1.

In the smoke generating device 1, a constant current flows into the ignition tool 3, whereby the ignition agent ignites, and the ignition agent 5 burns by the flame and the impact.

The flame of the ignition agent 5 propagates from the ignition hole 4a of the ignition case 4 to the ignition agent 6, and the internal pressure of the combustion chamber 10 rises by this combustion gas smoke.

And the nozzle closures 9a and 9b which block the 1st research 8a and the 2nd research 8b by the internal pressure of the combustion chamber 10 reach an elastic limit, and they break | rupture.

Moreover, the gas smoke produced by the combustion of the smoke agent 6 is blown off from the 1st research 8a and the 2nd research 8b.

Then, the smoke blown out from the first dust study 8a collides with the conical skirt portion 43d of the gas smoke flow passage control member 41 and is strongly ejected in a state where it is concentrated in the longitudinal axis direction of the smoke generating device 40. .

In addition, the gas smoke generated by the combustion of the fuming agent 6 is accompanied by pronunciation in order to pass through the first branch study 8a and the second branch study 8b at a speed that exceeds the speed of sound.

Thereby, the smoke screen which blocks a visual field in a safe room spreads.

As described above, according to the smoke generating device 40 according to the present embodiment, the smoke generating device 40 has the same effect as the smoke generating device 1 and the unique action effect of providing the gas smoke flow passage control member 41. It becomes possible to have

That is, a strong gas smoke with an ejection force is formed in which the gas smoke ejected from the first dust study 8a is concentrated again in the longitudinal axis direction of the smoke generating device 40, so that smoke spreading (shortening of time-blocking time, safe box) Uniform field of view to spaces such as rooms) improves. In addition, the effect of the shape of the space part by preventing the weakness of the gas smoke eruption by the shape of the space part such as the safe room which produces smoke smoke In addition, the behavior of the smoke screen can be controlled by changing the angle of the skirt portion 43d of the gas smoke flow passage control member 41.

In addition, although this embodiment demonstrated the case where the 1st research 8a and the 2nd research 8b were prepared, either of them was closed, and a research on only one side was provided, and a gas smoke was provided. It is also possible to emit from one direction.

20 to 22 show a smoke generating device 50 according to the fourth embodiment of the present invention.

The smoke generating device 50 according to the present embodiment has a gas smoke flow path control member 51 provided on the flange portion 28c and surrounds the outer circumference of the jet chamber 31. It is different from the device 20.

The gas smoke flow passage control member 51 is formed of a cylindrical member 52 made of stainless steel having a plate thickness of 1.5 mm, which is mounted via a bolt 54 to a flange portion 28c located outside the ejection chamber 31. It is attached to the inner surface of the cylindrical member 52, and has a conical skirt member 53 which extends from the opening end 52a of one side of the cylindrical member 52 toward the opening end 52b of the other side. In the opening end 52a on one side of the skirt member 53, four screw holes 53a for engaging the bolt 54 are equally provided on the circumference.

Next, the operation of the smoke generating device 50 according to the present embodiment will be described.

The smoke generating device 50 according to the present embodiment is installed, for example, on the ceiling of a safe room.

For example, when the abnormality detection sensor detects an illegal intruder such as a robbery, an operation signal (ignition current) is sent to the smoke generating device.

First, the ignition tool 23b ignites because a constant electric current flows through the ignition tool 22, and the ignition agent 25 burns by the flame and the impact.

The flame of the ignition agent 25 propagates from the ignition hole 24a of the ignition case 24 to the ignition agent 26, and the internal pressure of the combustion chamber 30 rises by this combustion gas smoke.

And the nozzle closer 29a which blocks the powder 28a by the internal pressure of a combustion chamber reaches an elastic limit, and it breaks.

In addition, the gas smoke generated by the combustion of the smoke agent 26 passes through the powder research 28a from the filter 29b and the nozzle closure 29a, and is blocked by the separating member 33 of the ejection chamber 31. It flows from the 1st chamber 31a to the 2nd chamber 31b, passes through the hole 34a of the other partition member 34, and flows into the 3rd chamber 31c, and it is made into the 1st research 32a and 1st chamber. Smoke is blown off from two minutes study 32b.

The smoke ejected from the first powder research 32a is strongly ejected in a state of being concentrated in the longitudinal axis direction of the smoke generating device 50 while colliding with the gas smoke flow passage control member 51.

In addition, the gas smoke generated by the combustion of the smoke agent 26 is accompanied by pronunciation so as to pass through the smoke-compressing sphere 28a at a speed exceeding the speed of sound.

Thereby, the smoke screen which blocks the visual field in a vault room spreads.

Next, in the smoke generating apparatus 50 which concerns on 4th Embodiment, the experiment regarding the visual field interruption time was performed, and the result is shown.

In addition, the field of view blocking time of this experiment means time until there is no difference in the density (field of view) of the smoke in space parts such as the safe room (room), and the time required until the field of vision completely shuts off to be.

For example, even in the position of the neck of the installation chamber (space part) of the smoke generating apparatus 50 according to the present embodiment, there is no visual difference (concentration difference) due to smoke.

The smoke generating device 50 according to the present embodiment is the same as the smoke generating device 20 according to the second embodiment, as shown in FIG. 7, about 5.3 m wide x 2.1 m deep x 2.3 high. It was installed at the position of approximately 30cm from the ceiling in the center part of the room of m (volume: approximately 26m 3).

In addition, in order to measure the visual field cut-off time, an optical measuring sensor is equally installed in four spaces from the ceiling to the floor, respectively, on one side wall surface of the room (space part) and the other side wall surface intersecting the one side wall surface. did.

As shown in Fig. 29, this optical measuring sensor is a pair of optical sensors that transmit and receive light from the amplifier unit 100. When the smoke is generated, the amount of light transmitted, that is, the amount of light received, is determined. Use this to change.

In other words, although a certain amount of light is transmitted, if there is smoke between the light sensors, the light is blocked and the amount of light received is reduced, so that the amount of received light is displayed on the digital screen.

Then, after the smoke generating device 50 according to the present embodiment is operated, the change in the elapsed time of the received light amount in the room is measured, and the time at which the received light amount of the optical sensor 101 reaches the same level is determined as the view blocking time. did.

Experimental Example 7

In the apparatus of Experimental Example 7, the number of the first minute study 32a was 8 mm, and the number was 20, and the second minute study 32b was 6 mm, the number was 8.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoke was finished in about 0.5 seconds, and the gas smoke was ejected from the first study and the second study until one to two seconds after the combustion of the smoke.

Then, the ejected gas smoke diffused without variation around each of the study 32a and 32b, and diffused through the space in a few tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the fumes are shown in Figs. 23A, 23B, (C), (D) and (E), respectively.

In addition, approximately 5 minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

Experimental Example 8

The apparatus of Experimental Example 8 was equipped with the gas smoke flow passage control member 51 in which the reflection angle of the skirt member 53 was set to 45 ° to the smoke generating apparatus of Experimental Example 7. FIG.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoker was finished in about 0.5 seconds, and the smoke was ejected from the first study and the second study 1 to 2 seconds after the smoke was burned.

Then, the spewed smoke diffused without variation around each of the study 32a and 32b, and diffused through the space for several tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the fumes are shown in FIGS. 24A, 24B, C, D, and E, respectively.

In addition, approximately 2.5 minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

Experimental Example 9

The apparatus (corresponding to the smoke generating device 60 shown in FIG. 30) of Experimental Example 9 is a configuration in which only the first minute study (diameter 8 mm × 20 pieces) 32a is provided in the smoke generating device of Experimental Example 7. As a result, a gas smoke flow passage control member 51 having a reflection angle of the skirt member 53 set to 45 degrees was attached thereto.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoke was finished in about 0.5 seconds, and the gas smoke was ejected from the first powder 32a in 1 to 2 seconds after the combustion of the smoke.

Then, the ejected gas smoke diffused without variation from each particle study 32a around, and diffused through the space for several tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the fumes were shown in Figs. 25A, 25B, 25C, and 18E, respectively.

In addition, approximately two minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

Experimental Example 10

The apparatus of Experimental Example 10, in the smoke generating apparatus of Experimental Example 9, was equipped with a gas smoke flow passage control member 51 in which the reflection angle of the skirt member 53 was set to 32 degrees.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoke was finished in about 0.5 seconds, and the gas smoke was ejected from the first powder study 32a 1 to 2 seconds after the combustion of the smoke.

Then, the ejected gas smoke diffused without variation from each particle study 32a around, and diffused through the space for several tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the smokes are indicated in FIGS. 26A, 26B, (C), (D), and (E), respectively.

In addition, approximately 3 minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

Experimental Example 11

The apparatus of Experimental Example 11 is equipped with a gas smoke flow passage control member 51 in which the reflection angle of the skirt member 53 is set to 28 ° in the smoke generating apparatus of Experimental Example 9.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoke was terminated by about 0.5 seconds, and the gas smoke was ejected from the first powder study 32a 1 to 2 seconds after the combustion of the smoke.

Then, the ejected gas smoke diffused without variation from each particle study 32a around, and diffused through the space for several tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the fumes were shown in Figs. 27A, 27B, (C), (D) and (E), respectively.

In addition, approximately 3 minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

Experimental Example 12

The apparatus of Experimental Example 12 is equipped with a gas smoke flow passage control member 51 in which the reflection angle of the skirt member 53 is set to 23 ° in the smoke screen generating apparatus of Experimental Example 9.

Next, the device was operated by energizing the ignition tool by remote operation.

As a result, the combustion of the smoke was terminated by about 0.5 seconds, and the gas smoke was ejected from the first powder study 32a 1 to 2 seconds after the combustion of the smoke.

Then, the ejected gas smoke diffused without variation from each particle study 32a around, and diffused through the space for several tens of seconds.

Immediately after the operation, 0.5 seconds later, 3 seconds later, 60 seconds later, and 120 seconds later, the fumes were shown in FIGS. 28A, 28B, C, D, and E, respectively.

In addition, approximately 3.5 minutes after the operation, the difference in the field of vision reached the same level (field blindfold time).

(Review)

From Experimental Examples 7 to 12, it was found that the smoke-growing value obtained by the gas smoke flow passage control member 51 was improved in the diffusibility effect of the smoke screen.

In addition, it was found that the behavior (diffusion) of the smoke screen was changed by the set angle of the skirt member 53 of the gas smoke flow passage control member 51 when fixed in the configuration of only the first minute study 32a.

30 shows a smoke generating device 60 according to the fifth embodiment of the present invention.

The smoke generating device 60 according to the present embodiment is different from the smoke generating device 20 according to the fourth embodiment in that the second research 32b is omitted.

According to the smoke generating apparatus 60 which concerns on this embodiment, since the powder research was made into only the 1st research 32a which was formed only in one side on the circumferential side (curved part), the gas from the 1st research 32a was made. As smoke vaporized by the gas smoke flow passage control member 51, the effect of improving the diffusibility is increased, and a state in which there is no difference in the concentration (field of view) of the gas smoke in the space part such as the safe room is possible in a short time.

In addition, since the gas smoke flow path impinges on the control member 51 and changes the direction of the gas smoke from the first research 32a, the gas smoke is ejected vigorously, thereby concentrating on the protective object in the safe room and blocking the view in the safe room in a short time. .

As described above, according to the present invention, since the ignition device is arranged directly in the combustion chamber containing the fuming agent, it is possible to instantaneously blow off the smoke in the dust study and diffuse the smoke screen after the operation.

In addition, by arranging the ignition apparatus directly in the combustion chamber containing the smoke retardant, and also by arranging the powder, it is possible to reduce the size compared to the prior art while securing a predetermined amount of smoke.

In addition, by providing a plurality of powdered researches and installing the plurality of powdered researches at different angles, it is possible to diffuse gas smoke widely and enhance the visual field blocking effect.

In addition, if the combustion chamber is formed in a container that can withstand high pressure, the internal pressure of the combustion chamber can be increased, or the combustion of the smoke can be increased quickly, thereby increasing the amount of smoke per unit time, and easily ejecting the gas smoke necessary for a short time from the container. It is also possible.

In addition, by maintaining the pressure of the gas smoke combusted by the smoke in the combustion chamber for a predetermined time, it is possible to pronounce while the gas smoke blows out of the apparatus at a speed exceeding the speed of sound.

In addition, since the gas smoke flow path control member is provided, the gas smoke ejected from the dust research is concentrated again in the longitudinal axis direction of the smoke generating device to form a strong gas smoke that is ejected, and thus the smoke spreadability (shortening of the time-blocking time is shortened). Uniform view block to space parts such as safe room) is improved.

In addition, since the gas smoke flow path control member is provided, it is possible to prevent the force of the gas smoke from being blown off by the shape of the space part such as the safe room for generating smoke smoke, so that the influence of the shape of the space part can be reduced.

In addition, it is possible to control the behavior of the smoke screen by changing the angle of the gas smoke flow passage control member.

Claims (17)

With ignition, A fuming agent that burns and smokes by the ignition device, A combustion chamber accommodating the fumes and providing a dust study for ejecting gas smoke generated by combustion of the fumes to the outside; A pressure holding member installed on the inner surface of the combustion chamber so as to prevent the dust study and maintaining the pressure in the combustion chamber until combustion of the smoke can be started; Smoke generating device, characterized in that provided with. The method of claim 1, And a gas smoke flow passage control member which wraps around the outer circumference of the combustion chamber and changes the flow path of the gas smoke ejected from the dust study. The method of claim 2, The gas smoke flow path control member, A cylindrical member mounted to the combustion chamber to surround the combustion chamber outer circumference; And a conical skirt member whose diameter extends toward the opening end side of said tubular member. With ignition, A fuming agent that burns and smokes by the ignition device, A combustion chamber accommodating the smoke retarder and providing a first respiratory study for ejecting gas smoke generated by combustion of the smoke retardant; A pressure holding member installed on the inner surface of the combustion chamber so as to prevent the first minute study, and maintaining a pressure in the combustion chamber until combustion of the smoke can be started; An ejection chamber disposed adjacent to the combustion chamber and introducing the gas smoke from the first fractional study; A second branch study installed on one side of the ejection chamber and ejecting the gas smoke introduced from the first branch study to the outside; A separating member arranged to surround the first minute study at a predetermined interval from the first minute study in an internal space of the jet chamber in contact with the first minute study and the second minute study; A plurality of disappearances separated by the separating member, A flow path formed by the plurality of disappearances so as to introduce the gas smoke from the first branch study to the second branch study, Smoke generating device, characterized in that provided with. delete delete delete delete delete delete delete delete delete delete delete delete delete

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