KR200344504Y1 - Lacrimatory gas atomizer for self-defense - Google Patents

Abstract

The present invention relates to a tear gas sprayer for self-defense, the pressurization button of the conventional pressurized pumping type is connected to the tear gas reservoir, presses the injection button of the injection hole is inserted into the nozzle tip, the pumping action of the pressure pump, the tear gas in the gas reservoir Through the gas supply tube, it is supplied to the gas discharge path of the injection button is injected into the injection hole of the nozzle tip; The nozzle tip is inserted into the nozzle tip insertion groove of the injection button, the locking projection formed on the outer circumferential surface thereof is combined with the projection locking groove formed in the nozzle tip insertion groove, the tear gas sprayer is fixed to the injection button, the gas discharge path is It is formed to penetrate one side of the nozzle tip fixing groove of the injection button; At least one gas guide groove is formed on the inner circumferential surface of the nozzle tip from the rear end to the injection hole for guiding the tear gas supplied from the gas discharge path to the injection hole; The locking projection is formed in the middle portion of the nozzle tip, the nozzle tip is projected from the injection button is formed between the nozzle tip and the gas discharge path for the tear gas circulation gap, the tear hole between the injection hole of the nozzle tip and the side wall of the injection button It is characterized in that the condensation chamber for gas compression is formed, the injection gas is compressed in the gas induction groove and the coagulation chamber, there is an effect that the range is extended.

Description

Self-tear gas atomizer for self-defense {LACRIMATORY GAS ATOMIZER FOR SELF-DEFENSE}

The present invention relates to a portable escaping gas nebulizer for portable self-contained, and relates to a self-extinguishing gas nebulizer for escaping gas sprayed by the spraying machine.

In general, the tear gas sprayer is manufactured to be sized to be held in one hand to be portable, and when the lid is opened and the spray button of the nozzle is pressed, the built-in tear gas is sprayed.

Attached Figure 1 is a side cross-sectional view showing the configuration of such a common tear gas atomizer, as shown in the general tear gas atomizer, the gas reservoir (10) in which the tear gas is stored, and is fastened to the gas reservoir (10) It is divided into injection holes 20 through which the tear gas is injected by the pressurizing operation, and the gas reservoir 10 is built in the case 12 to prevent damage, and a lid 15 to prevent malfunctions on the upper part of the injection holes 20. ) Is combined.

Here, the injection hole 20 is fastened to the gas reservoir 10 by a fixing cap 24 of the lower end screwed with the gas reservoir 10 as shown.

When the tear gas atomizer opens the lid 15 and presses the injection button 22 of the injection hole 20, the pressure pump 26 is pumped to supply the tear gas of the gas reservoir 10 to the gas supply tube 28. This tear gas is supplied to the gas discharge path 22a formed inside the injection button 22 by the pumping pressure.

And the tear gas is injected through the injection hole 32 of the cylindrical nozzle tip 30 is inserted into the nozzle tip fixing groove 22b passing through the gas discharge path (22a).

At this time, the gas discharge passage (22a) is formed in the center of the nozzle tip fixing groove (22b) as shown to be in direct communication with the injection hole (32).

However, such a common tear gas atomizer has a problem in that the pumping pressure of the pressure pump 26 is too weak to shorten the range, and the injected tear gas is spread to the surroundings.

In order to solve this problem, the pumping pressure can be enhanced by employing a pressure pump 26 manufactured larger, but when the pressure pump 26 is employed, the gas reservoir 10 must be relatively larger. There is a disadvantage, such that when the gas reservoir 10 is large there is a disadvantage that the portability of the sprayer is lowered.

Of course, unlike this, the pumping pressure may be improved by injecting a compressed gas, such as a freon gas, into the interior of the gas reservoir 10, but in this case, it is necessary to obtain permission from the police or related authorities due to the danger or hazard of the compressed gas. In addition to the inconvenience, there is also a problem that leads to an increase in manufacturing costs due to the injection of compressed gas.

In addition, the above-described general tear gas sprayer can not check the nozzle tip 30 at night, so when the nozzle tip 30 does not check the state toward the user and presses the injection button 22, it is determined to the culprit such as molester or strength. The tear gas is not sprayed, but rather, the tear gas is sprayed to the user.

In addition, there is a problem in that the gas reservoir 10 is built in the case 12 so that the remaining amount of the tear gas cannot be confirmed.

On the other hand, reference numeral 33 is a locking projection formed on the tip side of the outer peripheral surface of the nozzle tip 30, 23 is a projection locking groove formed in the nozzle tip fixing groove 22b of the injection button 22, nozzle tip 30 is The locking projection 33 and the projection locking groove 23 are fixed to the nozzle tip fixing groove 22b.

The present invention has been devised to solve the conventional problems as described above, by changing the nozzle tip structure of the injection hole can not only extend the firing range of the spraying gas to be sprayed, but also the spraying gas is not spread The purpose is to provide a self-protecting tear gas atomizer for hitting only.

1 is a side cross-sectional view showing the configuration of a typical tear gas sprayer,

2 is a perspective view showing a tear gas sprayer according to the present invention;

Figure 3 is a side cross-sectional view showing the configuration of the tear gas sprayer shown in FIG.

4 is a perspective view of a portion of the nozzle tip shown in FIG. 2;

5 is a rear view of the nozzle tip shown in FIG.

6 is a rear view of the nozzle tip according to another embodiment of the tear gas sprayer according to the present invention;

7 is a rear view of the nozzle tip according to another embodiment of the tear gas sprayer according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: gas reservoir 12: case

20: injection hole 22: injection button

22b: nozzle tip fixing groove 23: projection locking groove

30: nozzle tip 32: injection hole

33: locking projection 100: opening

120: door 300: gas induction groove

350: gas compression groove C: coagulation chamber

G: gap

The purpose of the present invention as described above, the normal pressurized pumping injection port 20 is fastened to the tear gas storage gas reservoir 10 having a case 12 by the lower fixing cap 24, the nozzle tip 30 When the injection button 22 of the injection hole 20 is inserted and fixed, the tear gas of the gas reservoir 10 is pumped through the gas supply tube 28 by the pumping action of the pressure pump 26, and the injection button 22. It is supplied to the gas discharge passage (22a) formed in the interior of the injection hole 32 of the nozzle tip (30); The nozzle tip 30 is inserted into the nozzle tip insertion groove 22b of the injection button 22 so that the locking projection 33 formed on the outer circumferential surface thereof has a projection locking groove 23 formed inside the nozzle tip insertion groove 22b. In the tear gas atomizer is fixed to the injection button 22, the gas discharge path (22a) is formed so as to pass through one side of the nozzle tip fixing groove (22b) of the injection button (22); On the inner circumferential surface of the nozzle tip 30, at least one gas guide groove 300, which guides the tear gas supplied from the gas discharge path 22a, to the injection hole 32, from the rear end thereof to the injection hole 32. Formed; The locking protrusion 33 is formed at the middle of the nozzle tip 30 so that the tip of the nozzle tip 30 protrudes from the injection button 22 and is inserted and fixed, and the nozzle tip 30 is formed by the protrusion of the nozzle tip 30. A gap G is formed between the 30 and the gas discharge passage 22a to supply the gas induction groove 300 while the tear gas circulates, and the injection hole 32 and the injection button 22 of the nozzle tip 30 are formed. It is achieved by the self-tear gas atomizer for self-defense gas characterized in that the condensation chamber (C) is formed between the side walls of the c) is formed by the tear gas is agglomerated.

Hereinafter, with reference to the accompanying drawings illustrating a self-protecting tear gas atomizer according to the present invention is as follows, the same components and components having the same technical spirit and the same configuration as the prior art described in the description will be described with the same reference numerals. .

2 is a perspective view showing a tear gas sprayer according to the present invention, and FIG. 3 is a side cross-sectional view showing the configuration of the tear gas sprayer shown in FIG. 2, and FIG. 4 is a part of the nozzle tip shown in FIG. 2. 5 is a perspective view cut away, Figure 5 is a rear view of the nozzle tip shown in FIG.

As shown, a self-protecting tear gas atomizer according to the present invention, a normal pressurized pumping injection hole 20 is fastened by a fixed cap 24 to a lower gas storage container 10 having a case 12. When the lid 15 is opened and the injection button 22 of the injection hole 20 to which the nozzle tip 30 is inserted is repeatedly pressed, the tear gas of the gas reservoir 10 is pumped by the pumping action of the pressure pump 26. Through the gas supply tube 28, it is supplied to the gas discharge path (22a) formed inside the injection button 22 is configured to be injected into the injection hole 32 of the nozzle tip (30).

And, the nozzle tip 30 is inserted into the nozzle tip insertion groove 22b of the injection button 22, the locking projection 33 formed on the outer circumferential surface of the projection locking groove (b) formed inside the nozzle tip insertion groove 22b ( By combining with 23), it was configured to be fixed to the injection button (22).

In addition, the gas discharge passage (22a) is formed to penetrate through one side of the nozzle tip fixing groove (22b) of the injection button 22, as shown in Figure 3, the inner peripheral surface of the nozzle tip 30 in Figures 3 to 5 As shown, at least one gas induction groove 300 for injecting the tear gas supplied from the gas discharge passage 22a connected to the pressure pump 26 to the injection hole 32 is injected from the rear end of the injection hole 32. Formed to.

At this time, the gas discharge path 22a is not formed at the center of the nozzle tip fixing groove 22b as in the prior art, and the reason why it is formed at one side of the nozzle tip fixing groove 22b is that the tear gas is formed through the gas guide groove 300. To supply

Meanwhile, as shown in FIGS. 3 to 5, the gas guide grooves 300 are formed in three so as to face each other in three directions with equal intervals along the inner circumferential surface of the nozzle tip 30.

In addition, the locking projection 33 formed on the nozzle tip 30 is formed in the middle portion (see Fig. 3) of the nozzle tip 30, unlike the conventional, so that the nozzle tip 30 is the nozzle of the injection button 22 When inserted into the tip insertion groove 22b, and the engaging projection 33 is engaged with the projection engaging groove 23 formed in the nozzle tip insertion groove 22b, the tip of the nozzle tip 30 is shown in FIG. As is protruded from the injection button 22 is fixed.

In this way, when the nozzle tip 30 protrudes from the injection button 22, the gas induction groove 300 while the tear gas circulates between the nozzle tip 30 and the gas discharge passage 22a as shown in FIG. A gap G to be supplied is formed, and an agglomeration chamber C is formed between the injection hole 32 of the nozzle tip 30 and the side wall of the injection button 22 to aggregate and compress the tear gas.

Of course, the locking projection 33 of the nozzle tip 30 may be formed on the rear side instead of the middle portion of the nozzle tip 30. In this case, the gap G and the coagulation chamber C are expanded more. .

The tear gas atomizer according to the present invention configured as described above, the pressure pump 26 is pumped by repeatedly pressing the injection button 22, the tear gas in the gas discharge path 22a formed in the injection button 22 as described above Is supplied, and the supplied tear gas is agglomerated in the coagulation chamber C through the gas guide groove 300 while circulating in the gap G between the nozzle tip 30 and the gas discharge passage 22a, and then pumped. The pressure is injected into the injection hole 32 of the nozzle tip 30.

At this time, the tear gas is dispersed into the gas induction groove 300 in the gap G, and the pressure increases by the width of the gas induction groove 300 which is relatively narrower than the gap G space, thereby increasing the aggregation chamber C at a high speed. Supplied to.

The tear gas coagulated in the coagulation chamber C at high speed is compressed while gathered in the coagulation chamber C by the supply of the tear gas by the continuous pumping operation, and the injection force of the tear gas is amplified by this compression force.

Of course, the tear gas in the agglomeration chamber C is compressed because the amount of supply through the gas guide groove 300 is greater than the amount of injection through the injection hole 32.

Therefore, the ejected tear gas is enhanced by the amplification of the injection force, so that the straightness is not diffused to the surroundings, but is injected farther than before.

That is, the injected tear gas does not diffuse to the periphery because it is going to advance only as the straightness is enhanced.

On the other hand, the gas guide groove 300 may be configured to form a spiral from the injection hole 32 of the nozzle tip 30 to the side wall of the nozzle tip 30, as shown in FIGS.

Then, since the tear gas compressed in the coagulation chamber C is supplied to the injection hole 32 while vortexing in this spiral portion, the range of the tear gas can be further extended by the rotational force generated during the vortex.

In addition, the back of the nozzle tip 30 may be formed by forming a gas compression groove 350 having a predetermined size centering on the injection hole 32 as shown in FIGS. 4 and 5.

Then, since the tear gas coagulated in the coagulation chamber C is compressed once again in the gas compression groove 350 and then supplied to the injection hole 32, the firing force by the compressive force can be further extended. have.

As shown in FIG. 4 and FIG. 5, the gas compression groove 350 has a triangular shape with each gas induction groove 300 as a vertex. It is desirable to form.

On the other hand, in the present invention by coloring the light emitting pigment on the surface of the nozzle tip 30, it was configured to check the position of the nozzle tip 30 at night.

Such a luminous pigment may be applied to any one of a luminous pigment that accumulates light during the day and emits at night, a luminous pigment that emits light itself, or a reflective pigment that reflects even weak light. Light-emitting pigments are also applicable.

Then, the nozzle tip 30 can be checked even at night, so that the injection direction can be easily recognized, and even when the molars appear suddenly, the tear gas can be accurately fired at the molars.

On the other hand, the present invention is formed of a transparent material so that the inside of the gas reservoir 10 is transparent, and the opening 100 is formed on one side of the case 12, the residual amount of the tear gas stored in the gas reservoir 10 It was configured to check through the opening (100).

Therefore, since the residual amount of tear gas can be checked at any time, it is possible to prevent the mistake of carrying the sprayer without knowing that the tear gas is completely exhausted.

At this time, the opening 100 further includes a sliding door 120 inward so that the opening 100 is expressed only when checking the remaining amount of the tear gas.

The sliding door 120 is inserted and installed between the gas reservoir 10 and the case 12, as shown in Figure 2, thereby the door 120 is opened and closed while sliding to the side.

Therefore, when the door 120 is opened, the tear gas remaining amount of the gas reservoir 10 can be checked through the opening 100. When the door 120 is closed, the opening 100 is concealed to close the aesthetics of the case 12. I can keep it.

Here, an enlarged view of a portion of the circle shown in FIG. 2 shows a state in which the door 120 is closed, and a portion indicated by broken lines prevents the door 120 from being separated from the case 12. The part (border part) of the door 120 inserted in the inside is shown.

On the other hand, Figure 6 is a rear view of the nozzle tip according to another embodiment of the tear gas sprayer according to the present invention, Figure 7 is a rear view of the nozzle tip according to another embodiment of the tear gas sprayer according to the present invention.

FIG. 6 shows the coagulation chamber C removed from the nozzle tip 30 having the three gas guide grooves 300 shown in FIGS. 3 to 5, and FIG. 7 shows the gas guide groove ( 300 is formed in two so as to face each other on the inner peripheral surface of the nozzle tip (30).

Therefore, the nozzle tip 30 may be variously manufactured as shown in FIG. 5 or 6 and 7.

On the other hand, the tear gas spray machine for self-defense according to the present invention shown in Figures 2 to 4 illustrate that the overall shape is manufactured in a cylindrical shape, but may be manufactured in a rectangular rather than cylindrical to prevent the sprayer from rolling.

The above-described embodiments are merely illustrative of preferred embodiments of the present invention, and the scope of application of the present invention is not limited thereto, and may be appropriately changed within the scope of the same idea.

Therefore, the shape and structure of each component shown in the embodiment of the present invention can be carried out by modifying, it is natural that the modification of the shape and structure belong to the utility model registration claims of the present invention attached.

The tear gas sprayer for self-defense according to the present invention, the injection force of the tear gas injected by the gas guide groove formed in the nozzle tip, the coagulation chamber between the nozzle tip and the injection button side wall, and the gas compression groove formed in the nozzle tip. Since it can be strengthened, not only can the range of the tear gas be improved, but the tear gas injected by the enhanced injection force is hit by the target without being diffused to the surroundings.

In addition, the range can be improved to target criminals such as molars and strength even at a long distance, and since the tear gas is injected without being diffused, a large amount of tear gas can be sprayed onto the molars.

In addition, since the nozzle tip emits light, it is possible to easily check the position of the nozzle tip at night, thereby preventing the tear gas from being sprayed to the user, and also having the effect of accurately aiming the tear gas at the molars.

In addition, since the tear gas remaining amount of the gas reservoir can be checked at any time through the opening of the case, there is also an effect that can always check the remaining amount of tear gas in case of emergency.

Claims (7)

A normal pressurized pumping injection hole 20 is fastened to a tear gas storage gas storage container 10 having a case 12 by a lower fixing cap 24 so that the nozzle tip 30 is inserted and fixed. When the injection button 22 of the pressurization button is pressed, the tear gas of the gas reservoir 10 is pumped by the pressure pump 26 through the gas supply tube 28, and the gas discharge path formed inside the injection button 22 ( 22a) is injected into the injection hole 32 of the nozzle tip 30; The nozzle tip 30 is inserted into the nozzle tip insertion groove 22b of the injection button 22 so that the locking projection 33 formed on the outer circumferential surface thereof has a projection locking groove 23 formed inside the nozzle tip insertion groove 22b. In the tear gas atomizer is fixed to the injection button 22 by being combined with, The gas discharge passage (22a) is formed to pass through one side of the nozzle tip fixing groove (22b) of the injection button 22; On the inner circumferential surface of the nozzle tip 30, at least one gas guide groove 300, which guides the tear gas supplied from the gas discharge path 22a, to the injection hole 32, from the rear end thereof to the injection hole 32. Formed; The locking protrusion 33 is formed at the middle of the nozzle tip 30 so that the tip of the nozzle tip 30 protrudes from the injection button 22 and is inserted and fixed, and the nozzle tip 30 is formed by the protrusion of the nozzle tip 30. A gap G is formed between the 30 and the gas discharge passage 22a to supply the gas induction groove 300 while the tear gas circulates, and the injection hole 32 and the injection button 22 of the nozzle tip 30 are formed. A tear gas sprayer for self-defense, characterized in that the coagulation chamber (C) is formed between the side walls of the) to form the agglomerated tear gas. The method of claim 1, The gas induction groove 300 is a tear gas sprayer for self-defense, characterized in that formed by forming two to face each other on the inner peripheral surface of the nozzle tip (30). The method of claim 1, The gas induction groove 300 is a tear gas sprayer for self-defense characterized in that formed by forming three to face each other in the same direction along the inner circumferential surface of the nozzle tip (30). The method of claim 1, A gas compression groove 350 having a predetermined size is formed on the rear surface of the nozzle tip 30 so that the gas agglomerated in the agglomeration chamber C is the gas compression groove 350. Once again in the pressurized tear gas atomizer, characterized in that configured to be supplied to the injection hole (32). The method according to any one of claims 1 to 4, The gas guide groove 22a is formed to form a spiral from the injection hole 32 of the nozzle tip 30 to the side wall of the nozzle tip 30, so that the tear gas supplied to the injection hole 32 vortexes in this spiral portion. It is supplied by, the tear gas sprayer for self-defense characterized in that configured to extend the range of the tear gas by the rotational force generated during the vortex. The method of claim 1, The tear gas sprayer for self-defense, characterized in that the surface of the nozzle tip 30 is configured to color the light-emitting pigment, so that the position of the nozzle tip 30 can be confirmed at night. The method of claim 1, The gas reservoir 10 is formed of a transparent material so as to see through the inside, and the opening 100 is formed on one side of the case 12, the remaining amount of the tear gas stored in the gas reservoir 10 is the opening 100 ) To verify; The opening 100 is a tear gas sprayer for self-defense, characterized in that it further comprises a sliding door 120 on the inside so that only when the residual amount of tear gas is confirmed.