JPH11193999A - Imitation cannonball firing cylinder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To securely fire a cannonball part toward a culprit or an object even from a mobile vehicle regardless of individual deference such as physical strength by utilizing propulsive force being generated by a compression gas for discharging the cannonball part. SOLUTION: A cylinder is provided with a cylindrical cannonball part 5 with an imitation cannonball 52, a cannon 1 for accommodating the cannonball part 5, and a holder part 2 being connected to the cannon 1. The holder part 2 accommodates a gas feed container V. When an operation part 4 is operated for injecting a compression gas to the cannon 1 through a gas injection port 25 from a gas-supplying/sending container V, the cannonball part 5 receives the pressure of the compression gas and is powerfully discharged from the cannon 1. Generally, the cannonball part 5 is retained in the cannon 1 by a cannonball part retention means 6.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a simulated shell launcher,
More specifically, the present invention relates to a simulated shell launcher used for coloring and marking an offender or an object provided for the offense during a crime.

[0002]

2. Description of the Related Art Conventionally, in the case of crimes that rob money from financial institutions such as banks and post offices and fast food stores, so-called colored balls are thrown at criminals and objects and colored liquids are adhered to them. Investigation methods have been performed to make it easier to identify a criminal or an object based on the presence or color of the colored liquid.

[0003]

However, according to the conventional method, even if a person with weak strength such as a woman or girl throws a color ball at a criminal or an object, or throws it at a moving vehicle, the person struggles. However, there has been a problem that the color ball often does not reach the criminal or the object or does not hit them well.

The present invention has been made in view of the above problems, and is based on the fact that a simulated ammunition equivalent to a conventional color ball is fired by using a propulsive force generated by a compressed gas. It is an object of the present invention to provide a simulated shell which can reliably fire a simulated ammunition impregnated with a coloring liquid, irrespective of individual differences such as from a moving vehicle and aiming at a criminal or an object. And

[0005] It is another object of the present invention to provide a simulated shell launching tube in which the hit rate of a simulated shell for a criminal or an object is increased.

[0006]

According to a first aspect of the present invention, there is provided a simulated projectile launching tube comprising: a tubular projectile portion having at least a closed front end; and a projectile opening formed at the front end of the tube. The barrel portion, which is hermetically shielded by mounting the shell portion and the inner space of the cylindrical body is formed in a pressure chamber, and the shell portion attached to the barrel portion, the barrel portion when the internal pressure of the barrel portion is normal pressure. And holding means for releasing the holding state when the internal pressure of the barrel increases due to the compressed gas injected into the internal space of the barrel. In the simulated shell shell thus configured, the shell is attached to the barrel, and when the shell is held by the shell holding means by the shell holding means, the compressed gas is injected into the barrel, The internal pressure of the gun barrel rises, the engagement by the shell holding means is released, and the holding state of the shell with respect to the gun is released, so that the shell is released from the gun.

According to a second aspect of the present invention, there is provided a simulated shell in which the front end is closed and the rear end is open and a simulated shell is provided at the front end, and a barrel for housing the shell. Part and the shell part housed in the barrel part,
Shell part holding means for holding the shell part when the internal pressure of the shell part is at normal pressure and releasing the holding state when the internal pressure of the shell part rises due to the injected compressed gas. It is. In the simulated shell shell thus configured, the shell is attached to the barrel, and when the shell is held by the shell holding means by the shell holding means, the compressed gas is injected into the barrel, Since the internal pressure of the shell portion accommodated in the barrel portion increases, the engagement by the shell portion holding means is released, and the holding state of the shell portion with respect to the barrel portion is released, so that the shell portion is discharged from the barrel portion.

Further, according to a third aspect of the present invention, there is provided a simulated shell in which the front end is closed and the rear end is open, and a simulated shell is provided at the front end, and a barrel for accommodating the shell. Part, a holder part which is connected to the rear end of the barrel part and accommodates a gas supply container filled with compressed gas,
The gas inlet port for communicating the nozzle of the gas supply container housed in the holder and the barrel section, and the shell section housed in the barrel section, when the internal pressure of the shell section is normal pressure A shell portion holding means for holding the shell portion and releasing the holding state when the internal pressure of the shell portion is increased by the compressed gas injected through the gas inlet portion; and And an operation unit for opening and closing the on-off valve provided on the nozzle. In the simulated projectile shell thus configured, the gas supply container is provided in the holder, the shell is provided in the barrel,
When the operating section is operated to open and close the nozzle of the gas supply container while the shell portion is held by the gun barrel portion while holding the shell portion, the compressed gas filled in the gas supply container is released. It is injected into the barrel through the nozzle and gas inlet. When compressed gas is injected into the barrel,
The internal pressure of the shell section housed in the barrel section increases, the engagement by the shell section holding means is released, and the holding state of the shell section with respect to the barrel section is released, so that the shell section is released from the barrel section. .

According to a fourth aspect of the present invention, there is provided a simulated shell launcher according to the present invention, wherein the shell holding means is provided separately for the shell and the barrel, and when the internal pressure of the barrel is normal pressure. The engaging portion and the engaged portion which hold the shell portion in the barrel portion and release the holding state when the internal pressure of the barrel portion is increased by the compressed gas injected into the internal space of the barrel portion. And the configuration according to claim 1. In the simulated shell launch tube thus configured, the engagement by the shell holding means is not released until the internal pressure of the barrel due to the injection of the compressed gas into the gun rises to a certain pressure, and the internal pressure of the gun is constant. Only when the pressure rises to the pressure, the engagement by the shell holding means is released and the holding state of the shell with respect to the barrel is released, so that the shell is discharged from the barrel at a constant pressure. Therefore, the shell portion is more powerfully and reliably discharged than the barrel portion.

According to a fifth aspect of the present invention, there is provided a simulated shell launching tube wherein the shell holding means is provided separately for the shell and the barrel, and when the internal pressure of the shell is normal pressure. 3. An engaging part and an engaged part which are released from the holding state when the internal pressure of the shell part is increased by the compressed gas which is held in the barrel part and injected by the compressed gas. 3 is constituted. In the simulated projectile shell thus constructed, the engagement by the projectile holding means is not released until the internal pressure of the projectile due to the injection of the compressed gas into the barrel rises to a certain pressure, and the internal pressure of the projectile is constant. Only when the pressure rises to the pressure, the engagement by the shell holding means is released and the holding state of the shell with respect to the barrel is released, so that the shell is discharged from the barrel at a constant pressure. Therefore, the shell portion is more powerfully and reliably discharged than the barrel portion.

According to a sixth aspect of the present invention, there is provided the simulated projectile launcher according to the first, second, third, fourth, or fourth aspect, wherein the simulated projectile is formed by impregnating a flexible substance with a coloring liquid. According to a fifth aspect of the present invention, there is provided a configuration. In the simulated artillery launching cylinder configured in this way, there is no danger of the simulated artillery shell being fired hitting the criminal or the target when they hit the criminal or the target, and the criminal or the target is determined by the color of the colored liquid attached. Easy to identify.

[0012]

FIG. 1 is a longitudinal sectional side view of a simulated projectile launcher according to the present invention, and FIG. 2 is an enlarged sectional view of a main part of FIG. The barrel portion 1 of the simulated shell in the figure is a cylindrical body,
The front end opening is formed as a shell firing port 1A.
A holder 2 is connected to the rear end of the barrel 1. That is, as shown in an enlarged view in FIG. 2, the holder 2 is provided with the female screw 22 provided at the front end thereof, and
It is connected to the rear end of the barrel 1 by screwing it into a male screw 12 formed on the outer surface of the rear end. A partition wall 23 is provided at the front end of the holder 2, and a connection port 24 protruding rearward from the partition wall 23 is provided with the connection port 24 and the partition wall. 23, a gas injection port 25 is formed.
At the rear end of the connection port 24, a recess 26 into which a nozzle N of a gas supply container V described later is inserted is provided.

The gas supply container V has a cylindrical pressure vessel filled with a compressed gas. The nozzle N provided in the gas supply container V is retractable and is always urged in the protruding direction. The nozzle N is provided with an on-off valve. When the nozzle N is located at the protruding position, the on-off valve is closed to prevent the discharge of the compressed gas from the nozzle N, and the nozzle N is pushed in. At times, the on-off valve is opened and the compressed gas is discharged from the nozzle N. Since such a gas supply container itself is publicly known, a specific configuration of the on-off valve and the like are not illustrated.

The gas supply container V is accommodated and held in a cylindrical adapter 3, and is inserted into the holder 2 together with the adapter 3 by inserting the adapter 3 from the rear end opening 27 of the holder 2. The nozzle N of the gas supply container V accommodated in the holder 2 in this manner is
As shown in FIG. 1, it is fitted into the recess 26 of the connection port 24 described above.

An operation unit 4 includes a push button 41 and a holder 42 for holding the push button 41 in the holder 2.
And a spring 43 disposed in the holder 42 and constantly biasing the push button 41 in the protruding direction. The push button 41 is inserted into the opening 28 formed in the holder 2 and the opening 31 formed in the adapter 3, and the inclined surface 44 provided on the push button 41 is inserted into the opening 31 of the adapter 3. Are opposed to the opening edge 32. Therefore, when the push button 41 is pushed in against the bias of the spring 43, the inclined surface 44 pushes the opening edge 32 of the opening 31 of the adapter 3 to move the adapter 3 forward together with the gas feeding container V accommodated therein. Push in. Therefore, the nozzle N is pushed relatively to the gas supply container V to open the above-mentioned on-off valve, and the compressed gas filled in the gas supply container V passes through the nozzle N and the gas inlet 25 to the barrel 1. Is injected into.

The gun barrel 1 accommodates a shell 5. The shell part 5 has a flexible simulated shell 52 impregnated with a coloring liquid at the front end of a cylindrical body 51 having a front end closed and a rear end opened.
Is held. As shown in detail in FIG.
1 has an engaged portion 61 having an uneven shape inside the opened rear end, and the engaged portion 61 is located outside the boss 29 protruding toward the front end of the holder 2. Is engaged with the concave-convex engaging portion 62 formed in the first portion. Therefore, when a large force is applied to the shell portion 5 forward, the engaged portion 61 gets over the engaging portion 62 of the holder portion 2 and the engagement between the engaging portion 62 and the engaged portion 61 is released. Is done. Therefore, at normal pressure when the compressed gas of the gas supply container V is not injected into the barrel portion 1, the engaging portion 62 and the engaged portion 61 are engaged so that the shell portion 5 does not fall into the barrel portion 1. On the other hand, when the internal pressure of the shell portion 5 increases when the compressed gas of the gas supply container V is injected into the barrel portion 1 and the internal pressure of the shell portion 5 rises above a certain value, the holding state is maintained. The release is released, and a force (hereinafter referred to as “relaxation pressure”) that vigorously pushes the shell 5 forward. The barrel 51 of the shell 5 is formed of an elastic synthetic resin such as polyethylene resin, and the outer surface of the rear end of the barrel 51 of the shell 5 housed in the barrel 1 and the barrel A predetermined gap S is secured between the inner surface of the portion 1 and the inner surface. For this reason, when a large force is applied to the shell 5 forward,
The cylinder 51 has elasticity, and the cylinder 51
Since the diameter of the rear end of the cylindrical body 51 is secured by the gap S, the rear end of the cylindrical body 51 expands in diameter and its engaged portion 61
Can get over the engaging portion 62 of the holder portion 2 and the engagement between the engaging portion 62 and the engaged portion 61 can be reliably and smoothly released.

Here, the engaging portion 62 and the engaged portion 61 hold the shell 5 accommodated in the barrel 1 on the barrel 1 when the internal pressure of the shell 5 is normal pressure. And, when the internal pressure of the cylindrical body 51 of the shell part 5 is increased by the compressed gas injected through the gas inlet 25, the shell part holding means 6 is released. The shell portion holding means 6 exhibiting such an effect is not limited to the combination of the engaging portion 62 and the engaged portion 61 shown in FIG.
Means to join the shell part 1 to the shell part 5 with an adhesive sheet that can be torn when a certain pressure is applied to the shell part 5, or the cylinder 51 of the shell part 5 and the barrel part 1 to the shell part 5. It is also possible to employ a means such as joining with an adhesive tape which is peeled off when a certain ejection pressure is applied.

In the above-described simulated projectile shell, the barrel 1, the holder 2, the adapter 3 and the like can be inexpensively formed of a synthetic resin such as polyethylene resin. In addition, the simulated shell 52 is formed by impregnating a porous flexible substance such as a flexible synthetic resin foam (for example, sponge) with a predetermined coloring liquid. Further, it is desirable that the above-mentioned shell part holding means 6 can connect the cylinder 51 of the shell part 5 and the boss part 29 of the holder part 2 as tightly as possible.

In the simulated projectile shell constructed as described above, the gas supply container V is accommodated in the holder 2 together with the adapter 3 and the shell 5 is accommodated in the barrel 1 as shown in FIG. Further, the shell portion 5 is held by the barrel portion 1 by the shell portion holding means 6 formed by the engaging portion 62 and the engaged portion 61. When the shell portion 5 is held on the barrel portion 1 by the shell portion holding means 6 as described above, the situation in which the shell portion 5 comes off from the barrel portion 1 when carrying the simulated shell shell is not caused.

In this simulated shell launching cylinder, while the shell part 5 is held by the gun barrel part 1 by the shell part holding means 6, the push button 41 of the operation part 4 is pushed by the finger of the hand as described above. When the gas supply container V is pushed forward, the open / close valve of the nozzle N is opened, and the compressed gas filled in the gas supply container V is injected into the barrel 1 through the nozzle N and the gas injection port 25. You. Thus the barrel 1
When the compressed gas is injected into the barrel 1, the internal pressure of the barrel 51 of the shell 5 housed in the barrel 1 rises, and the internal pressure causes the engagement by the shell holding means 6 to be released, so that the barrel 1
Is released from the holding state of the shell portion 5. As a result, the shell portion 5 is vigorously discharged from the barrel portion 1 by the ejection pressure applied to the shell portion 5. As described above, when the shell portion 5 is released from the barrel portion 1, the cylindrical barrel portion 1 guides the cylinder body 51 of the shell portion 5 straight forward, so that the discharge direction of the shell portion 5 is Determined relatively accurately by orientation. This helps to increase the hit rate of the simulated cannonball 52 against a criminal or an object.

Further, since the simulated shell 52 of the shell section 5 is flexible, there is no danger that the simulated shell 52 of the shell section 5 that has been released hits a criminal or an object and damages them. Therefore, it is useful in the subsequent investigation of the criminal or the object. Further, if a soft material such as a sponge is used for the simulated shell 52, there is an advantage that the simulated shell 52 is not damaged by the impact when the shell part 5 is released.

In the simulated shell launching tube of this embodiment, the barrel 1 for accommodating the shell 5 and the holder 2 are screwed and connected by a male screw 12 and a female screw 22. For this reason, if the one in which the shell part 5 is accommodated in the barrel part 1 is used as a disposable unit, the barrel part 1 in which the shell part 5 is accommodated can be screwed and connected to the holder part 2 to assemble a simulated shell launch tube. By doing so, there is an advantage that a situation that can occur when the shell section 5 is handled alone, for example, a situation in which the coloring liquid of the simulated shell 52 adheres to hands and clothes and stains them, is eliminated. .

Various gases such as carbon dioxide gas, nitrogen gas, liquefied petroleum gas, and chlorofluorocarbon gas can be used as the compressed gas used to fill the gas supply container V.
In consideration of the special characteristics of the simulated shell in which the use environment is not specified, it is desirable to use a gas that does not cause explosion or combustion even in a place where there is fire and that has little risk of damaging the global environment. In this sense, liquefied non-polluting chlorofluorocarbon (eg, HFC 1
34a) is desirable. Moreover, since the liquefied pollution-free chlorofluorocarbon has a pressure of about 3.5 kg / cm ² (effective pressure according to the method of use), using the gas supply container V filled with this liquefied pollution-free chlorofluorocarbon does not prevent the use of shells even when used When the internal pressure of the cylinder 51 of the section 5 does not rise to 3.5 kg / cm ² or more, if the pressure is at such a level, the barrel 51 of the barrel section 1 and the cylinder 51 of the shell section 5 are made of synthetic resin such as inexpensive polyethylene resin. There is an advantage that it can be formed thin with resin. Further, by setting the ejection pressure to be equal to or less than the pressure resistance of the cylinder 51, even if the pressure increases, the safety valve operates to prevent the cylinder from being damaged. On the other hand, when the pressure is intentionally set to a high value to perform a modification such as power-up, the cylinder body 51 is damaged, so that malicious modification can be prevented.

FIG. 3 shows another embodiment of the simulated shell launcher according to the present invention. The difference between the simulated shell launcher of this embodiment and that described with reference to FIG.
Is formed integrally with the holder 2, and an operating unit 4 for opening and closing an on-off valve provided in the nozzle N of the gas supply container V is provided with a pressing button provided at the rear end of the holder 2. 45, the point that the gas supply container V is accommodated in the holder part 2 without using the adapter 3, and the like. The other points are the same as those described with reference to FIGS. 1 and 2, and for the sake of simplicity, the same or corresponding parts will be denoted by the same reference characters and detailed description will be omitted.

FIGS. 4 and 5 show still another embodiment of the simulated shell launcher according to the present invention. In the simulated shell shell of this embodiment, the barrel portion 1 is a cylindrical body, a shell opening 1A is provided at the front end, and the rear end opening is a partition wall 2
3 is formed to shield the rear end of the barrel 1. This partition wall portion 23 penetrates through the partition wall portion 23 and the partition wall portion 2
A gas injection port 25 protruding before and after 3 is formed. The difference from the simulated shell launcher described with reference to FIGS. 1 and 3 is that the mounting condition of the barrel 1 and the shell 5 is significantly different. That is, the shell portion 5 in FIG. 4 is airtightly fitted and housed in the barrel portion 1 like the simulated shell shell of FIGS. 1 and 3, and the cylinder 51 of the shell portion 5 has its axis. Direction, and has an uneven engaging portion 61 outside the open rear end, and the engaging portion 61 is formed in an uneven shape formed inside the barrel 1. The engaging portion 62 is engaged. The shell portion 5 is formed by integrally forming a cylinder 51 of the shell portion 5 and a simulated shell 52. At normal pressure when the compressed gas is not injected into the barrel 1, the engaging portion 62 and the engaged portion 61 are engaged so that the shell 5 is held so as not to fall into the barrel 1. On the other hand, when the internal pressure of the gun barrel 1 rises due to the injection of the compressed gas of the gas supply container V into the gun barrel 1, when the internal pressure exceeds a certain value, the shell holding means 6
Is released, and a force for pushing the shell portion 5 forward is applied. Therefore, the above-mentioned barrel section 1 is hermetically shielded from the shell opening 1A formed at the front end of the tubular body by mounting the tubular shell section 5 having the front end closed and the rear end opened. Is formed as a pressure chamber.

The shell portion 5 in FIG.
1 is formed to be short in the axial direction, and has an engaged portion 61 having an irregular shape inside the opened rear end. The engaged portion 61 is located near the shell opening 1 </ b> A of the barrel 1. Is engaged with a concave-convex engaging portion 62 formed on the outer side of the main body. The engagement between the barrel portion 1 and the shell portion 5 in FIG. 5 is performed on the outer surface of the barrel portion 1 as described above, and the simulated shell shell described with reference to FIGS. There is a great difference between the mounting state of the shell 1 and the shell part 5. By mounting the above-mentioned shell part 5 on the barrel part 1, the shell opening 1A formed at the front end of the cylinder is airtightly shielded, and the internal space 1B of the cylinder of the barrel part 1 is formed as a pressure chamber. When the compressed gas is not injected into the barrel 1 at normal pressure, the engaging portion 6
2 and the to-be-engaged portion 61 are engaged so that the shell portion 5 is held in the barrel portion 1 so as not to fall out, while the compressed gas of the gas supply container V is injected into the barrel portion 1 and the barrel portion When the internal pressure of the unit 1 increases, the shell holding unit 6 is released when the internal pressure becomes equal to or higher than a predetermined value, and the shell 5 jumps out vigorously forward.

In FIGS. 4 and 5, a holder for accommodating the gas supply container filled with the compressed gas described in FIGS. 1 and 3 or an on-off valve provided in the nozzle of the gas supply container Although an operation part for opening the opening is not shown and its explanation is omitted, it may be formed in the same manner as that described with reference to FIGS. 1, 2 and 3, or another structure such as a barrel A gas supply container filled with compressed gas is accommodated in the barrel of the barrel 1 without providing a holder or the like for accommodating the gas supply container behind the unit 1, and gas is supplied to the outside of the barrel of the barrel 1. An operation unit for opening and closing the on-off valve may be provided.

[0028]

The simulated projectile launcher according to the present invention uses the propulsive force generated by the compressed gas to release the projectile portion, so that the projectile can be extended far regardless of individual differences due to differences in arm strength and the like. It is possible to fly the part vigorously, and furthermore, the discharge direction of the shell part is determined to some extent accurately by the direction of the barrel part. Therefore, even if the user is a woman or a woman, or fired from a moving vehicle,
The likelihood of the shells hitting criminals and objects increases. For this reason, the simulated shell launching cylinder according to the present invention can effectively contribute to adopting an investigation method of marking and marking a criminal or an object.

In the case of using a simulated shell in which a flexible substance is impregnated with a coloring liquid, there is no danger that the simulated shell that has been fired hits a criminal or an object and damages them. Useful for interrogating objects.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional side view of an embodiment of a simulated shell launcher according to the present invention.

FIG. 2 is an enlarged sectional view of a main part of FIG.

FIG. 3 is a vertical sectional side view of another embodiment of the simulated projectile launcher according to the present invention.

FIG. 4 is a vertical sectional side view of still another embodiment of the simulated shell launcher according to the present invention.

FIG. 5 is a longitudinal sectional side view of still another embodiment of the simulated shell launcher according to the present invention.

[Explanation of symbols]

 V Gas feeding container N Nozzle 1 Gun barrel part 2 Holder part 4 Operation part 5 Shell part 6 Shell part holding means 25 Gas injection part 52 Simulated shell 61 Engaged part 62 Engagement part

Claims (6)

[Claims] At least a shell portion of a cylindrical body whose front end is closed, and a shell opening formed at the front end of the cylindrical body are hermetically shielded by mounting the shell portion, and the internal space of the cylindrical body is formed into a pressure chamber. The formed barrel portion and the shell portion mounted on the barrel portion are held by the barrel portion when the internal pressure of the barrel portion is normal pressure, and the compressed gas injected into the internal space of the barrel portion is used for the above-mentioned barrel portion. A simulated shell launching cylinder, comprising: a shell holding means for releasing the holding state when the internal pressure of the barrel rises. 2. A shell having a front end closed and a rear end opened and having a simulated ammunition at the front end, a barrel for accommodating the shell, and the shell contained in the barrel. A shell portion holding means for holding the shell portion when the internal pressure of the shell portion is normal pressure and releasing the holding state when the internal pressure of the shell portion is increased by the injected compressed gas. A simulated shell launcher characterized by having 3. A shell having a front end closed and a rear end opened and having a simulated ammunition at the front end, a barrel for storing the shell, and a rear end connected to the rear end of the barrel. A holder for accommodating the gas supply container filled with the compressed gas, a gas injection port for communicating the nozzle of the gas supply container accommodated in the holder with the barrel, and a housing for the barrel When the internal pressure of the shell portion is held at normal pressure, the shell portion is held in the barrel portion, and when the internal pressure of the shell portion rises due to the compressed gas injected through the gas inlet, the holding state is maintained. A simulated shell shell, comprising: a shell part holding means for canceling the operation; and an operating part for opening and closing an on-off valve provided in the nozzle of the gas supply container. 4. The shell portion holding means is provided separately for the shell portion and the barrel portion, and when the internal pressure of the barrel portion is normal pressure, holds the shell portion on the barrel portion and the barrel portion. 2. The simulated shell firing according to claim 1, wherein the simulated shell is formed by an engaging portion and an engaged portion that are released from the holding state when the internal pressure of the barrel portion is increased by the compressed gas injected into the internal space of the portion. Tube. 5. The shell portion holding means is provided separately for the shell portion and the barrel portion. When the internal pressure of the shell portion is normal pressure, the shell portion holding means is held by the gun portion and compressed by the injected gas. The simulated shell shell according to claim 2 or 3, wherein the simulated shell shell is formed by an engaging portion and an engaged portion that are released when the internal pressure of the shell portion increases. 6. The simulated artillery shell according to claim 1, wherein the flexible substance is impregnated with a coloring liquid.
Alternatively, the simulated shell launch cylinder according to claim 5.