KR102093831B1 - reaction force generator for the imitation firing - Google Patents

Abstract

A reaction force generator for simulation shooting to perform simulation training by using a real gun comprises: a simulation bolt carrier which allows the front end of a recoil spring to be inserted therethrough to be fixed thereon, and is coupled to a real gun to be slid towards the other end of the recoil spring; a simulation bolt which is slidably mounted in an accommodation groove in the simulation bolt carrier, and is slidable with the simulation bolt carrier; a simulation gas magazine provided with a discharge valve device therein to discharge compressed gas, and mounted on a real gun through a magazine coupling unit of a real gun; and a simulation firing pin which is mounted in a penetration groove in the simulation bolt to be slid in the longitudinal direction of the simulation bolt, and opens the discharge valve device by a strike of a hammer of a real gun. A reaction force is generated by directly sliding the simulation bolt carrier and the simulation bolt as one unit to the back of a real gun by gas discharged from the opened discharge valve device.

Description

Reaction force generator for the imitation firing}

The present invention relates to a reaction force generating device for simulated shooting for performing simulation training using a real gun, more specifically, a simulated bolt mounted on the real gun directly by gas discharged by a trigger operation of the real gun and The simulated bolt carrier assembly relates to a reaction force generating device for simulated shooting in which a reaction force is generated by sliding to the rear of the gun.

The term 'real gun' used in this specification should be interpreted to include a real fireable gun, as well as a simulated gun having substantially the same internal and external structure and operation as the real gun.

In order to perform training in the same situation as the actual situation during the training of the military base, the actual homicide-killing ammunition is not used, but the terrorist gun which has only the warhead removed from the actual ammunition is used for training purposes.It consists of a primer, a casing, and a propellant. have.

As described above, the terror bombs are loaded into the magazines and used in combination with the rifle, but when the trigger is operated, the ball hits the terror bomb detonator through the hammer to explode the propulsion charges, so you can feel the noise and reaction force.

However, even for a horror munition, the minimum safety distance must be secured, and the same caution is required for handling the horror munition. There is a hassle to do.

In addition, since the horror bomb is made of the same material as the real bullet, it is basically expensive to manufacture, and there is no difficulty in recovering the casing due to night training, and there is no fear of killing, causing light burns and trauma due to careless handling. There was a problem in that the fatigue of soldiers accumulated due to the need for frequent firearm import procedures, as the life of the firearm was reduced due to prevention training and firearm wear and corrosion.

In order to improve this problem, by using high-pressure gas rather than real or horror bombs, the reaction force generator for firearms for simulated shooting training to provide the noise and shock that occur during actual shooting, so that the same effect as actual shooting can be achieved. Has been published as a prior art.

Among them, Patent Document 1, which is a prior patent of the present applicant, discloses a reaction force generator for a fire machine for simulated shooting training, which is exemplified as being applicable to an M16 rifle. The reaction force generating device, as schematically shown in FIG. 7, while being slidably coupled to the presser receiving chamber of the real gun, simulates the presser 100 hitting the recoil spring while reversing by the gas pressure provided at the front end side; A simulated gas magazine (300) coupled to the magazine coupling portion of the real gun and providing gas pressure to the simulated pulley; And a filling cylinder which is connected to the simulated gas magazine 300 in a fixed manner and fluidly communicatively coupled to the front end side of the mock pulley 100 and filled with a gas having a predetermined capacity. It includes a mock key bundle 400 including a gas ejection valve that can open and close.

When the gas ejection valve is opened due to the hammer hit by the trigger operation of the igniter in the reaction force generating device, the gas stored in the filling cylinder is discharged toward the simulated key 100 to provide a driving force for moving backward. Grant.

In such a reaction force generating device, when the simulated gas magazine 300 is mounted on a real gun through a magazine coupling portion, the simulated gas magazine 300 has its own gas outlet valve, a gas supply nipple coupled to the simulated bolt assembly, and the like. It has a structure that is connected in fluid communication with the filling cylinder. Therefore, there is a possibility that the fluid always leaks from the fluid communication passage of this structure, that is, from the gas chamber in the simulated gas magazine 300 to the filling cylinder in the simulated key bundle.

On the other hand, while being fixed to the mock key 400, while supporting the mock key 400 in a state caught in the key receiving space, and moving the mock key by gas ejection (connected with the mock gas magazine 300) It is necessary to additional configuration, such as a fixed plate to prevent the flow of the mock bolt 400.

In addition, as shown in Figure 7, the simulated gas magazine 300 is a structure mounted toward the magazine engaging portion of the actual gun in a vertical upward direction from the bottom of the actual gun, if the depth of the engaging portion of the magazine engaging portion is sufficiently deep Although the possibility of gas leakage at the connection portion between the simulated gas magazine 300 and the simulated key bolt may be small, considering the fact that there is a significant difference in its structure or operation method depending on the type of the actual gun, it is surely a stable simulation. There is a problem that cannot be said to guarantee the combination of a gas magazine and a key bolt.

Moreover, the reaction force generating device according to the prior art of the above method uses a banana-shaped magazine like an AK47-based rifle, and due to the special shape of the magazine, the magazine has a structure in which the magazine is mounted in a rotating manner through the magazine coupling part of the actual gun. In particular, the possibility of gas leakage becomes high when applied to.

On the other hand, if the reaction force generating device for simulated shooting for performing simulation training using a real gun, there is a constraint that there should be no change in the specifications of the real gun, such as the appearance or total weight of the real gun. It is impossible to prevent such gas leakage through improvement such as changing the shape of the body portion of the firearm.

Republic of Korea Registered Patent Publication No. 10-1802427

The present invention has been devised to solve the problems in the prior art as described above, by using a high-pressure gas to generate a reaction force similar to the noise and shock generated during shooting, so that it can enjoy the same effect as the actual shot, It is an object of the present invention to provide a reaction force generating device for simulated shooting that can reduce the cost associated with the use of terror bombs.

In addition, the present invention does not install a gas storage magazine for storing high-pressure gas and a temporary filling space in fluid communication at all times in parts such as a bundle of bolts installed in a real gun, and by opening the discharge valve device of the gas storage magazine only when necessary By providing compressed gas for reaction force generation from the gas storage magazine directly, it prevents gas leakage in advance and provides a counter reaction force generator for simulated shooting that can significantly reduce the number of additional parts for the reaction force generator. Do something else.

In addition, the present invention replaces only bolts and bolt carrier combinations, balls, and magazines among the components of the real gun and allows the rest of the components of the real gun to be used as it is. Another object of the present invention is to provide a reaction force generator for simulated shooting.

The reaction force generating device for simulated shooting according to an embodiment of the present invention for achieving the above object is a reaction force generating device for simulated shooting for performing simulation training using a real gun, and is fixed by being inserted through the tip of the recoil spring A mock bolt carrier coupled to a real gun slidably toward the other end of the recoil spring; A simulated bolt slidably mounted in the receiving groove in the simulated bolt carrier and slidable with the simulated bolt carrier; The compressed gas is stored therein, and a simulated gas magazine coupled to the real gun through the magazine engaging portion of the real gun; And a simulated ball slidably mounted in the through groove in the simulated bolt along the longitudinal direction of the simulated bolt and opening the discharge valve device inside the simulated gas magazine by the hammer of the real gun. The reaction force is generated when the simulated bolt and the simulated bolt carrier are integrally slid toward the rear of the real gun by the gas discharged from the discharge valve device.

In the above embodiment, the simulated gas magazine is formed so that only one side of the upper end inserted into the real gun is projected upward, so as to be coupled in a rotational mounting manner through the magazine joint of the real gun, and the upper end protruding upward It is preferred that a discharge valve device is provided.

In addition, in the above embodiment, the discharge valve device includes a ball valve that is movably built on a gas discharge flow path to shield a gas outlet, and to open the gas outlet by sliding movement of the simulated ball; A ball spring providing an elastic force in a direction of shielding the gas outlet with respect to the ball valve in a state embedded in the discharge passage; A spring fixing pin for elastically deforming the ball spring; It is preferable to include a bushing that is fixed to the distal end of the discharge valve device and seats the ball valve in a fixed position while forming the gas outlet.

In addition, in the above embodiment, it is preferable that the simulated gas magazine is coupled through the magazine coupling portion of the real gun in such a way that the discharge valve device directly faces the front of the simulated bolt.

In addition, in the embodiment, the simulated gas gun is placed in the simulated ball so that the distal end of the simulated ball is located in the through groove of the simulated bolt so as not to interfere with the process of coupling the simulated gas magazine through the magazine coupling portion of the real gun. It is preferable that the ball providing the elastic force to the rear further comprises a rear support spring.

In addition, in the above embodiment, it is preferable that a gas receiving groove having a larger diameter than the through groove is continuously formed so that the gas discharged from the discharge valve device can be accommodated in front of the through groove in the simulated bolt.

In addition, in the embodiment, in order to prevent the simulated bolt from completely exiting the simulated bolt carrier, a bolt retaining pin inserted in a direction perpendicular to the length of the simulated bolt is provided in a groove formed in an outer wall surface of the simulated bolt. It is preferred to further include.

In addition, in the above embodiment, it is preferable that the simulated gas magazine includes a filling valve device for re-using compressed gas.

In addition, in the above embodiment, the compressed gas is preferably carbon dioxide (CO2) gas.

In addition, in the above embodiment, it is preferable that the real gun is an AK47 series real gun.

According to one embodiment of the present invention, by using a high pressure gas to generate a reaction force similar to the noise and shock generated during shooting, so that the same effect as the shooting can be enjoyed, and the cost of using a real or horror bomb can be reduced. have.

In addition, according to an embodiment of the present invention, a temporary storage space in which the gas storage magazine for storing high-pressure gas and the fluid are always in fluid communication is not installed in parts such as a bundle of bolts installed in a real gun, and only when necessary. By opening the discharge valve device, compressed gas for generating reaction force can be discharged directly from the gas storage magazine, thereby preventing gas leakage in advance and significantly reducing the number of additional components for the reaction force generator.

In addition, according to an embodiment of the present invention, by replacing only the bolt and the bolt carrier combination, the ball, the magazine among the components of the real gun, and the rest of the components of the real gun so that the components of the real gun can be used as it is, making the actual gun with minimal change. It is possible to exert a training effect similar to that of the training.

1 is a front partial sectional view showing a state in which a reaction force generating device for simulated shooting according to an embodiment of the present invention is applied to a real gun;
FIG. 2 is a partially enlarged view of a real gun to which the reaction force generating device for simulated shooting shown in FIG. 1 is applied,
Figure 3 is a partial enlarged cross-sectional view showing the state before the trigger operation in a real firearm with a reaction force generating device for simulated shooting according to an embodiment of the present invention,
Figure 4 is a partial enlarged cross-sectional view showing a hammer ball hitting the trigger action interlocked with the trigger operation in a real gun to which a reaction force generator for simulated shooting according to an embodiment of the present invention is applied,
5 is a partial enlarged cross-sectional view showing a state in which the simulated bolt and the simulated bolt carrier combination are moved rearward in response to gas discharge in a real gun to which a reaction force generator for simulated shooting according to an embodiment of the present invention is applied,
Figure 6 is a partial enlarged cross-sectional view showing the installation state of the ball rear support spring for positioning the simulated ball in the simulated bolt in a real firearm to which a reaction force generating device for simulated shooting according to an embodiment of the present invention is applied,
7 is an enlarged cross-sectional view of a main portion of a reaction force generator according to the prior art.

Hereinafter, specific embodiments in which the present invention can be practiced will be described in detail. These examples are described in detail enough to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the technical spirit and scope of the invention in connection with one embodiment. Therefore, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed. Specific examples in which the invention may be practiced are described in detail. These examples are described in detail enough to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the technical spirit and scope of the invention in connection with one embodiment. Therefore, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed.

1 is a front partial sectional view showing a state in which a reaction force generating device for simulated shooting according to an embodiment of the present invention is applied to a real gun, and FIG. 2 is a part of a real gun applied with the reaction force generating device for simulated shooting shown in FIG. It is an enlarged view.

The reaction force generating device for simulated shooting according to an embodiment of the present invention is a reaction force generating device for simulated shooting for performing simulation training using a real gun, as illustrated in FIG. 1 by way of example. It can be applied and used. In this specification, the AK47 series gun is described as an example, but the present invention should not be construed as being limited thereto.

1 and 2, the reaction force generating device for simulated shooting according to an embodiment of the present invention is used to be detachably mounted on a real gun, and is largely simulated bolt 100A, simulated bolt carrier 400A ), A simulated ball (200A), may include a simulated gas magazine (300A), generates a high-pressure gas pressure by the blow of the hammer (H) to rotate in conjunction with the trigger (T) of the real gun trigger And by hitting the recoil spring R, it is possible to generate simulated noise and reaction force.

The simulated bolt carrier (400A) is formed integrally with the carrier top having a through hole through which the distal end of the recoil spring (R) of the real gun is inserted and fixed, and the simulated bolt (100A) is slidable. It is composed of a lower part of a carrier having a receiving groove formed therein, and is alternately mounted at a position where the bolt carrier of the real gun is mounted.

The simulated bolt (100A) is slidably mounted in the receiving groove of the simulated bolt carrier (400A), the simulated bolt (100A) in the space between the outer wall surface of the simulated bolt (100A) and the inner wall surface of the receiving groove The mock bolt by installing the position alignment spring 104A, and inserting the bolt holding pin 102A in the vertical direction to the longitudinal direction of the mock bolt 100A in the groove formed in the outer wall surface of the mock bolt 100A. In order to prevent the 100A from coming out completely from the simulated bolt carrier 400A, it is possible to slide together in the longitudinal direction of the real gun.

A through groove is formed in the center of the simulation bolt 100A from the rear, and a gas having a diameter larger than the through groove is accommodated in front of the through groove so that gas discharged from the simulated gas magazine 300A described later can be accommodated. Grooves are formed continuously.

The simulated ball 200A is slidably mounted along the longitudinal direction of the simulated bolt 100A in a through groove in the simulated bolt 100A, and simulated gas magazine (described later by a hammer H of the real gun) As a component for opening the discharge valve device 310A of 300A), the distal end portion is configured to have the entire length exposed outward from the front portion of the simulated bolt 100A.

On the other hand, by inserting the ball holding pin 202A in the vertical direction in the longitudinal direction of the mock ball 200A into the groove portion formed on one side of the outer wall surface of the mock ball 200A, the mock ball 200A is the mock bolt It is possible to slide in the longitudinal direction of the simulated bolt (100A) in a state that is prevented from coming out completely from (100A).

In addition, in order to prevent damage due to inadvertent mounting of the user during the installation of the simulated gas magazine 300A, the tip end exposed in front of the simulated bolt 100A of the simulated ball 200A, until release by necessity A ball rear support spring 204A simulates the ball by allowing the simulated ball 200A to be positioned at the front end of the simulated ball 200A in the central through groove of the simulated bolt 100A by applying elastic force to the rear of the actual gun 200A. It is preferable to be installed in a space between the outer wall surface of the ball 200A and the inner wall surface of the simulated bolt 100A. 6 is a partially enlarged cross-sectional view showing an exemplary installation state of a ball rear support spring for positioning a simulated ball in a simulated bolt in a real gun to which a reaction force generating device for simulated shooting according to an embodiment of the present invention is applied. However, if it is possible to achieve the same purpose as above, the ball rear support spring may be installed in different ways or in different positions.

The simulated gas magazine 300A is a component for storing compressed gas as a source for generating reaction force during simulated shooting, and is manufactured to have an appearance similar to that of a real gun, and is mounted on a real gun through a magazine engaging portion of the real gun. The gas chamber 330A for storing compressed gas therein, the filling valve device 320A for refilling the gas chamber 330A for reuse, and the compressed gas stored in the gas chamber 330A. And a discharge valve device 310A that can be opened and closed so as to discharge the simulated bolt 100A toward the front gas receiving groove.

The simulated gas magazine (300A) is formed so that only one side of the upper end inserted into the real gun protrudes upward so as to be coupled in a rotational mounting manner through the magazine joint of the real gun, so that the appearance of the magazine used in the real gun is shown. Even if deformed, it is preferable to configure so that there is no problem in mounting through the magazine joint.

In addition, the simulated gas (200A) is simulated along the through-hole of the simulated bolt (100A) while sliding along the longitudinal direction of the real gun, the simulated gas projected upward so that the discharge valve device (310A) can be directly blown open. It is preferable that the discharge valve device 310A is provided at an upper end of the magazine 300A. As a result, a separate opening means of the discharge valve device 310A becomes unnecessary, and thus, changes or additions to components of the real gun can be minimized.

Meanwhile, the discharge valve device 310A is movably built on a gas discharge flow path from the gas chamber 330A to shield a gas outlet, and the gas outlet is moved by sliding movement of the simulated ball 200A. Ball valve (312A) that serves to open the; A ball spring 314A providing an elastic force in a direction of shielding the gas outlet with respect to the ball valve 312A in a state embedded in the gas discharge passage; A spring fixing pin 316A supporting the ball spring 314A to be elastically deformable; And a bushing 318A fixed to the distal end of the discharge valve device 310A and seating the ball valve 312A in place while forming the gas outlet.

In addition, the compressed gas that is stored and used in the simulated gas magazine 300A is preferably carbon dioxide (CO2) gas in order to obtain an appropriate reaction force, and an amount of gas capable of simulating at least 100 shots or more at one full charge. It should be able to be stored in the simulated gas magazine (300A).

Hereinafter, a method of operating a reaction force generating device for simulated shooting according to an embodiment of the present invention configured as above will be described in detail with reference to the accompanying drawings.

3 is a partially enlarged cross-sectional view showing a state before trigger operation in a real gun to which a reaction force generating device for simulated shooting according to an embodiment of the present invention is applied, and FIG. 4 is a reaction force generating device for simulated shooting according to an embodiment of the present invention Is a partially enlarged cross-sectional view showing a hammer hitting a ball interlocked with a trigger operation in a real gun, and FIG. 5 is a simulation bolt according to gas discharge in a real gun with a reaction force generating device for simulated shooting according to an embodiment of the present invention And a partially enlarged cross-sectional view showing a state in which the simulated bolt carrier assembly is moved rearward.

As shown in Figure 3, before the trigger (T) operation of the real gun, the pressure of the compressed gas stored in the gas chamber in the simulated gas magazine (300A) and the elastic force by the ball spring (314A) applied through the spring fixing pin (316A) The ball valve 312A, which is movably embedded on the gas discharge flow path by, is located in a state in which the gas outlet is shielded, so that the discharge valve device 310A is kept closed.

In this state, as shown in Figure 4, when the trigger (T) of the real gun is triggered, the hammer (H) of the real gun that rotates and moves in association with it hits the rear end of the simulated ball (200A), the simulation The ball 200A slides forward in the through groove in the simulated bolt 100A and pushes the ball valve 312A, the tip of which is located at a position where the gas outlet is shielded, thereby opening the gas outlet, Gas is discharged into the gas receiving groove in front of the simulated bolt 100A.

As shown in FIG. 5, by the direct pressure of the discharged gas, the simulated bolt 100A, the simulated ball 200A, and the simulated bolt carrier 400A connected to be integrally slid together are moved to the rear of the real gun. As the sliding movement, the recoil spring (R) of the real gun is compressed, and in this process, a reaction force is generated with noise.

In addition, since the pressing force from the simulated ball 200A has been removed, the discharge valve device 310A of the simulated gas magazine 300A returns to the closed state before the trigger T operation shown in FIG. 3, and moves backward. The combination of the simulated bolt 100A and the simulated bolt carrier 400A that has been slid is also returned to the state shown in FIG. 3 by the return force of the recoil spring R.

If the trigger (T) of the real gun is triggered again in this state, the above process is repeated again.

After all, in the reaction force generator for simulated shooting according to an embodiment of the present invention, the gas in the simulated gas magazine 300A is released by trigger T triggering of the real gun, and the emitted gas is directly simulated in the bolt 100A and simulated The reaction force is generated by sliding the bolt carrier 400A backward.

In the above, specific examples of the present invention have been described as examples, but these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art to which the present invention pertains that various substitutions, modifications, and modifications are possible without departing from the spirit of the present invention.

100A: mock bolt
200A: mock ball
300A: simulated gas magazine
310A: drain valve device
320A: Filling valve device
330A: gas chamber
400A: mock bolt carrier
T: Trigger
H: Hammer
R: Recoil spring

Claims (10)

As a reaction force generator for simulated shooting for performing simulation training using a real gun,
A simulated bolt carrier that is fixed by being inserted through the front end of the recoil spring and slidably toward the other end of the recoil spring;
A simulated bolt slidably mounted in the receiving groove in the simulated bolt carrier and slidable with the simulated bolt carrier;
The compressed gas is stored therein, and a simulated gas magazine coupled to the real gun through the magazine engaging portion of the real gun; And
It includes; a simulation ball slidably mounted along the longitudinal direction of the simulated bolt in the through groove in the simulated bolt and opening a discharge valve device inside the simulated gas magazine by a hammer hitting the real gun;
A reaction force generating device for simulated shooting, wherein reaction force is generated by sliding the simulated bolt and the simulated bolt carrier to the rear of the real gun directly by the gas discharged from the opened discharge valve device. The method according to claim 1,
The simulated gas magazine is formed so that only one side of the upper end inserted into the real gun is projected upward so as to be coupled in a rotational mounting manner through the magazine joint of the real gun, and the discharge valve device is provided at the upper end projecting upward. , Reaction force generator for simulated shooting. The method according to claim 1,
The discharge valve device,
A ball valve movably embedded on the gas discharge passage to shield the gas outlet, and to open the gas outlet by sliding movement of the simulated ball;
A ball spring providing an elastic force in a direction of shielding the gas outlet with respect to the ball valve in a state embedded in the discharge passage;
A spring fixing pin for elastically deforming the ball spring;
And a bushing fixed to the distal end of the discharge valve device and seating the ball valve in a fixed position while forming the gas outlet. The method according to claim 1,
The simulated gas magazine is coupled through the magazine coupling portion of the real gun in such a way that the discharge valve device directly faces the front of the simulated bolt, a reaction force generating device for simulated shooting. The method according to claim 1,
Provides elastic force to the rear of the actual gun to the simulated ball so that the distal end of the simulated ball is located in the through groove of the simulated bolt so as not to interfere with the process of coupling the simulated gas magazine through the magazine engaging portion of the actual gun. The ball further comprises a rear support spring, the reaction force generating device for simulated shooting. The method according to claim 1,
A gas receiving groove having a diameter larger than that of the through groove is continuously formed in front of the through groove in the simulation bolt so that gas discharged from the discharge valve device can be accommodated. The method according to claim 1,
Further comprising a bolt retaining pin inserted in the vertical direction in the longitudinal direction of the mock bolt in the groove portion formed on the outer wall surface of the mock bolt to prevent the mock bolt from completely coming out of the mock bolt carrier, for mock shooting Recoil generator. The method according to claim 1,
The simulated gas magazine includes a filling valve device for re-using compressed gas and reusing the simulated gas. The method according to claim 1,
The compressed gas is a carbon dioxide (CO2) gas, a reaction force generator for simulated shooting. The method according to claim 1,
The real gun is an AK47 series real gun, a reaction force generating device for simulated shooting.

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