KR20090008250U - A simulation firearms - Google Patents

Abstract

       The present invention relates to a reaction force generating device of a rifle or a revolver type pistol, in which compressed air, which is a transmission medium of the reaction device, is divided into two lines according to a trigger of a simulated gun (the rifle is given priority). The other side is sucked by the recoil of the butt plate, and the piston is reciprocated in the inner cylinder of the butt plate to give a shock at the time of shooting, and the important point is to reuse the loss of the compressed air hit by Helping to lift the gun is another feature.

Compressed air enters one line and is split into two lines by the T-type coupler, one line flows to the front of the muzzle to create muzzle lift, and the other flows to the recoil on the buttboard side to the inner cylinder of the buttboard. It is a device that makes the piston reciprocate and gives an impact when shooting. At this time, the compressed air discharged after the piston reciprocating movement in the inner cylinder of the butt plate is reused in the lifting line of the front muzzle through the discharge line to further enhance the lifting phenomenon.

       An air line for muzzle lifting is installed in front of the muzzle and the recoil of the gun is fixed inside the buttboard and the cylinder, piston, spring for the return of the piston, the blow surface to which the piston can strike, the cylinder and pump The air compressor installed in the connecting hose and the pressure regulating valve to maintain a constant pressure of the line, the solenoid valve for opening and closing the flow of compressed gas, and the inlet and outlet air lines are combined without a separate controller by using a pressure difference. do.

       As described above, the present invention implements a simulated rifle and a revolver type pistol as close as possible to real fire. As a compressed air having a high compression pressure, the present invention implements a gun lifting phenomenon by the reaction of the actual explosion and the impact of the actual explosion. Its purpose is to maximize efficiency by using loss air properly.

In particular, it is possible to feel a new concept and a sense of real shooting higher than the existing inventions, and it is also suitable for mock shooting training of the police or military and leisure for the general public.

Firearm, shooting, simulation, image, training, air injection, trigger, cylinder

Description

Firearms for Image Shooting Training {A simulation firearms}

The present invention relates to a firearm structure for video shooting training. More specifically, it is possible to obtain the same or similar firearm recoil effect as the real shooting when training a simulated shooting in a virtual space using multimedia technology and computer programming technology. The present invention relates to a firearm structure for image shooting training, which accurately detects an outgoing signal and realizes a recoil effect at the same time as triggering.

As is well known, virtual experiences such as the recent development of multimedia technology and computer programming have created a situation that is difficult to implement in real life while having the same feeling as real life in a virtual space that simulates real life. It is gaining a lot of popularity.

In particular, aircraft training and indoor driving practice are carried out in the virtual space simulated in the same way as in the actual situation, and in the sports area, the training of sports athletes is carried out in the virtual space, so that perfect training is performed based on accurate data. have.

Meanwhile, in the field of entertainment, people are experiencing situations that cannot be produced in real situations through virtual experiences through multimedia and computer technology.

In this way, virtual reality education by simulator is used to cultivate the ability to cope with the actual situation when it is possible to actually experience the situation that is difficult to direct the actual situation.

Among them, recent multimedia and computer technologies can be used to simulate various situations that can actually occur in a virtual space that simulates the actual situation, so that shooting training can be carried out in the same way as the actual situation. An image shooting training system has been researched and started to hone the on-the-spot experience and shooting techniques.

On the other hand, in Korea, only some authorized people, such as police and soldiers, are allowed to use life-saving firearms.

Therefore, in order to use the firearms, they are allowed to use only in the authorized area, and the practice of shooting is about to use the firearm to a fixed target several times a year.

In addition to completing the standard shooting training that uses firearms on fixed targets, if the actual use of the firearms is permitted in a situation where there are not many training opportunities, firearms accidents are caused by the immaturity of the ability to cope with the actual situation. The problem is that it can harm innocent lives.

In addition, there is a problem that when performing actual shooting training, a large obstacle arises in constructing an efficient training system due to various civil complaints and time, space, and material constraints by residents near the training place.

In order to solve this problem, the necessity of an image shooting training system as described above is emerging.

In addition, the Republic of Korea Patent Publication No. 2000-0063143 (2000.11.6.) Discloses an air supply device composed of a pump 16 and a hose 18 connected to the bottom of the handle 44 at the moment of pulling the trigger 14 of the gun. Through the air supplied to the cylinder 24 and the piston 26 of the reaction force generating unit 12 provided inside the gun through the generated technology to generate a reaction force pushed to the rear to feel the actual shooting sense It is.

However, although the conventional simulated firearms are known to some extent to realize the reaction force of the firearm such as the rear reaction force through the above-described reaction force generator, the triggering feeling is different from the actual firearms, There was a problem of being somewhat weak.

That is, in the case of a real firearm, there is a reaction force such that the firearm is lifted up as well as the rear reaction force at the same time, there is a problem that the technology for implementing such a reaction force is rather weak.

In addition, there is a problem that does not have a more precise control system in providing a reaction force of the gun at the precise triggering time.

Therefore, the present invention was devised to improve the problems of the simulated firearm applied to the conventional video shooting training system as described above, and the purpose of the present invention is to achieve the same or similar firearm recoil effect as the actual shooting during the training. It is to provide a gun structure for visual shooting training.

       The present invention is to give a simulated firearm recoil like a real fire, the solenoid valve is operated at the moment the trigger of the gun is pulled, compressed air comes into the line to the firearm is divided into two lines by the T-type coupler, one line is It flows to the front of the muzzle to create a muzzle lift phenomenon, and the other side is a repelling device on the buttboard side, which causes the piston to reciprocate in the inner cylinder of the buttboard. At this time, the compressed air discharged after the piston reciprocating movement in the inner cylinder of the butt plate is reused in the lifting line of the front muzzle through the discharge line to further enhance the lifting phenomenon.

       Currently, firearms of simulated fire drills in the police department or military units are somewhat different from actual fires, and their reactions are weak, which is not helpful for actual training.

       Accordingly, the present invention maximizes the fire feeling similar to the actual fire by reinforcing the recoil of the gun and the lifting of the muzzle for more realistic shooting training.

       The present invention is to give a simulated firearm recoil like a real fire, the solenoid valve is operated at the moment the trigger of the gun is pulled, compressed air comes into the line to the firearm is divided into two lines by the T-type coupler, one line is It flows toward the front of the muzzle to create a muzzle lift phenomenon, and the other side flows to the recoil on the buttboard side to cause the piston to reciprocate in the inner cylinder of the buttboard. At this time, the compressed air discharged after the piston reciprocating movement in the inner cylinder of the butt plate is reused in the lifting line of the front muzzle through the discharge line to further enhance the lifting phenomenon.

As such, the present invention has an effect of more realistic shooting training by maximizing the reaction force of the firearm at the correct time by using the triggering start and completion signal of the actual firearm operation principle.

       According to the present invention, when the trigger controller triggers a trigger signal when the trigger of the gun is pulled, when the trigger controller generates a trigger signal, the compressed air enters one line up to the gun and is divided into two lines by a T-type coupler, The air is split into two lines, one for the gun and one for the recoil in the other, with the front and rear caps sealed on both sides of the cylinder and the cylinders fixed inside the butt (if the rifle is an example). And an air compressor which contacts the inner wall of the cylinder and reciprocates in the cylinder and strikes the rear cap to provide pressure to the piston in the cylinder by means of a piston and a hose generating a reaction force and causing the piston to strike the rear cap. To eliminate pulsations in the air delivery process of air and cylinders and air compressors An air control valve for the purpose of delivering compressed air, an air storage tank for storing a certain amount, a solenoid valve for opening and closing the flow of compressed gas, and a control device for operating the solenoid valve by the movement of the trigger, The aim is to reinforce the muzzle lift by instantaneous discharge of compressed air to create a muzzle lift and to finally reuse the air that has passed through the recoil's operating line.

       In addition, a spring is installed between the piston and the rear cap, the front cap is formed with a guide hole which is connected to the hose supplied with compressed air through the air compressor, the inside of the guide hole by the compressed air to the piston back to the rear cap When the mating surface of the piston hits the spring surface of the rear cap side and strikes the striking surface, the signal transmitted from the control device opens the solenoid valve every time when the trigger is pulled as a normally closed valve, thereby supplying compressed air. .

       In addition, the compressed air entered through the solenoid valve of the hose toward the inlet moves the piston toward the rear cap as described above, hits the piston, and then returns to its original position by the elasticity of the compressed spring. In this case, the compressed air inside the airtight piston is compressed air into the discharge line in order not to nourish the forward and backward movement of the piston. At this time, the compressed pressure inside the piston is placed in front of the muzzle to make muzzle lift.

       In addition, the air compressor communicates with the inner space of the cylinder by a hose and pressurizes the compressed air into the inner space of the cylinder to provide pressure to the piston, and the compressed air entering the inlet line of the cylinder pushes the piston out of the rear cap and The secondary compressed air between the pistons moves to the discharge line, which is connected to the line for the purpose of lifting the muzzle.

       The secondary compressed air generated in the front cap and the piston lower space generated by the return of the piston falls back toward the cylinder inlet and is instantaneously vented by a line that acts as a muzzle lifter.

       The trigger controller also generates a signal with the trigger pulled, causing the solenoid valve to open for a period of time after the trigger is pulled, thereby continuously supplying compressed air to the supply port, thereby allowing the reaction force to be continuously generated while the trigger is pulled. It features.

       Next, the present invention will be described with reference to the accompanying drawings.

       1 is a view showing the main air of the recoil device is blown (recoil) in order to explain the concept of the reaction force generating device in the shape of a device before being installed in the simulated rifle or pistol according to the invention.

       First, the recoil device of FIG. 1 can be mounted on a simulated rifle (FIG. 4) or a simulated pistol (FIG. 5), and only the recoil device will be described in order to explain easily.

The recoil device has a cylinder 203 visible from the outside, a front cap (A), a rear cap (B) that blocks both sides of the cylinder, and each holding pin 201 and muzzle lift phenomenon that secure the front and rear caps to the cylinder. The discharge line 208 and the guide 204 and the piston 209 to maintain the airtight, the sealing of each part is a role. The piston 209 is advanced by the compressed air inside, and the joint surface 207 of the piston 209 strikes the striking surface 210 of the rear cap B. At this time, the rear cap B and the piston ( Some of the compressed air between 209 is discharged toward OUT and the other is discharged to discharge line 208. The discharge line 208 then produces a muzzle lift as shown in FIG.

       FIG. 2 is a view showing a state in which the recoil device strikes and returns to explain the concept of the reaction force generating device in the shape of a device before being installed in the simulated rifle or pistol according to the present invention.

       2 may be regarded as only the position of the piston is moved compared to FIG.

Only the results from the displacement of the piston are different. The piston 209 is returned to the front cap A by the spring 205 and the secondary compressed air between the piston and the front cap is discharged to the discharge line 208. The discharged compressed air is then used to make muzzle lifts.

       3 is a top view and a bottom view of the recoil device of the simulated firearm according to the invention.

3 is a top view and a bottom view of the case consisting of a front cap, a rear cap, and a key with an edge of the case.

       4 is a view in which the recoil device is mounted on the simulated rifle M4A1.

4 is a simulated rifle M4A1 and a recoil device, and a muzzle lift line 401, a muzzle lift reinforcement line 402 connected to the muzzle lift line from the reaction window, and a compressed air inlet line 404 through which compressed air is sucked into the simulated rifle. ) And an air vent from the rear cap of the recoil unit.

       At this time, when compressed air is supplied to the compressed air inlet line 404, air is supplied to the recoil device and at the same time, air is also supplied to the muzzle lift line, where the muzzle is lifted up. Move to the lifting help line is combined with the muzzle lifting line 401 to help the muzzle lift.

       5 is a view in which the recoil device is mounted on a simulated pistol (revolver).

5 is composed of a simulated pistol (revolver) and a recoil window, muzzle lifting line 501, muzzle lifting reinforcement line 503 and compressed air inlet line 502.

       At this time, the shape of the line is slightly different from that of Fig. 4, since the mock pistol is lighter than the mock rifle, there is no need to double the muzzle lift line, and one instant compressed air discharge (the second compression after operating from the recoil unit). Compressed air is supplied to the compressed air inlet line 502 so that the secondary compressed air between the rear cap and the piston resulting from the advancement of the piston is the discharge line and the muzzle lift line ( 501) to produce a muzzle lift. In addition, the secondary compressed air that has been operated from the recoil device is combined with the muzzle lift line 501 via the muzzle lift reinforcement line 503 to produce muzzle lift.

       6 and 7 are diagrams for explaining the flow of compressed air with the recoil device mounted on the simulated rifle M4A1. First, compressed air entering through the compressed air inlet line 404 of FIG. 6 is influenced by the guide 405 in the coupler 602 so that 70% of the air goes to the recoil device to make the recoil and 30% the muzzle lift line Go to (401) and create a muzzle lift phenomenon. At this time, the back pressure inside the recoil device is discharged to the line 403.

       7 is an enlarged view of the coupler of FIG. 6, and includes a compressed air inlet line 404, a muzzle lift line 401, a guide 405, a muzzle lift reinforcement line 402, and a recoil device inlet line 406. have.

       1 is a view showing a state in which the main air of the recoil device is sucked in order to explain the concept of the reaction power generator in the shape of a device before being installed in the simulated rifle or pistol according to the present invention.

       2 is a view showing a state in which the main air of the recoil device is discharged in order to explain the concept of the reaction power generating device in the shape of a device before being installed in the simulated rifle or pistol according to the present invention.

       3 is a cross-sectional view of the upper and lower portions of the recoil device.

       4 is a view of the recoil mounted on the M4A1 rifle;

       5 is a view in which the recoil unit is mounted on the revolver pistol

       6 and 7 are diagrams for explaining the flow of compressed air with the recoil device mounted on the simulated rifle M4A1.

Description of the main parts of the drawing

201: fixing pin 202: sealing

203: cylinder 207: joint surface

208: discharge line 209: piston

210: batting surface

401: muzzle lift line 402: muzzle lift reinforcement

403: back pressure discharge line 404: compressed air inlet line

405: Guide 406: Recoil inlet line

501: muzzle lift line 502: compressed air inlet line

503: muzzle lift reinforcement line

602 coupler

Claims (3)

       The solenoid valve actuates as soon as the gun is triggered, giving the simulated fire a recoil like a real shot. Compressed air enters one line up to the gun and is divided into two lines by the T-type coupler, one line in front of the muzzle. It flows into the muzzle lift phenomenon, and the other side flows to the recoil device on the buttboard side, causing the piston to reciprocate in the inner cylinder of the buttboard. At this time, the compressed air discharged after the piston reciprocating movement in the inner cylinder cylinder is reused in the lifting line of the front muzzle through the discharge line to further enhance the lifting phenomenon,        The cylinder is fixed by the cylinder and the front cap and the rear cap which are sealed at both ends of the gun and the cylinder by the piston and the hose contacting the inner wall of the cylinder and reciprocating in the cylinder and hitting the rear cap to generate the reaction force It stores air compressors that provide pressure to the pistons inside and force the pistons to strike the rear caps, as well as air control valves for uniform compressed air delivery to eliminate pulsation during the air delivery of cylinders and air compressors. Air storage tank, and a solenoid valve to open and close the flow of compressed gas, and a control device to operate the solenoid valve by the movement of the trigger. The air that has passed through the operating line Firearms for imaging training, including re-emphasizing muzzle lift The method of claim 1,       Compressed air, which enters the inlet through the solenoid valve of the hose, moves the piston toward the rear cap as described above, strikes it, and then returns to its original position by the elasticity of the compressed spring. In this case, the compressed air inside the airtight piston is compressed air into the discharge line in order not to nourish the forward and backward movement of the piston. At this time, the compressed pressure inside the piston is placed in front of the muzzle to make muzzle lift. In addition, the air compressor communicates with the inner space of the cylinder by a hose and pressurizes the compressed air into the inner space of the cylinder to provide a pressing force to the piston, and the compressed air entering the inlet line of the cylinder pushes the piston out of the rear cap and the piston. In between, the second compressed air moves to the discharge line, which is connected to the line for the purpose of lifting the muzzle. The secondary compressed air generated in the front cap and the piston lower space generated by the return of the piston falls back toward the cylinder inlet and is instantaneously discharged by a line that acts as a muzzle lift. The method according to claim 1 or 2,       The trigger controller generates a signal in which the trigger is pulled, thereby continuously supplying compressed air to the supply port by opening the solenoid valve for a predetermined time after the trigger is pulled, so that reaction force is continuously generated while the trigger is pulled. .

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