KR101084907B1 - Devices with sham rifles have reaction - Google Patents

Abstract

PURPOSE: An imitation rifle having a reacting force generator is provided to reduce costs for purchasing carbon dioxide and prevent environmental contamination by generating a reaction force using compressed air instead of carbon dioxide. CONSTITUTION: An imitation rifle comprises an imitation rifle body(100), a bolt carrier part(200), and a compressed air tank part. The imitation rifle body comprises a moving part, a trigger(160), and a connection part(170). The bolt carrier part includes a pestle(270) is hit by a hammer(180) connected to the trigger and the connection part of the imitation rifle body. An insertion rod(340) of the compressed air tank part has a compressed air opening and closing valve unit(330) which is inserted into or protruded from an insertion hole(240) of the bolt carrier part. When the pestle strikes an opening and closing pin of the compressed air opening and closing valve unit, compressed air is ejected from a compressed air ejecting hole and the bolt carrier part is moved left from the compressed air opening and closing valve unit. The bolt carrier part is moved right by the elastic rebound force of a recoil spring, thereby generating a reaction force.

Description

A simulated rifle with a reaction force generator. {Devices with sham rifles have reaction}

The present invention relates to a simulated rifle having a reaction force generating device, and more particularly, to a high pressure compressed air which is composed of a bolt carrier portion and a compressed air tank portion installed in the simulated rifle main body, and ejected from the compressed air open / close valve portion. Due to this, the bolt carrier part is moved to the left side, and the connecting member installed on the upper part of the bolt carrier part is connected to the guide rod installed in the guide part of the mock rifle main body, and the bolt carrier is driven by the resilient spring of the recoil spring inserted into the left side of the connecting member and the outer circumference of the guide rod. The unit was moved to the right to generate reaction forces in the rifle, such as reaction forces fired by the ammunition or dread bullets.

As is well known, the DPR used in the automatic rifle is to remove only bullets from the bullets for training purposes, to distinguish them from the actual killing shots in order to give a realistic situation in the rifle training. It consists of casings and propulsion drugs.

These terror bullets are loaded into magazines and used in the rifle. When a trigger is pulled, the ball strikes the detonator's detonator, detonates the detonator and explodes a propellant, making it sound as if it's being used for training purposes. In this case, the weapons are fired and used in a state where a minimum safety distance is secured during training, thereby achieving the same effect as in combat.

However, in handling the bombs, the careful use of the bombs by the user or the manager to recycle them after the use of the bombs in training, and the management operation procedure based on the actual bullets are applied to prevent them from being used in crime. .

In producing such a dread bomb, since it is made of the same material as a real bullet, there is a problem in that expensive manufacturing cost is required.

In addition, in the field unit, the demand for the dread bullets is increasing to obtain a realistic training effect in training, which causes a large consumption of the national budget, and to improve the description and effect of the realistic training situation in the future. Additional Dreadshot

Since the demand is expected to occur largely, the cost is expected to increase further, resulting in a problem that the consumable cost continues to increase.

On the other hand, when using terror bombs in field units, there are no fears compared to real bullets, which can lead to accidents caused by physical injuries such as burns and injuries due to carelessness, as well as damage to the training atmosphere due to safety accidents. There was a lot of waste in safety education and prevention programs.

In addition, the deterioration factor of gun life, such as gun wear and corrosion caused by the use of terror bombs, and the maintenance time of the soldiers increased due to firearms in the field.

In dealing with other horror bombs, there were problems such as excessive management time due to separate management of the management personnel and excessive demand for training administration due to payment. The psychological burden was so heavy that the training effect was always inherent.

In addition, there has been a problem that the reaction force generating device that generates the same reaction force generated when using a bullet or a bullet in the real gun as a simulated rifle main body, a bolt carrier part, and a compressed air storage unit operated by high-pressure compressed air has not been provided.

In order to solve this problem, the present invention is composed of a bolt carrier portion installed in the mock rifle main body and a compressed air tank portion, due to the high-pressure compressed air ejected from the compressed air opening and closing valve portion provided in the insertion port of the compressed air tank portion The bolt carrier part is moved to the left side, and the connecting member installed on the upper part of the bolt carrier part is connected to the guide rod installed in the guide part of the mock rifle main body, and the bolt carrier part is driven by the repulsive force of the recoil spring inserted to the left side of the connecting member and the outer circumference of the guide bar. The reaction force generated by the real rifle body, the bolt carrier part, and the compressed air storage part is implemented by the reaction force generated by the real or the shotgun by moving it to the right side. Feel, eliminate the cost of buying ammunition and dread bullets, Blanks relates to a simulated rifle with a reaction force generating device to eliminate reduce training costs Blanks adapter costs to prevent the muzzle of the revolver to use silchong.

In order to achieve the above object, the present invention has a moving part formed horizontally in the inner center, a guide part is formed in the upper part of the moving part, a guide rod having a recoil spring is installed in the guide part, and a magazine insertion part is provided in the lower right part. A simulated rifle main body having a trigger installed at a right side of the magazine insert and having a connection portion connected to an upper portion of the trigger, and a hammer connected to the connection portion; A body installed on the left side of the moving unit and installed to move left and right in the moving unit, and a hammer accommodation unit configured to accommodate the hammer on the left side of the body, the horizontal body of which is connected to the hammer accommodation unit A ball, an insertion hole formed at a right side of the moving hole and connected to the moving hole, a fixing groove formed at an upper center of the body, a fixing groove formed at an upper right side of the body, and inserted into the moving hole to the hammer A bolt carrier portion comprising a ball priced by; Compressed air tank body installed on the right side of the moving part, the compressed air storage unit formed inside the left side of the compressed air tank body, and the opening and closing pin portion and the compressed air ejection hole so as to interfere with the ball on the left side of the compressed air storage unit And an insertion hole having a compressed air opening and closing valve part for opening and closing the compressed air to be inserted into and out of the insertion hole, and a compressed air moving hole connecting the compressed air opening and closing valve part to the compressed air storage part of the compressed air tank body. It is formed inside, characterized in that composed of a compressed air tank unit which is installed on the outer periphery of the compressed air tank body and provided with a compressed air inlet connected to the compressed air storage unit.

In addition, the fixing member is inserted into the fixing groove is installed in the lower portion, the upper portion of the connecting member is installed through the guide rod is inserted, the left side of the connecting member and the recoil spring is installed on the outer circumference of the guide rod The connecting member is installed so as to move left and right in the guide rod.

In addition, a compressed air receiving portion is formed inside the compressed air opening and closing valve portion, a closed wall provided on the right side of the compressed air receiving portion, a movement guide hole formed on the left side of the compressed air opening and closing valve portion, and a movement guide through hole formed in the closed wall. The opening pin and the opening and closing ball formed on the right side of the moving pin to open and close the right side of the movement guide hole of the closed wall is installed on the inner left side of the compressed air movement hole and the rear of the opening and closing ball It is characterized in that it is composed of a spring installed inside the compressed air moving hole, and a plurality of compressed air ejection hole formed in the circumference of the movement guide hole and connected to the compressed air receiving portion.

In addition, a semi-circular groove portion is formed on the right side of the ball, and a semi-circular protrusion is formed on the left side of the moving pin to be seated in the groove portion, and a guide member inserted into the right side of the moving hole and formed in the guide member. A guide hole is inserted into the right side of the ball, and the compressed air inlet is provided with a compressed air connection adapter, and the compressed air connection adapter is characterized in that the portable compressed air tank in which the compressed air is stored.

 The present invention is composed of a bolt carrier portion and a compressed air tank portion installed in the mock rifle main body, the bolt carrier portion is moved to the left side by the high pressure compressed air ejected from the compressed air opening and closing valve portion provided in the insertion port of the compressed air tank portion, The connecting member installed on the upper part of the bolt carrier part is connected to the guide bar installed on the guide part of the mock rifle main body, and the bolt carrier part is moved to the right side by the elastic force of the recoil spring inserted on the left side of the connecting member and the outer circumference of the guide bar. Alternatively, the reaction force generated by the shotgun is implemented by a reaction force generator composed of a simulated rifle main body, a bolt carrier part, and a compressed air storage unit, and has the effect of feeling the reaction force of the real gun generated by the ammunition and the bullet.

In addition, the present invention generates a reaction force to the mock rifle consisting of a bolt carrier part and a compressed air tank using compressed air compressed air in the atmosphere to provide a reaction force to the mock rifle using a conventional high pressure gas, that is, carbon dioxide gas. By preventing the occurrence of carbon dioxide gas and the cost of purchasing and using the tool to reduce the cost and to prevent the environmental pollution caused by the use of carbon dioxide, there is an eco-friendly effect.

In addition, the present invention eliminates the cost of purchasing bullets and bullets, and has the effect of reducing the training cost by eliminating the adapter cost of blocking the muzzle of the real gun when using the bullets in a continuous firing.

In addition, the present invention is effective in eliminating the hassle of using the ammunition and the dread bullet used in the real gun and the trouble of the ammunition and the dread bullet.

1 is a schematic view according to the present invention.
Figure 2 is an exploded view showing the configuration of the present invention.
Figure 3 is a schematic cross-sectional view showing a coupling relationship between the bolt carrier portion and the compressed air tank unit to the simulated rifle main body according to the present invention.
Figure 4 is a schematic separation cross-sectional view according to the present invention.
5 to 7 are schematic views showing the action according to the present invention.
8 is another embodiment according to the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to explain the present invention more safely to those having ordinary skill in the art.

Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals.

In addition, detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

1 is a schematic view according to the present invention, Figure 2 is an exploded view showing the configuration of the present invention, Figure 3 is a schematic cross-sectional view showing the coupling relationship between the bolt carrier portion and the compressed air tank unit to the simulated rifle main body, Figure 4 is a schematic separation cross-sectional view according to the present invention, Figures 5 to 7 is a schematic view showing the action according to the present invention, Figure 8 is another embodiment according to the present invention.

The simulation rifle having a reaction force generating device according to the present invention will be described in detail with reference to those shown in Figs.

The simulated rifle having a reaction force generating device according to the present invention is composed of a simulated rifle main body 100, the bolt carrier portion 200, and the compressed air storage unit 300.

As shown in FIGS. 1 to 4, the simulated rifle main body 100 includes a moving part 110 formed horizontally in the inner center of the simulated rifle main body 100.

The moving part 110 is provided with a bolt carrier 200 to be described later.

In addition, the guide portion 120 is formed on the upper portion of the moving part 110 is configured.

The guide rod 140 is installed on the guide portion 120.

Recoil spring 130 is inserted into the outer circumference of the guide rod 140 is configured.

The recoil spring 130 is configured to support the left side of the connection member 190 to be described later shot.

A magazine insertion unit 150 is formed at the lower right side of the simulated rifle main body 100.

The trigger 160 is installed on the right side of the magazine insertion unit 150 formed at the lower right side of the simulated rifle main body 100, and a connection unit 170 connected to and installed at an upper portion of the trigger 160, and the connection unit ( 170 is configured to be connected to the hammer 180 is installed.

The locking jaw 181 formed at the lower left side of the hammer 180 is interfered with the locking hole 171 formed at the upper right side of the connecting portion 170 of the trigger 160.

When the locking hole 171 is caught by the locking jaw 181, that is, the hammer 180 having a resilience force of a spring (not shown) installed in the hammer 180 is inclined to the left to the hammer 180 When the triggering jaw 181 of the engaging lock 171 when the trigger 160 is operated, the latch 171 of the connecting portion 170 installed on the upper portion of the trigger 160 is hammered The hammer 180, which is separated from the locking step 181 and tilted to the left side, is operated from left to right to stand vertically to hit the left side of the ball 270 to be described later. To move from left to right.

Although the simulated rifle main body 100 is illustrated in the present invention in the shape of the body of the K2 rifle which is a real gun, the body shape of the M16 A1 rifle that is the M16 rifle that is a real gun, the body shape of the M16 A2 rifle, the M16 The body shape of the A3 rifle, the AK series rifle body shape of the real rifle, the K1 rifle body shape of the K rifle series, the K2 rifle body shape, the K3 rifle body shape, and the body shape of the M4 rifle real rifle It can be formed in the back, and can be applied to the shape of the automatic rifle body currently used.

That is, the simulated rifle of the present invention may be manufactured by using the actual rifle as a simulated rifle and applying the simulated rifle main body 100, the bolt carrier part 200, and the compressed air tank part 300 which are the configurations of the present invention.

As shown in FIGS. 1 to 4, the bolt carrier part 200 is installed on the left side of the moving part 110 to move left and right in the moving part 110. It is composed of a body 210 to be installed.

On the left side of the body 210 is formed a hammer receiving portion 220 is received the hammer 180 is formed.

Is formed horizontally of the body 210 is composed of a moving hole 230 connected to the hammer receiving portion 220.

The insertion hole 240 is formed on the right side of the moving hole 230 and is connected to the moving hole 230.

The insertion hole 340 of the compressed air opening / closing valve part 330 which will be described below is inserted into the insertion hole 240.

It is composed of a fixing groove 250 formed in the upper center of the body 210.

A lower portion is inserted into the fixing groove 250 is formed of a connection member 190 installed.

The guide rod 140 is inserted through the upper portion of the connection member 190 is installed.

It is installed on the left side of the connecting member 190 and consists of the recoil spring 130 installed on the outer circumference of the guide rod 140 so that the connecting member 190 is moved left and right in the guide rod 140 Installed and configured.

In other words, a lower portion of the connection member 190 is seated in the fixing groove 250, and the guide rod 140 penetrates and is installed on the upper portion of the connection member 190. The recoil spring 130 installed on the left side and inserted into the outer circumference of the guide rod 140 is shot based on the left side of the connecting member 190 so that the connecting member 190 is the guide rod 140. And from left to right or from right to left.

When the bolt carrier 200 is pushed to the left by the high-pressure compressed air and pneumatic pressure ejected from the compressed air opening and closing valve unit 330 provided on the left side of the compressed air tank 300 to be described later When the connecting member 190 of the bolt carrier part 200 is automatically moved to the right side due to the guide rod 140 and the recoil spring 130, the bolt carrier part 200 is also moved to the right side.

In other words, the state in which the bolt carrier 200 is moved to the left and right is composed of a selector (not shown) for adjusting the single shot mode, the continuous shooting mode, and the three-point shooting mode installed in the mock rifle main body 100. When the bolt carrier part 200 is continuously moved to the left and right in the continuous mode, or when the selector (not shown) is in the single mode, the bolt carrier part 200 is moved to the left and right once. Or, when the selector (not shown) in the three-point mode, the bolt carrier part 200 is configured to be moved left and right three times.

It is composed of a fixing groove 260 formed on the upper right side of the body 210.

An operating lever (not shown) is installed in the fixing groove 260.

The ball 270 inserted into the moving hole 230 and priced by the hammer 180 is configured.

The upper right side of the hammer 180 strikes the right side of the ball 270 so that the ball 270 moves within the moving hole 230.

In addition, a semicircular groove 271 is formed at the right side of the ball 270, and a semicircular protrusion 334 ′ is formed at the left side of the moving pin 334 to be seated in the groove 271.

The groove 271 is in contact with the projection 334 ′ stably contact the right side of the ball 270 to hit the left side of the moving pin 334 stably the ball 270 is the moving pin 334 This is to minimize price failure.

 On the other hand, it is composed of a guide member 500 inserted into the inner right of the moving hole 230.

 The guide hole 510 formed in the guide member 500 is configured to be inserted into the right side of the ball 270.

Installing the guide member 500 on the inner right side of the moving hole 230 as described above is to guide the operation of the right side of the cantilever 270 more stably.

The compressed air tank 300 is shown in Figures 1 to 4, the compressed air tank 300 is composed of a compressed air tank body 310 installed on the right side of the moving part (110). .

The pressure of the compressed air stored in the compressed air storage unit 320 of the compressed air tank 300 is preferably composed of 150kg / cm², the pressure of the compressed air is 150kg / cm² or more or 150kg / cm² It may consist of the following.

In this way, the compressed air stored in the compressed air tank unit 300 is configured to blow into the compressed air ejection hole 338 of the compressed air open / close valve unit 330.

Compressed air tank is composed of a compressed air storage unit 320 formed inside the left side of the main body (310).

The compressed air storage unit 320, the compressed air moving hole 340a, the compressed air inlet 350, and the compressed air opening and closing valve unit 330 constituting the compressed air tank body 310 150kg It is preferably composed of a metal material that withstands air pressure above / cm².

The compressed air storage 320 is injected and stored with high pressure compressed air or pneumatic pressure.

On the left side of the compressed air storage unit 320 is provided with an opening and closing pin 336 and the compressed air ejection hole 338 to interfere with the ball 270 to open and close the compressed air opening and closing valve unit 330 It is configured to be installed to be inserted into the insertion hole 340 having the inside of the insertion hole 240.

A compressed air accommodating part 331 is formed inside the compressed air opening / closing valve part 330 and includes a closed wall 332 provided on the right side of the compressed air accommodating part 331.

In addition, the movement guide hole 333 formed on the left side of the compressed air opening and closing valve 330 and the movement pin 334 and the movement pin which are moved in the movement guide hole 333 'formed in the closing wall 332. Opening and closing pins 335 formed on the right side of the closing wall 332 to open and close the right side of the movement guide hole 333 'is installed on the inner left side of the compressed air movement hole 340a. 336.

Supporting the rear of the opening and closing ball 335, it is composed of a spring 337 installed inside the compressed air moving hole (340a).

The spring 337 is configured to return the rear surface of the opening and closing ball 335 that is moved from left to right from right to left with the elastic force of the spring 337.

It is composed of a plurality of compressed air blowing holes 338 formed around the movement guide hole 333 and connected to the compressed air receiving portion 331.

The compressed air opening / closing valve unit 330 and the compressed air storage unit 340a for connecting the compressed air storage unit 320 are formed inside the compressed air tank body 310.

The compressed air moving hole 340a is configured to receive high pressure compressed air or pneumatic pressure from the compressed air storage unit 320.

 Compressed air tank is installed in the outer periphery of the main body 310 and is composed of a compressed air inlet 350 connected to the compressed air storage unit 320.

The compressed air inlet 350 is configured to inject high pressure compressed air or air into the compressed air storage 320.

In addition, as shown in FIG. 8, a compressed air connection adapter 600 is installed at the compressed air inlet 350, and the compressed air connection adapter 600 is connected to a portable compressed air tank 610 to provide compressed air. It is configured to receive.

The portable compressed air tank 610 is preferably configured to 150kg / cm² to withstand the pressure of the compressed air, the pressure of the compressed air may be able to withstand the air pressure of more than 150kg / cm² or less than 150kg / cm². .

In addition, the compressed air connection adapter 600 is preferably made of a metal material that withstands air pressure of 150kg / cm² or more.

The compressed air connection adapter 600 may be connected to a connection hose (not shown) connected to a compressed air generator (not shown) for generating compressed air.

The compressed air generating device (not shown) is preferably to generate the pressure of the compressed air more than 150kg / cm².

This configuration is to supply high-pressure compressed air and supply compressed air of a constant pressure to the reaction force generator of the mock rifle so as to stably generate and use a stable reaction force in the reaction force generator.

The present invention is configured as described above is composed of the simulated rifle main body 100, the bolt carrier portion 200, and the compressed air tank unit 300 to feel the recoil due to real bullets and bullets in the real gun. It is.

In addition, by replacing the existing high-pressure carbon dioxide gas by using the compressed air generated by compressing the air in the air as it is to prevent the air pollution generated when using the carbon dioxide gas.

Multiple intergrated laser engagement system comprising a laser device (not shown) installed in the mock rifle according to the present invention to detect the laser beam sent to the laser launcher to determine the hit (Multiple intergrated laser engagement) It can be applied to the Miles System to allow soldiers to perform realistic combat training with the simulated rifle of the present invention.

Referring to the operation of the present invention with reference to those shown in Figures 5 to 7 as follows.

5 is a view showing the state before the ball hitting the opening and closing pin, Figure 6 is a view showing the state after the ball hitting the opening and closing pin portion, Figure 7 is the ball carrier after moving the opening and closing pin portion, the bolt carrier part is moved to the left It is a figure which shows the state.

First, when high pressure compressed air is injected into the compressed air storage unit 320 through the compressed air inlet 350, the insertion hole (340a) is connected to the compressed air moving hole 340a connected to the compressed air storage unit 320. The right side of the closing wall 332 of the compressed air open / close valve unit 330 installed on the left side of the head 340 is reached.

At this time, when the trigger 160 is pulled to the left, the upper portion of the connecting portion 170 installed on the upper portion of the trigger 160 releases the lower portion of the hammer 180 so that the right surface of the hammer 180 is the ball 270. The right side of the ball 270 is moved to the left side from the inside of the moving hole 230 to hit the left side of the right side of the compressed air opening and closing valve portion inserted into the insertion hole 240 ( When the left side of the moving pin 334 of the 330 is hit, the moving pin 334 is moved from left to right in the movement guide hole 333 and the movement guide hole 333 '. The opening and closing ball 335 which is integrally connected to the rear of the moving pin 334 blocks the rear of the closing wall 332 and the movement guide hole 333 'and is moved from left to right to move the movement guide hole ( 333 ') is opened.

At this time, the spring 337, which was supporting the right side of the opening and closing ball 335, is compressed, and the high pressure is applied to the compressed air accommodating part 331 through the movement guide hole 333 'of the closing wall 332. The compressed air of the high-pressure compressed air is ejected through the plurality of compressed air ejection holes 338 connected to the compressed air accommodating part 331.

The compressed high pressure compressed air is supplied to the left space of the insertion hole 240 to move the bolt carrier part 200 to the left side.

At this time, the connecting member 190 seated in the fixing groove 250 formed on the upper part of the bolt carrier part 200 is moved to the left side from the guide rod 140, the recoil installed on the guide rod 140 When the spring 130 is compressed based on the left side of the connecting member 190, the connecting member 190 and the bolt carrier portion 200 again from left to right by the elastic force of the recoil spring 130 Let it move

The series of operations described above are controlled by the selector (not shown) installed in the simulated rifle of the present invention to control a continuous shooting mode, a single shot mode, and a three-point shooting mode. The bolt carrier part 200 continuously moves the bolt carrier part 200 to the left and right sides of the moving part 110, and the bolt carrier part 200 once when the selector (not shown) is set to the single shot mode. When the selector (not shown) is in three-point mode, the bolt carrier part 200 is configured to be moved left and right three times.

It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the scope of the present invention. . Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description.

Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents and substitutions within the spirit and scope of the invention as defined by the appended claims.

DESCRIPTION OF SYMBOLS 100: Mock rifle main body 110: Moving part 120: Guide part 130: Recoil spring 140: Guide rod 150: Magazine insertion part 160: Trigger 170: Connection part 180: Hammer 190: Connection member 200: Bolt carrier part 210: Body 220: Hammer Receiving part 230: Moving hole 240: Insertion hole 250: Fixed groove 260: Fixed groove 270: Ball 271: Groove 300: Compressed air tank 310 310 Compressed air tank body 320: Compressed air storage 330: Compressed air open / close valve 331 : Compressed air accommodating part 332: Closed wall 333: Moving guide hole 333 ': Moving guide hole 334: Moving pin 334': Projection 335: Opening ball 336: Opening pin 337: Spring 338: Compressed air ejection hole 340: Insertion hole 340a: Compressed air moving ball 350: Compressed air inlet 500: Guide member 510: Guide hole 600: Compressed air connection adapter 610: Portable compressed air tank

Claims (4)

The moving part 110 is formed horizontally in the inner center, the guide part 120 is formed on the upper part of the moving part 110, and the guide rod 140 having the recoil spring 130 in the guide part 120. ) Is installed, the magazine insertion unit 150 is formed on the lower right side, the trigger 160 is installed on the right side of the magazine insertion unit 150, the connection portion 170 is installed in the upper portion of the trigger 160 A simulated rifle main body 100 having a hammer 180 connected to the connection part 170;
The body 210 is installed on the left side of the moving part 110 and installed to move left and right in the moving part 110, and the hammer accommodation part accommodated in the left side of the body 210. 220 is formed and formed in the horizontal of the body 210, the moving hole 230 connected to the hammer receiving portion 220, and formed on the right side of the moving hole 230 and the moving hole 230 Insertion hole 240 formed to be connected to the, and the fixing groove 250 formed in the upper center of the body 210, the fixing groove 260 formed on the upper right of the body 210, and the moving hole 230 A bolt carrier part 200 formed of a ball 270 inserted into the hammer and priced by the hammer 180;
Compressed air tank body 310 installed on the right side of the moving unit 110, the compressed air storage unit 320 formed inside the left side of the compressed air tank body 310, and the compressed air storage unit 320 The insertion hole 340 having a compressed air opening and closing valve portion 330 for opening and closing the compressed air having the opening and closing pin portion 336 and the compressed air ejection hole 338 to be interfered by the ball 270 on the left side of the insertion Installed in and out of the ball 240, the compressed air moving hole 340a for connecting the compressed air opening and closing valve unit 330 and the compressed air storage unit 320 of the compressed air tank body 310 Is formed therein, is composed of a compressed air tank unit 300 which is installed on the outer circumference of the compressed air tank body 310 and provided with a compressed air inlet 350 connected to the compressed air storage unit 320 A simulated rifle with a reaction force generating device. The method of claim 1,
The connecting member 190 installed with the lower portion inserted into the fixing groove 250, and the guide rod 140 is inserted through the upper portion of the connecting member 190, and is installed on the left side of the connecting member 190. Recoil spring is installed and consists of the recoil spring 130 installed on the outer circumference of the guide rod 140, the connecting member 190 is installed to move left and right in the guide rod 140, characterized in that the reaction force generating device Mocking rifle. The method of claim 1,
A compressed air accommodating part 331 is formed inside the compressed air open / close valve part 330, and a closed wall 332 provided on the right side of the compressed air accommodating part 331 and the compressed air open / close valve part 330. The movement guide hole 333 formed on the left side of the) and the movement pin 334 and the movement pin 334 moved in the movement guide hole 333 'formed in the closure wall 332 are formed on the right side of the movement pin 334. Opening and closing ball 335 for opening and closing the right side of the movement guide hole 333 'of the wall 332 is installed on the inner left side of the compressed air moving hole 340a and the opening and closing ball portion 336, ) And a plurality of springs 337 installed in the compressed air moving hole 340a and a plurality of circumferences of the moving guide hole 333 and connected to the compressed air accommodating part 331. A simulated rifle having a reaction force generating device, characterized in that composed of compressed air ejection holes (338) formed. The method of claim 3, wherein
A semicircular groove 271 is formed at the right side of the ball 270, and a semicircular protrusion 334 ′ is formed at the left side of the moving pin 334 to be seated in the groove 271. The guide member 500 inserted into the inner right side of the 230 and the guide hole 510 formed in the guide member 500 are inserted into the right side of the ball 270, and the compressed air inlet 350 is compressed air. Connection adapter 600 is installed, the compressed air connection adapter 600, a simulated rifle having a reaction force generating device, characterized in that the portable compressed air tank 610 is stored compressed air is installed.

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