KR102511368B1 - Air rifle using electromagnetic valve - Google Patents

Abstract

According to the characteristics of the present invention, the air tank 110 in which high-pressure air is stored is coupled to one side and the trigger 120 for triggering operation is provided to the other side, and the air supply opened to the rear position of the loaded bullet 141 inside. a gun body 100 in which a ball 130 is formed; a trigger switch 200 outputting a trigger signal when the trigger 120 triggers; An air supply passage 311 disposed between the air tank 110 and the air supply hole 130 in the gun body 100 to discharge the air injected from the air tank 110 to the air supply hole 130. ) and an electronic valve 300 for selectively opening and closing the air supply passage 311 according to a control signal; And when a triggering signal is input from the triggering switch 200, the solenoid valve 300 controls driving to open the air supply passage 311, and the bullet 141 is fired by the air discharged through the air supply hole 130. An air gun using an electronic valve including a control unit 400 to be fired is provided.

Description

Air gun using an electronic valve {AIR RIFLE USING ELECTROMAGNETIC VALVE}

The present invention relates to an air gun using an electromagnetic valve, and more particularly, to an air gun of an electrically driven type that generates air pressure necessary for firing bullets using an electromagnetic valve operated according to an electrical control signal.

11 discloses a configuration of an air gun according to the prior art. Referring to the drawing, in a conventional air gun, an air tank 116 in which high-pressure air is stored is coupled to the front side of a gun body 110, and a compressed air gun body 110 is opened to the rear position of a loaded bullet 164. An air passage 112 is formed, and a sink 114 for selectively opening the compressed air passage 112 according to external pressure is provided in the discharge valve 113 disposed at the end of the air tank 116.

In addition, a hammer 140 is disposed inside the gun body 110 at a position opposite to the sinker 114 in front and back, and the hammer 140 is elastically pressed toward the sinker 114 by the hammer spring 144. The hammer spring 144 could be supported in a compressed state by the rotation latch 151 that rotates with the triggering action of the trigger 152.

Therefore, as shown in FIG. 12, when the user presses the trigger 152 for a trigger operation, the hammer clasp 151 rotates and the supported state of the hammer 140 is released, and the elastic restoring force of the hammer spring 144 The hammer 140 strikes the sinking needle 114, and as the sinking needle 114 retreats to the inside, the sealed compressed air passage 112 is opened, and the bullet 164 is pushed forward by high-pressure air. could be fired

However, in the conventional air gun, the hammer 140 strikes the sinking needle 114 of the air tank 116 to generate the air pressure necessary for firing the bullet by a mechanical drive method that opens and closes the compressed air passage 112, so the hammer ( 140) has a problem in that the aiming state aimed at the target can be easily disturbed due to the shock generated when the percussion needle 114 and the release valve 113 are hit.

In addition, the hammer 140, the hammer spring 144, the hammer clasp 151 and the clasp spring 159 for realizing the mechanical drive method, as well as an auxiliary push rod 180 for moving the hammer 140 backward, Since a number of parts, such as the auxiliary push rod spring 182 and the push rod connecting pin 131, are assembled so as to interlock with each other inside the gun body 110, not only minor malfunctions easily occur, but also the weight of the air gun becomes heavy and the portability deteriorates. There was a problem.

In addition, in the conventional air gun, in order to control the speed of the bullet 164 to be fired, the weight of the hammer 140 mounted inside the gun body 110 or the elastic restoring force of the hammer spring 144 is gradually adjusted to maintain the appropriate bullet speed. For this, disassembly and assembly of the gun body 110 must be repeated several times. ) There is a problem in that the projectile speed of the bullet 164 is gradually reduced as the air discharge rate through the compressed air passage 112 is reduced due to the decrease in the hitting force.

In addition, when the hammer 140 retreats and the air gun is dropped while being supported by the hammer clasp 151 or a strong impact is applied to the gun body 110 from the outside, the hammer clasp 152 is not triggered. There was a problem in that the supported state of the hammer 140 by 151 was released, resulting in an accidental firing.

Publication No. 10-2012-0056072 (2012.06.01), air gun.

The present invention was created to solve the above-mentioned problems, and an object of the present invention is to prevent the aiming state of aiming at a target from being disturbed due to a percussion shock by generating the air pressure required for bullet firing by an electric driving method using an electromagnetic valve. It is an object of the present invention to provide an air gun using an electromagnetic valve, which can be prevented, minimized the number of parts required for bullet firing, can reduce minor malfunctions, and has increased portability by lightening the air gun.

According to the characteristics of the present invention, the air tank 110 in which high-pressure air is stored is coupled to one side and the trigger 120 for triggering operation is provided to the other side, and the air supply opened to the rear position of the loaded bullet 141 inside. a gun body 100 in which a ball 130 is formed; a trigger switch 200 outputting a trigger signal when the trigger 120 triggers; An air supply passage 311 disposed between the air tank 110 and the air supply hole 130 in the gun body 100 to discharge the air injected from the air tank 110 to the air supply hole 130. ) and an electronic valve 300 for selectively opening and closing the air supply passage 311 according to a control signal; And when a triggering signal is input from the triggering switch 200, the solenoid valve 300 controls driving to open the air supply passage 311, and the bullet 141 is fired by the air discharged through the air supply hole 130. An air gun using an electronic valve including a control unit 400 to be fired is provided.

According to another feature of the present invention, the air supply passage 311 communicates with the air injection hole 312 connected to the air tank 110 and into which air is injected, and the air supply hole 130 An air discharge hole 313 and an air storage chamber 314 communicating with the air injection hole 312 and the air discharge hole 313 and storing a certain amount of air, the solenoid valve 300, An air supply passage 311 is formed inside, an air outlet 315 is formed between the air storage chamber 314 and the air discharge hole 313, and a guide groove 316 communicating with the air storage chamber 314 is formed. A valve body 310, a plunger 320 inserted into the guide groove 316 and sliding and reciprocating within the valve body 310 to selectively open and close the air outlet 315, and the guide groove 316 ) and when a control signal from the control unit 400 is applied, a magnetic field is formed and the plunger 320 slides to open the air outlet 315 using an electromagnetic valve including a coil 330. An air gun is provided.

According to another feature of the present invention, the plunger 320 is opened from the front end to the rear end in the sliding reciprocating direction, and the first air transfer hole 321 communicates the air storage chamber 314 and the guide groove 316 is formed, and the plunger 320 is pressed toward the air outlet 315 by air introduced into the guide groove 316 through the first air feed hole 321 to hermetically seal the air outlet 315. An air gun using an electronic valve is provided, characterized in that.

According to another feature of the present invention, the solenoid valve 300 further includes an elastic spring 340 disposed inside the guide groove 316 to press the plunger 320 toward the air outlet 315. And, when the magnetic field of the coil 330 disappears, the plunger 320 slides toward the air outlet 315 by the elastic restoring force of the elastic spring 340. An air gun using an electromagnetic valve is provided. .

According to another feature of the present invention, a second air feeding hole 322 communicating the first air feeding hole 321 and the guide groove 316 is formed inside the plunger 320, and the plunge ( 320) is a solenoid valve characterized by sealing the air outlet 315 more airtightly while being pressed toward the air outlet 315 by air introduced into the guide groove 316 through the second air transfer hole 322. A used air gun is provided.

According to another feature of the present invention, the controller 400 controls the solenoid valve 300 to open the air supply passage 311 only for a set opening duration when a trigger signal is input from the trigger switch 200. There is provided an air gun using an electronic valve, characterized in that it comprises an opening duration setting unit 440 for driving control.

According to another feature of the present invention, the control unit 400, during the set double trigger prevention time after the trigger signal of the trigger switch 200 is input or after the control signal is output to the solenoid valve 300 An air gun using an electromagnetic valve, characterized in that it further comprises a double trigger prevention time setting unit 450 for driving control so that the electromagnetic valve 300 does not open and close by ignoring the trigger signal re-input from the trigger switch 200. is provided.

According to another feature of the present invention, the control unit 400 includes a display 470 displaying a set time 481 set as the opening duration and a set time 482 set as the double trigger prevention time on the screen; It further includes a control unit 480 outputting a user manipulation signal for adjusting each set time 481 and 482 according to a user manipulation, and changes the set time of each set time 481 and 482 according to the control signal of the control unit 480. An air gun using an electronic valve is provided, characterized in that for.

According to another feature of the present invention, the controller 400 controls that, when a trigger signal is input from the trigger switch 200, the solenoid valve 300 opens the air supply passage 311 after a set firing delay time has elapsed. There is provided an air gun using an electronic valve, characterized in that it further comprises a firing delay time setting unit 460 for driving control to open.

Meanwhile. According to another feature of the present invention, the display 470 further displays the set time 483 set as the launch delay time, and the control unit 480 adjusts the set time 483 according to a user's manipulation. An air gun using an electromagnetic valve is provided, characterized in that the control unit 400 changes the set time of the set time 483 according to the operation signal of the control unit 480.

As described above, according to the present invention,

First, the gun body 100 has an air tank 110 in which high-pressure air is stored on one side, and a trigger 120 for triggering action is provided on the other side. A supply hole 130 is formed, the trigger switch 200 outputs a trigger signal when the trigger 120 triggers, and the solenoid valve 300 controls the air tank 110 and air in the gun body 100. It is disposed between the supply holes 130 to form an air supply passage 311 for discharging air injected from the air tank 110 to the air supply hole 130, and controls the air supply passage 311 according to a control signal. The control unit 400 controls driving so that the solenoid valve 300 opens the air supply passage 311 when a trigger signal is input from the trigger switch 200 so that the air is discharged to the air supply hole 130. As the bullet 141 is fired by air, the air pressure necessary for firing the bullet can be generated by the electric driving method using the solenoid valve 300 that opens and closes according to the electrical control signal, thereby destroying the target due to the shock. Aiming state can be prevented from being disturbed, the number of parts required for bullet firing can be minimized to reduce minor malfunctions, and the air gun can be lightened to increase portability.

In addition, unlike the conventional mechanical driving method in which the bullet speed is reduced due to the decrease in the impact force of the hammer 140 due to the decrease in the elastic restoring force of the hammer spring 144, the amount of air discharged to the bullet 141 by the opening operation of the electromagnetic valve 300 It has the advantage that the bullet speed does not change even after long-term use because it is constant.

Second, the air supply passage 311 includes an air injection hole 312 connected to the air tank 110 and into which air is injected, an air discharge hole 313 communicating with the air supply hole 130, An air storage chamber 314 communicating with the air injection hole 312 and the air discharge hole 313 and storing a certain amount of air is included, and the solenoid valve 300 has the air supply passage 311 inside. A valve body 310 having an air outlet 315 formed between the air storage chamber 314 and the air discharge hole 313 and having a guide groove 316 communicating with the air storage chamber 314; A plunger 320 inserted into the guide groove 316 and sliding and reciprocating within the valve body 310 selectively opens and closes the air outlet 315, and is wound around the guide groove 316 and controls the control unit. A structure for opening and closing the air outlet 315 is provided by including a coil 330 that forms a magnetic field when the control signal of 400 is applied so that the plunge 320 slides to open the air outlet 315. Simplify and reduce manufacturing cost.

Third, the plunger 320 is formed with a first air transfer hole 321 that is opened from the front end to the rear end in a sliding reciprocating direction and communicates the air storage chamber 314 and the guide groove 316, and the plunge 320 is pressurized toward the air outlet 315 by the air introduced into the guide groove 316 through the first air feed hole 321 and hermetically seals the air outlet 315, so that the air injection hole 312 Through this, it is possible to prevent the air injected into the air storage chamber 314 from leaking through the air discharge hole 313, and it is possible to maintain the high pressure of the air injected into the air storage chamber 314 and stored, so that the projectile speed set during the firing operation can be implemented. there is.

Fourth, the electromagnetic valve 300 further includes an elastic spring 340 disposed inside the guide groove 316 to press the plunge 320 toward the air outlet 315, and the plunge 320 When the magnetic field of the coil 330 disappears, it slides toward the air outlet 315 by the elastic restoring force of the elastic spring 340, and the plunge 320 is caused by the air introduced into the first air delivery hole 321. can be guided to move forward toward the air outlet 315, and in a backward-moving state, the plunge 320 is pressed forward by the high-pressure air introduced through the first air feed hole 321 to the air outlet ( 315), and it is possible to prevent the plunge 320 from colliding with the inside and generating noise while moving by its own weight in a state where air pressure does not act inside the air storage chamber 314. .

Fifth, a second air transfer hole 322 is formed inside the plunge 320 to communicate the first air transfer hole 321 and the guide groove 316, and the plunge 320 is a second air transfer hole. Compared to the case where only the first air delivery hole 321 is formed, the air outlet 315 is more airtightly sealed while being pressed toward the air outlet 315 by the air introduced into the guide groove 316 through the 322. As you can see, in order to press the plunger 320 toward the air outlet 315, the amount of air that needs to flow into the guide groove 316 is more quickly filled and the air outlet 315 closed by the plunger 320 is shortened. can do.

Sixth, the control unit 400 is an opening duration setting unit that drives and controls the solenoid valve 300 to open the air supply passage 311 only for a set opening duration when a trigger signal is input from the trigger switch 200. By including 440, the solenoid valve 300 can be opened to discharge the minimum amount of air required to fire the bullet 141 at an appropriate bullet speed regardless of the time the user presses the trigger switch 200, and the discharge Even after the bullet 141 is fired by the released air, the air outlet 315 is opened to prevent unnecessary waste of air in the air tank 110, and it is necessary to repeat the disassembly and assembly of the gun to adjust the bullet speed. Unlike the existing mechanical driving method, the bullet speed of the bullet 141 can be easily adjusted by setting and changing the opening duration of the electronic valve 300 .

Seventh, the control unit 400, during the set double trigger prevention time after the trigger signal of the trigger switch 200 is input or after the control signal is output to the solenoid valve 300, reloads from the trigger switch 200. By further including a double trigger prevention time setting unit 450 that controls driving so that the solenoid valve 300 does not open and close by ignoring the input trigger signal, the user triggers ( 120) can be prevented from being discharged in a state where the bullets 141 are not loaded by double triggering, and accordingly, the use time of the air tank 110, which has a limited capacity, can be significantly increased. there is.

Eighthly, the control unit 400 has a display 470 displaying a set time 481 set as the opening duration and a set time 482 set as the double trigger prevention time, and each set time 481, 482 according to user manipulation. ) and a control unit 480 for outputting a user control signal for adjusting the control unit 480, and by changing the set times of each set time 481 and 482 according to the operation signal of the control unit 480, the user can use the shooting environment or personal cooking. It is possible to easily adjust the projectile speed according to the selection, and by adjusting the double shooting prevention time according to the user's double shooting habit, it is possible to provide optimized shooting conditions for each user.

Ninth, when a trigger signal is input from the trigger switch 200, the control unit 400 controls the driving of the solenoid valve 300 to open the air supply passage 311 after a set firing delay time elapses. By further including the time setting unit 460, even if the muzzle is distorted during a firing operation, time for returning the distorted muzzle direction before the bullet 141 is fired can be provided.

1 is a cross-sectional side view showing the overall configuration of an air gun using an electronic valve according to a preferred embodiment of the present invention;
2 is a side cross-sectional view showing the main configuration of an air gun using an electronic valve according to a preferred embodiment of the present invention;
3 is a side cross-sectional view showing the configuration of an electromagnetic valve according to a preferred embodiment of the present invention;
4 is a cross-sectional side view showing a state in which a trigger switch is operated by a trigger action of a trigger according to a preferred embodiment of the present invention;
5 to 7 are side cross-sectional views for explaining the operating principle of the solenoid valve according to a preferred embodiment of the present invention;
8 is a block diagram showing the functional configuration of a control unit according to a preferred embodiment of the present invention;
9 is a plan view showing the external configuration of a control unit according to a preferred embodiment of the present invention;
10 is a schematic diagram showing various set times displayed on a display according to a preferred embodiment of the present invention;
11 and 12 are side cross-sectional views showing the configuration and operation principle of an air gun according to the prior art.

Objects, features and advantages of the present invention described above will become more apparent through the detailed description that follows. Hereinafter, a preferred embodiment of the present invention will be described based on the accompanying drawings.

An air gun 1 using a solenoid valve according to a preferred embodiment of the present invention is an air gun that generates air pressure required for bullet firing by an electric driving method using an solenoid valve, and as shown in FIGS. 1 and 2, the gun body 100 ), a trigger switch 200, an electromagnetic valve 300 and a control unit 400.

First, the gun body 100 forms a housing of the air gun 1 and is a base member on which each component is mounted. An air tank 110 in which high-pressure air is stored is coupled to the front side and a trigger 120 for triggering action is attached to the lower side. Is provided and an air supply hole 130 opened to the rear position of the loaded bullet 141 is formed inside. Here, the gun barrel 101, which extends forward and backward and is a passage through which the fired bullet 141 moves, is provided on the front side of the gun body 100, and a butt plate 102 for supporting the user's shoulder when shooting is provided on the rear side. are provided

In addition, as shown in FIG. 2, a magazine 140 into which a plurality of bullets 141 are inserted is provided on the upper side of the gun body 100, and the bullets 141 inserted into the magazine 140 are attached to the loading handle 150. It is separated from the magazine 140 and moved to the loading position inside the gun body 100 while being pushed forward by the push rod 151 moving forward and backward. In addition, the gun body 100 is provided with a power supply unit 500 that provides driving power necessary for driving the electronic valve 300 and the control unit 400, and the power supply unit 500 is a battery for portability of the air gun 1. can be made in the form

The trigger switch 200 detects when the trigger 120 triggers, generates a trigger signal, and outputs the trigger signal to the control unit 400 by being connected to the control unit 400 through a signal line L1. Here, the triggering action means a user's action of pressing the trigger backward with a finger, and as shown in FIG. It can be made in the form of a push button (switch) that outputs a trigger signal while being pressed by a part of the trigger 120, and in addition, an optical sensor or a magnetic sensor that detects a contacted state or a proximity state with a part of the trigger 120 , various sensors such as ultrasonic sensors may be used.

The electronic valve 300 is a valve that regulates the air pressure required to fire the loaded bullet 141, and as shown in FIGS. 2 and 3, the air tank 110 and air on the gun body 100 It is disposed between the supply holes 130 to form an air supply passage 311 for discharging the air injected from the air tank 110 to the air supply hole 130, and supplies the air according to a control signal from the control unit 400. The flow path 311 is selectively opened and closed.

More specifically, the air supply passage 311 includes an air injection hole 312 connected to the air tank 110 and into which air is injected, and an air discharge hole communicating with the air supply hole 130 ( 313) and an air storage chamber 314 communicating with the air injection hole 312 and the air discharge hole 313 and storing a certain amount of air, and the solenoid valve 300 includes a valve body 310, It includes a plunger 320 and a coil 330. In addition, the solenoid valve 300 is preferably an NC type (Normally Closed Type) valve that closes the flow path when a control signal is not input and opens the flow path when a control signal is input.

The air supply passage 311 is formed inside the valve body 310, an air outlet 315 is formed between the air storage chamber 314 and the air discharge hole 313, and the air storage chamber 314 and the front and rear A guide groove 316 communicating with is formed.

The plunge 320 is inserted into the guide groove 316 and selectively opens and closes the air outlet 315 while sliding and reciprocating in the front and rear directions within the valve body 310 . The coil 330 is wound around the guide groove 316, and when a control signal is applied from the control unit 400, a magnetic field is formed to pull the plunger 320 backward, so that the plunger 320 moves through the air outlet. Slide to open 315. Here, a signal line L2 is provided between the coil 330 and the control unit 400 so that the control signal output from the control unit 400 can be input to the coil 330, and the control signal is transmitted through the coil 330. It may be a driving power source for forming a magnetic field.

Therefore, as shown in FIG. 3 , when a control signal is output from the controller 400 in a state in which the plunge 320 moves forward to close the air outlet 315, the coil 330 responds to the input control signal. As shown in FIG. 5, the air outlet 315 closed by the plunge 320 while the plunge 320 is pulled backward (the position where the coil 330 is disposed) and moves, as shown in FIG. ) is opened, and the air stored in the air storage chamber 314 is discharged to the rear position of the bullet 141 through the air outlet 315, the air outlet hole 313, and the air supply hole 130 of the gun body 100. As the bullet 141 can be fired.

In addition, as shown in the drawing, a sealing member 323 made of rubber or silicon is provided at the end of the plunger 320 in contact with the air outlet 315 to further increase the airtightness of the air outlet 315. there is.

The control unit 400 controls the timing at which air compressed by the bullet 141 loaded by the opening operation of the solenoid valve 300 is discharged, that is, the timing at which the bullet 141 is fired, and the trigger switch ( When a firing signal is input from 200, the solenoid valve 300 controls driving to open the air supply passage 311 so that the bullet 141 is fired by the air discharged through the air supply hole 130.

To this end, as shown in FIG. 8 , the controller 400 includes a signal input unit 410 to which the trigger signal of the trigger switch 200 is input, a power input unit 420 to which driving power is input from the power supply unit 500, and , and a valve driving unit 430 that controls the opening and closing operation of the solenoid valve 300 according to the input trigger signal.

Including the signal input unit 410, the power input unit 420, and the valve driving unit 430, an opening duration setting unit 440, a double trigger prevention time setting unit 450, and a firing delay time setting unit 460 to be described below As shown in FIG. 9 , the control unit 480 and the control unit 480 may implement respective functions with a combined configuration of component elements configured as circuits on the PCB 490 . The signal input unit 410 is circuit-connected to the signal input terminal 411 signal-connected to the signal line L1 to receive a trigger signal output from the trigger switch 200, and the power input unit 420 is connected to the power supply unit 500. A circuit is connected to the connected power input terminal 421 to receive driving power output from the power supply unit 500, and the valve driving unit 430 circuits to the signal output terminal 431 signal-connected to the coil 330 of the solenoid valve 300. It is connected to output a control signal according to the reception of the trigger signal so that a magnetic field can be formed in the coil 330.

Through the combination of the above-described gun body 100, trigger switch 200, electronic valve 300, and control unit 400, bullets are operated by an electric driving method using an electronic valve 300 that opens and closes according to an electrical control signal. It is possible to generate the air pressure required for firing, and through this, compared to the conventional mechanical drive method using the hammer 140 and the hammer spring 144, the aiming state aimed at the target due to the shock of the shot can be prevented from being disturbed. It is possible to reduce the number of parts required for bullet firing to reduce minor malfunctions, and to increase portability by lightening the air gun.

In addition, in the conventional mechanical driving method, the user must perform a firing preparation process in which the loading handle 150 is tilted backward and fixed with a large force capable of compressing the highly elastic hammer spring 144, but the electric driving method of the present invention When the triggered trigger 120 is released, air is automatically injected into the air storage compartment 314 and air pressure is generated, so the user does not need to perform a separate firing preparation process, maximizing user convenience.

In addition, unlike the conventional mechanical driving method in which the bullet speed is reduced due to the decrease in the impact force of the hammer 140 due to the decrease in the elastic restoring force of the hammer spring 144, the amount of air discharged to the bullet 141 by the opening operation of the electromagnetic valve 300 It has the advantage that the bullet speed does not change even after long-term use because it is constant. In addition, since the hammer 140 or the hammer spring 144 is not provided, even if the air gun 1 is dropped or a strong impact is applied to the gun body 100, the hammer 140 is released from the fixed state of retraction, and misfire occurs. Accidents can be prevented. In addition, through the configuration of the solenoid valve 300 including the valve body 310, the plunger 320 and the coil 330, the structure for opening and closing the air outlet 315 in an electric drive method is simplified and the manufacturing cost is reduced. can save

On the other hand, the solenoid valve 300 uses the air pressure of the air tank 110 flowing into the air injection hole 312 after the air stored in the air supply hole 130 is discharged and the bullet 141 is fired to plunge. The air outlet 315 may be sealed by moving the air outlet 320 forward toward the air outlet 315 .

To this end, as shown in FIG. 7, the plunge 320 is opened from the front end to the rear end in the forward and backward direction of sliding reciprocation, and the first air transfer hole communicates the air storage chamber 314 and the guide groove 316. 321 is formed, and the plunge 320 is pressed toward the air outlet 315 by the air introduced into the guide groove 316 through the first air feed hole 321 to seal the air outlet 315. tightly sealed.

Due to the configuration of the first air delivery hole 321, air injected into the air storage chamber 314 through the air injection hole 312 can be prevented from leaking into the air discharge hole 313, and It is possible to maintain the high pressure of the injected and stored air, so that the projectile speed set during the firing operation can be realized.

In addition, the air injected from the air tank 110 through the air injection hole 312 while the air outlet 315 is closed fills the air storage chamber 314 and responds to the air supply pressure of the air tank 110. When the air pressure in the air storage chamber 314 increases to a certain extent, air supply from the air tank 110 is stopped. In addition, since the air pressure of the air discharged to the bullet 141 varies depending on the volume of the air storage chamber 314, it is preferable that the volume of the air storage chamber 314 is determined according to the type of bullet 141 or the required bullet speed. .

The solenoid valve 300 further includes an elastic spring 340 disposed inside the guide groove 316 to press the plunge 320 toward the air outlet 315, and the plunge 320 can slide toward the air outlet 315 by the elastic restoring force of the elastic spring 340 when the magnetic field of the coil 330 disappears.

Accordingly, the air introduced into the first air transfer hole 321 may guide the plunge 320 to move forward toward the air outlet 315, and in a state in which the plunge 320 moves backward, the first It is possible to prevent strong collision between the plunger 320 and the air outlet 315 while being pressurized forward by the high-pressure air introduced through the air feed hole 321, and air pressure does not act inside the air storage chamber 314. It is possible to prevent the plunge 320 from generating noise by colliding with the inside while moving by its own weight in a state of no movement.

In addition, a second air transfer hole 322 is formed inside the plunge 320 to communicate the first air transfer hole 321 and the guide groove 316, and the plunge 320 is a second air transfer hole ( 322) while being pressed toward the air outlet 315 by the air introduced into the guide groove 316, the air outlet 315 can be more airtightly sealed. Accordingly, only the first air delivery hole 321 is formed. Compared to the case, the air outlet 315 is sealed by the plunge 320 by filling the air amount to be introduced into the guide groove 316 more quickly in order to press the plunge 320 toward the air outlet 315. time can be shortened.

On the other hand, when the air outlet 315 is opened while the trigger switch 200 is operated by the trigger 120 due to the triggering operation of the trigger 120, the amount of air that falls short of or exceeds the amount of air required to fire the bullet 141 is air. Discharged through the supply hole 130, the range of the bullet 141 may be shortened or may exceed a prescribed bullet speed.

For example, when the amount of air required to fire the bullet 141 at an appropriate bullet speed is 100 and the time required to keep the air outlet 315 open in order to discharge the air amount of 100 to the air supply hole 130 is 50 ms , When the user presses the trigger 120 for 30 ms and the air outlet 315 is opened for only 30 ms, an air amount of less than 90 is discharged through the air supply hole 130, and the user presses the trigger for 80 ms to open the air outlet 315. When is opened for 80 ms, an air amount of 110 or more can be discharged through the air supply hole 130. Accordingly, in the air gun 1 according to a preferred embodiment of the present invention, it is possible to control an appropriate amount of air to be discharged through the air outlet 315 regardless of the time for which the user presses the trigger 120 and maintains the triggering action.

To this end, as shown in FIG. 8 , the controller 400 controls the solenoid valve 300 to open the air supply passage 311 only for a set opening duration when a trigger signal is input from the trigger switch 200. An opening duration setting unit 440 for driving control is included. Here, the open duration time refers to the time required to keep the air outlet 315 open based on an appropriate amount of air for launching the bullet 141 at an appropriate projectile speed and range.

Through this opening duration setting function, the air outlet 315 can be opened so that the minimum amount of air required to fire the bullet 141 at an appropriate bullet speed is discharged regardless of the length of time the user presses the trigger switch 200. For example, the solenoid valve 300 operates only for a set 50 ms regardless of the time during which the user presses the trigger 120 for 30 ms or 80 ms, and the bullet 141 is fired at an appropriate bullet speed. The required amount of air 100 can be discharged through the air outlet 315 .

In addition, even after the bullet 141 is fired by the discharged air, the air outlet 315 is opened to prevent unnecessary waste of air in the air tank 110, and it is possible to disassemble and assemble the firearm to adjust the bullet speed. Unlike conventional mechanical driving methods that must be repeated, the bullet velocity of the bullet 141 can be easily adjusted by setting and changing the opening duration of the electronic valve 300 .

Meanwhile, as shown in FIG. 8 , the control unit 400, during the set double trigger prevention time after the trigger signal of the trigger switch 200 is input or after the control signal is output to the solenoid valve 300, A double trigger prevention time setting unit 450 configured to drive and control the solenoid valve 300 not to open and close by ignoring the trigger signal re-inputted from the trigger switch 200 may be further included.

For example, when the double trigger prevention time is set to 60 ms and the user triggers the trigger 120 while the bullet 141 is loaded, a trigger signal is input from the trigger switch 200 to the control unit 400. Even if the user triggers the trigger 120 again for 60 ms from the time point when the control unit 400 outputs the control signal to the solenoid valve 300 according to the input of the triggering signal or the triggering signal, the triggering signal is input to the control unit 400. The solenoid valve 300 is not operated by the triggered trigger signal, and the solenoid valve 300 is controlled to be operated only by the trigger signal input after the set 60 ms has elapsed.

Through this double trigger prevention time setting function, air is discharged while the bullet 141 is not loaded by double trigger in which the user triggers the trigger 120 multiple times for one loaded bullet 141 when shooting. It is possible to prevent this from happening, and accordingly, the use time of the air tank 110, which has a limited capacity, can be significantly increased.

In addition, as shown in FIGS. 9 and 10 , the control unit 400 displays a display 470 for displaying a set time 481 set as the opening duration and a set time 482 set as the double trigger prevention time. And, further comprising a control unit 480 outputting a user manipulation signal for adjusting each set time (481, 482) according to the user's manipulation, wherein the set time of each set time (481, 482) according to the control signal of the control unit (480) can be changed.

Therefore, the user can easily adjust the projectile speed according to the shooting environment or personal choice, and the user can provide optimized shooting conditions for each user by adjusting the double shooting prevention time according to the user's double shooting habit.

On the other hand, normally, during the triggering action, the trigger 120 is pressed with the tip of the index finger (fingerprint) in a state where the muzzle is pointed at the target to the extent possible to rotate. At this time, excessive force is applied to the index finger or the index finger When the rotation range of the finger becomes longer, a force that presses the trigger 120 to the side is generated, so that the muzzle is twisted to the right (for a right-handed person) or to the left (for a left-handed person). Accordingly, the control unit 400 can provide time to restore the distorted muzzle direction before the bullet 141 is fired, even if the muzzle is distorted during the firing operation as described above.

To this end, as shown in FIG. 8 , the control unit 400, when a triggering signal is input from the triggering switch 200, sets the solenoid valve 300 to the air supply passage 311 after the set firing delay time has elapsed. It may further include a launch delay time setting unit 460 for driving control to open.

For example, when the firing delay time is set to 10 ms and the box triggers the trigger 120, the controller 400 controls the solenoid valve at the time when 10 ms has elapsed from the time the trigger signal is input from the trigger switch 200. A control signal is output to 300 to control the bullet 141 to be fired. Therefore, even if the muzzle direction is distorted by the pressing force of the index finger during the user's firing operation, the distorted muzzle direction can be rearranged to the original position during the firing delay time of 10 ms.

In addition, although not shown, a speaker is provided in the gun body 100, and the control unit 400 outputs a notification sound such as a buzzer through the speaker when the trigger 120 is triggered and a trigger signal is input from the trigger switch 200. It may be provided so that the user can recognize the timing at which the trigger 120 is triggered.

In addition, the display 470 further displays the set time 483 set as the launch delay time, and the control unit 480 outputs a user manipulation signal for adjusting the set time 483 according to the user manipulation, , The control unit 400 can change the set time of the set time 483 according to the operation signal of the control unit 480, so user convenience can be further increased. In addition, the display 470 can provide various information necessary for the user while using the air gun 1 , such as the cumulative usage time 484 and the number of bullets fired 485 using the air gun 1 .

The present invention described above is not limited by the foregoing embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible within a range that does not depart from the technical spirit of the present invention. It will be clear to those who have knowledge.

1...Air gun using an electronic valve
100 ... gun body 110 ... air tank
120 ... trigger 130 ... air supply hole
200 ... trigger switch 300 ... solenoid valve
310 ... valve body 311 ... air supply passage
312 ... air injection hole 313 ... air discharge hole
314 ... air storage compartment 315 ... air outlet
320...Plunge 321...First air transfer hole
322 ... second air transfer hole 330 ... coil
340 ... elastic spring 400 ... control unit
440 ... opening duration setting unit 450 ... double trigger prevention time setting unit
460 ... launch delay time setting unit

Claims (5)

A firearm in which an air tank 110 storing high-pressure air is coupled to one side, a trigger 120 for triggering action is provided on the other side, and an air supply hole 130 opened to the rear position of a loaded bullet 141 is formed inside. body 100; a trigger switch 200 outputting a trigger signal when the trigger 120 triggers; An air supply passage 311 disposed between the air tank 110 and the air supply hole 130 in the gun body 100 to discharge the air injected from the air tank 110 to the air supply hole 130. ) and an electronic valve 300 for selectively opening and closing the air supply passage 311 according to a control signal; And when a triggering signal is input from the triggering switch 200, the solenoid valve 300 controls driving to open the air supply passage 311, and the bullet 141 is fired by the air discharged through the air supply hole 130. Including; a control unit 400 that causes the launch,
The air supply passage 311 includes an air injection hole 312 connected to the air tank 110 and into which air is injected, an air discharge hole 313 communicating with the air supply hole 130, and the air An air storage chamber 314 communicating with the injection hole 312 and the air discharge hole 313 and storing a certain amount of air,
In the solenoid valve 300, the air supply passage 311 is formed inside, an air outlet 315 is formed between the air storage chamber 314 and the air discharge hole 313, and the air storage chamber 314 and A valve body 310 having a communicating guide groove 316, and a plunger inserted into the guide groove 316 and selectively opening and closing the air outlet 315 while sliding and reciprocating in the valve body 310 ( 320) and a coil that is wound around the guide groove 316 and forms a magnetic field when a control signal from the control unit 400 is applied to slide the plunge 320 to open the air outlet 315 ( 330), an air gun using an electronic valve.
The method of claim 1,
The plunger 320 is formed with a first air transfer hole 321 that is opened from the front end to the rear end in a sliding reciprocating direction and communicates the air storage chamber 314 and the guide groove 316,
The plunge 320 is pressed toward the air outlet 315 by the air introduced into the guide groove 316 through the first air feed hole 321 to airtightly seal the air outlet 315. Air gun using electronic valve.
The method of claim 2,
The solenoid valve 300 further includes an elastic spring 340 disposed inside the guide groove 316 to press the plunge 320 toward the air outlet 315,
The plunger 320 slides toward the air outlet 315 by the elastic restoring force of the elastic spring 340 when the magnetic field of the coil 330 disappears.
The method of claim 3,
A second air delivery hole 322 is formed inside the plunge 320 to communicate the first air delivery hole 321 and the guide groove 316,
The plunge 320 is pressed toward the air outlet 315 by the air introduced into the guide groove 316 through the second air feed hole 322 to seal the air outlet 315 more airtightly. An air gun using a solenoid valve.
The method of claim 1,
The controller 400,
and an opening duration setting unit 440 that drives and controls the solenoid valve 300 to open the air supply passage 311 only for a set opening duration when a trigger signal is input from the trigger switch 200. An air gun using a solenoid valve.

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