KR920000395Y1 - Air gun - Google Patents

Abstract

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Description

air gun

1 is a cross-sectional view showing a structure for a conventional air gun.

Figure 2 is a cross-sectional view showing the internal structure of the air gun according to the present invention.

3 is an enlarged view of a portion A according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: air gun 4: ammunition

5: compression cylinder 6: gas container

9: trigger 10: ball

11 piezoelectric element 12 igniter

13: explosion chamber 14: leaf spring

18: piston 18a: piston rod

22,23 shank ball 24: nozzle

26: rubber packing 27: gas hole

28: spring

The present invention relates to an air gun that fires a bullet at pneumatic pressure. In particular, an air gun that fires a bullet with explosive power generated by ignition by mixing air from a cylinder with butane gas or propane gas filled in a commercially available gas container. It is about.

In order to fire a bullet from a conventional air gun, as shown in FIG. 1, a compression cylinder 101 is formed in the air gun 100 to incorporate a piston 104 capable of sucking and compressing air therein. Inter-link 103 and inter-operation 102 are provided for moving the piston forward or backward. Therefore, when the user pushes or pulls the operation section 102, the link section 103 leads the piston 104 to move forward or backward according to the moving state, and when the piston 104 moves forward by this operation, Air is sucked into the compression cylinder 101 and when retracted, the air sucked into the compression cylinder is compressed to a certain (adequate to fire bullet) pressure.

In this conventional air compression method, a large amount of air must be generally compressed in order to put a launchable pressure drop, and thus, four to five dumping operations are required for one shot. When the trigger of the air gun is pulled by the above configuration, a bullet loaded with compressed air is fired. The bullet fired in this process maintains a super long range of about 70M, but because the bullet is fired only by air pressure, the bullet speed was not strong. The problem related to the bullet speed, in turn, was greatly influenced by the ambient conditions (wind) acting at the time of shooting, causing the shooting accuracy to drop.

Therefore, the present invention was devised to solve the above problems with a small amount of explosive force of air and gas, and an explosion chamber including a filling chamber in addition to the compression cylinder is connected to the compression cylinder, and the ignition device and the pressure control in case of explosion Equipped with a device and a small gas cylinder connecting device having a firing function described in detail with the accompanying drawings as follows.

As shown in FIG. 2, an explosion chamber 13 having an ignition device and a gas container connection is provided in an ammunition chamber 4 capable of carrying a bullet 25 and a compression cylinder 5 capable of sucking and compressing external air. ) Is formed in the latter half of the barrel (2), and in forming the explosion chamber (13), the connecting passage (20) and the compression cylinder (5) for exporting the explosive force to the ammunition chamber (4) of the barrel (2). The supply passage 19 for receiving the compressed air from the air is formed in the upper and lower front portions of the explosion chamber 13, respectively, and the barrel of the ammunition chamber 4 and the compression cylinder 5 are formed in the explosion chamber ( 13), and the other side of the rear half of the explosion chamber 13 is formed with a fastening portion 15 for coupling or separating the small gas cylinder filled with the ignition compressed gas.

Inside the explosion chamber 13, a leaf spring 14 across the explosion chamber 13 and an igniter 12 connected to the ignition device are installed, and the leaf spring 14 is disposed inside the explosion chamber 13. At a point approximately two-thirds of the direction of the passageway 20 of the ammunition chamber, and the igniter 12 is located in front of the passageway 20 and the passageway 19 of the compression cylinder and in front of the leaf spring 14. Install on bottom of explosion chamber (13). The igniter 12 is connected to a piezoelectric element which is an ignition device. In addition, inside the explosion chamber 3 in which the plate ring 14 and the igniter 12 are installed, a piston 18 which slides back and forth with the explosive force and the momentary earth output of the compressed gas is provided, but the piston rod 18a is usually used for ammunition. It is located at the inlet of the passage 20 of the seal, and the piston head 18b is partitioned between the leaf spring 14 and the explosion chamber 13 to form a mixing chamber 13a between the head of the ammunition chamber passage 20. And between the fastening portions 15 of the explosion chamber 13 in the head 18b. The filling chamber 13b is formed between the fastening portions 15 of the explosion chamber 13 in the piston head 18b.

The passage 19 of the compression cylinder 13 of the explosion chamber 13 and the passage 21 of the piston head 18b having such a configuration prevent the explosion pressure from leaking to anything other than the passage 20 of the ammunition chamber. Brush the balls 22 and 23 together with the springs. In addition, the coupling portion 15 formed on the other side of the explosion chamber 13 is coupled to the gas container 6 filled with ignition compressed gas (butane gas or propane gas, for example) at a pressure of, for example, 5 kg / cm 2. In the gas container 6, a fixing part 6a configured to be screwed to the fastening part 15 is protruded, and a compressed gas discharge nozzle 24 is provided at the tip of the fixing part 6a. . The compressed gas discharge nozzle 24 is installed so as to be elastic between the rubber packing 26 of the fixed part and the compression spring 28 in the container, and is closed in the forward direction and opened in the reverse direction. ) Is an air gun having a nozzle 24 configured to be bent vertically.

The present invention made of such a configuration, by sucking the outside air is supplied to the explosion chamber 13 to be mixed with the filled gas and then ignited by the spark igniter 12 to explode the mixed gas, the piston part by the explosion force As the piston 18 moves backward, the piston rod 18a moves backward, and at this time, the explosive force is transmitted to the passage 20 which was normally blocked by the piston rod 18a, so the bullet 25 of the ammunition chamber is fired with the explosive force, When the user grabs the air gun and pushes the operation section 8 of the air gun 1 forward, the piston 5a moves forward in front of the muzzle, while the outside air is sucked into the compression cylinder 5, and the operation section 8 is pulled in by pulling the operation section 8 forward. The air is compressed, and the compressed air continuously pushes the check ball 22 to supply compressed air to the mixing chamber 13a of the explosion chamber 13. Therefore, the compressed air is mixed with the gas (butane gas) supplied from the gas container 6 in the mixing chamber 13a.

Thereafter, the bullet 25 is inserted into the chamber 4 and aimed to pull the trigger 9 so that the ball 10 of the trigger hits the piezoelectric element 11 that is the ignition device, thereby causing the spark to splatter the igniter 12. do. This flame causes the mixed gas to explode and the piston 18 retreats when the pressure in the gas mixing chamber 13a momentarily expands, so the piston rod 18a retreats from the through hole 20 to open the passage 20. When the explosion pressure is released through the passage that opens the bullet 25 loaded in the chamber (4).

When the pressure is expanded during the explosion process, the leaf spring 14 moves to the dotted line position of FIG. 2 and the piston 18 is pushed backward to compress the pressure in the gas filling chamber 13b. At this time, the rising compression force pushes the check ball 23 toward the front barrel. Accordingly, the spring located in the passage 21 of the piston head 18b contracts forward. As a result, the gas in the gas layer chamber 13b is the piston 18. The gas mixture chamber 13a is moved to the gas mixing explosion chamber 13a through the passage 21, and the gas mixture chamber 13a is filled with gas again, and the waste gas remaining in the gas mixing explosion chamber 13a is pushed in and is still open. After acting out of the passage of the ammunition chamber, the gas pressure filled in the gas filling chamber pushes the check ball 23 of the piston head to close the open passage 21 again.

During the movement of the piston 18, the piston head 18b pushes back and pushes the nozzle 25 of the gas container 6 located in the gas filling chamber 13b, so that the gas hole 27 of the nozzle 24 is moved. When the rubber packing 26 is opened and the compressed gas in the container is filled in the gas filling chamber 13b through the gas hole 27, the retracted piston 18 is advanced again, so that the piston rod 18a of the ammunition chamber When the fitting is inserted into the passage 20, the gas is filled in the filling chamber 13b while the advancing is stopped. That is, if the pressure in the gas mixing explosion chamber 13a is 3 kg / cm 2 before the explosion process in the gas mixing explosion chamber 13a is 3 kg / cm 2, the pressure in the gas filling chamber 13b is 3 kg / cm 2, for example, the small gas container 6. While the pressure inside is maintained at 5 kg / cm 2, when the mixed gas explodes, the pressure at the time of gas mixing explosion 13a is increased from 3 kg / cm 2 to 8 kg / cm 2 instantaneously to push the piston 8. When the piston 18 is pushed down, the passage 20 of the ammunition chamber is opened, maintaining a pressure of 3 kg / cm 2, the gas filling chamber 13b is compressed, the nozzle of the gas container is retracted, and the gas mixing explosion chamber 13a. 8 kg / cm 2 of the pressure is temporarily released into the open passage 20 to fire the bullet 25, so that the pressure in the gas mixture explosion chamber 13a becomes 0 kg / cm 2 again.

Therefore, the pressure of the gas filling chamber 13b, which is further compressed by the piston, for example, 5 kg / cm 2, pushes the passage 21 of the check ball 22 to open the gas mixing explosion chamber 13b. Since the gas introduced into the gas container 6 is introduced into the gas filling chamber 13b, the pressure of the gas mixing explosion chamber 13a is again 3 kg / cm 2 and the pressure of the filling chamber is also 3 kg / cm 2.

As described above, the present invention mixes butane or propane gas with air and supplies it to the explosion chamber of the air gun and ignites the spark generated by the piezoelectric element by the blow of the trigger, so that the bullet is fired by the explosive force due to the instantaneous explosion, The maximum range and effective range naturally increase, which not only improves the firing power of the air gun, but also improves the firing speed of the bullet and significantly reduces the size of the trigger ball. In addition, the performance of the air gun can also be improved.

Claims (1)

In the air gun for explosive operation of the gas mixed in the explosion chamber 13 by the supply of compressed air by the operation period 8 and the supply of explosive fuel gas by the separate gas container 6, the explosion chamber ( 13) a leaf spring 14 which traverses vertically; A piston rod 18a penetrating through the leaf spring 14 and the tip thereof blocks the passage 20 of the barrel 2, and the explosion chamber 13 includes a gas mixing chamber 13a and a gas filling chamber 13b. A piston (18) having a piston head (18b) separated by; And a head passage 21 having a spring and a check ball 23 in the piston head 18b, and a gas hole 27 in the fastening portion 15 of the larynx of the gas filling chamber 13b. Air gun, characterized in that the configuration to be connected to the gas container (6) having a nozzle (24) rubber packing (26) having a) and a spring (28) and a fixed portion (6a) installed.