KR102317184B1 - Double air compression multipurpose launcher - Google Patents

Abstract

The present application relates to an air chamber for storing compressed air; a piston provided in the chamber to move backward to primarily compress air; and an air compressor provided outside the chamber for secondary compression of air, wherein the compressed air is fired to the first exhaust unit provided in front of the air chamber to forward the projectile. Compression multipurpose launcher.

Description

Double air compression multipurpose launcher {DOUBLE AIR COMPRESSION MULTIPURPOSE LAUNCHER}

The present application relates to a multi-purpose launcher, and more particularly, to a multi-purpose launcher using compressed air.

The color guns used in conventional ships use gunpowder to increase the firing range, but they are fired accidentally because there is no fire safety device, resulting in burns or injuries, or when the expiry date of the gunpowder expires, the firing range is shortened or misfired. there was a problem with In addition, since the price of the accessories is high, there is a problem in that the cost is high even when used once.

In addition, there are cases in which the reaching distance of the projectile cannot be estimated, so the reaching distance is too long or rather short, so that the hull or the wheelhouse is struck. There is a problem in that the projectile is not fired accurately in a desired direction and location due to poor directionality, and a lot of accessories are used while firing multiple times, which incurs a lot of cost.

When a vessel breaks down at sea, another vessel tows the broken vessel to the repair dockyard or port. In the process of connecting to another ship, the two-color gun was fired and handed over. If the two ships could not get close because the ship was large or the weather was bad, it was impossible to use the heaving line that a person threw and hand over the rope. There was a problem.

Republic of Korea Patent Publication No. 10-2008-0077745 (2008.08.26.)

In order to solve the above problems, the present application is to provide a multi-purpose launcher capable of accurately firing a target to a desired distance.

In addition, the present application is to provide a multi-purpose launcher with high safety, easy storage, high portability, and economical in terms of cost.

In order to solve the above problems, an embodiment of the present application is a housing; an air chamber provided inside the housing and storing compressed air; a piston provided inside the chamber to move backward to primarily compress air in the air chamber; an air compressor provided outside the chamber for secondary compression of primary compressed air; a bolt disposed above the chamber to guide the movement of the piston; a locking jaw mounted on the lower surface of the chamber to fix the piston moved backward; and a connection nozzle disposed in front of the locking jaw and connecting the air compressor and the air chamber. and, after first compressing the air in the air chamber by moving the piston backward, operating the air compressor connected to the connection nozzle to secondarily compress the air in the air chamber, It provides a dual-air compression multi-purpose launcher, characterized in that by firing compressed air to the provided first discharge unit to forward the projectile.

delete

In one embodiment of the present application, the projectile guide tube is disposed in the front portion of the chamber, the compressed air is injected from the second discharge portion of the end; and a vertical sliding valve for connecting or blocking the first discharge unit provided in the front of the chamber and the inlet of the projectile guide tube through a hole provided therein.

In an embodiment of the present application, the first exhaust portion of the air chamber may form a venturi section, and an end diameter of the first exhaust portion may be larger than an inlet end diameter of the projectile guide tube.

In an embodiment of the present application, the vertical sliding valve is fixed to the inside of the housing by a compression spring connected thereto, and the diameter of the hole is equal to or smaller than the first outlet end diameter and equal to or larger than the inlet end diameter. can

In an embodiment of the present application, a trigger hingedly provided at the front of the handle; and a rod connected to the trigger and arranged horizontally on the lower part of the housing, and when the trigger is pulled, the rod end moves the sliding valve upward while the rod moves forward to open the hole, and at the same time, the locking jaw connected to the trigger by moving downward, the piston moves forward and the compressed air is injected to the second discharge unit to fire the projectile.

In one embodiment of the present application, it is disposed in the lower portion of the chamber, it may further include a handle having an air compressor and a battery therein.

In one embodiment of the present application, it is mounted on the front inner peripheral surface of the chamber may further include two or more piston support for supporting the piston moving forward during firing.

In an embodiment of the present application, the piston support may be spaced apart from each other on the front inner circumferential surface of the air chamber and disposed at the same distance from each other.

In an embodiment of the present application, the piston includes a protrusion accommodating part formed through the central portion of the piston, and the protrusion accommodating part is coupled with a protrusion provided to protrude into the rear end of the air chamber when the piston moves backward. Air can be sealed.

In an embodiment of the present application, the air compressor, an input unit for inputting a desired firing distance or a desired pressure; a display unit indicating the firing distance or pressure; and a control unit.

delete

In an embodiment of the present application, it further comprises a target into which the target guide tube is inserted, wherein the projectile includes: a tubular body into which the guide tube can be inserted; and a plurality of wing portions projecting radially from the outer circumferential surface of the body portion and formed at the same distance from each other.

In one embodiment of the present application, the projectile may be provided with a head in front of the body portion that can be replaced with a head for throwing a heaving line, a head for towing color transfer, a head for lifesaving or a head for a shogun.

The dual air compression multipurpose launcher of the present application provides the following effects.

First, it has the advantage of reducing the possibility of causing a safety accident compared to the existing gunpowder-type launcher when launching using the air compression method.

Second, it has the advantage of being able to reach a long distance by double-compressing the air, and controlling the distance by adjusting the pressure using the digital compression method.

Third, there is an effect of improving straightness in a desired direction due to the wing portion of the projectile.

Fourth, the launcher can be used for various purposes because the head of the projectile can be replaced according to the purpose of use.

1 is a cross-sectional view showing a dual air compression multi-purpose launcher according to an embodiment of the present application.
2 is a cross-sectional view illustrating a state in which a target is coupled to a launcher according to an embodiment of the present application.
3 is a cross-sectional view showing the flow of air according to the shape of the chamber according to an embodiment of the present application.
4 is a cross-sectional view illustrating an air flow in a closed state and an open state of the first discharge part of the chamber according to the movement of the sliding valve according to an embodiment of the present application.
5 is a view showing a trigger and a rod according to an embodiment of the present application.
6 is a view showing a trigger and a latching jaw according to an embodiment of the present application.
7 is a view illustrating a protrusion in a chamber and a protrusion accommodating part provided in a piston according to an embodiment of the present application.
8 is a view showing an input unit and a display unit of the air compressor according to an embodiment of the present application.

Hereinafter, the present application will be described in more detail with reference to the drawings.

In the present specification, the same and similar reference numerals are assigned to the same and similar components even in different embodiments, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, the suffixes "module" and "part" for the components used in the following description are given or mixed in consideration of only the ease of writing the specification, and do not have a meaning or role distinct from each other by themselves.

Throughout the specification, when a part "includes" a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

1 is a cross-sectional view showing a dual air compression multi-purpose launcher according to an embodiment of the present application, and FIG. 2 is a cross-sectional view showing a state in which a projectile is coupled to the launcher according to an embodiment of the present application.

1 and 2, the dual air compression multi-purpose launcher according to an embodiment of the present application includes an air chamber 100 for storing compressed air; a piston 110 provided in the chamber and moving backward to first compress air; and an air compressor 220 provided outside the chamber for secondary compression of air. The air-compression multipurpose launcher of the present application has the advantage of being able to fire with a sufficient reach as desired because it performs double air compression.

Compressed air may be fired to the first exhaust unit 102 provided in the front of the air chamber 100 to forward the projectile 500 .

It is disposed at the rear or lower portion of the chamber 100, and may further include a handle 200 having an air compressor 220 and a battery 240 therein.

As long as the battery 240 can supply power to the air compressor 220 , any type may be used.

The housing 10 including the chamber 100 and the handle 200 has the same shape as a general pistol, but has various shapes that can configure various elements for firing the projectile 500 . It is also possible to When the handle 200 is disposed at the rear of the chamber, the housing 10 may have a cylindrical shape.

It may further include a bolt 130 disposed above the chamber 100 to guide the movement of the piston 110 . The bolt 130 is connected to the piston 110 and serves to guide the movement of the piston 110 so as to move the piston 110 rearward. A first spring 120 is connected between the piston 110 and the rear inner surface of the air chamber 100 . The bolt 130 is disposed to protrude outside the upper portion of the chamber 100 so that it can be moved backward while being directly gripped by hand. After moving the piston 110 with the bolt 130 , the moved piston 110 may be fixed by the locking jaw 170 . The locking protrusion 170 may be disposed inside the lower surface of the chamber 100 .

A connection nozzle 210 connecting the chamber 100 and the air compressor 220 may be disposed in front of the locking jaw 170 so as to compress air in the air chamber 100 . The connection nozzle 210 connects the air compressor 220 and the air chamber 100 , and serves to generate air pressure in the air chamber 100 by the air compressor 220 .

After the piston 110 is moved rearwardly and the air inside the air chamber 100 is first compressed while being fixed to the locking jaw 170, the air chamber ( 100) can be compressed secondarily. When the connection nozzle 210 is positioned at the rear of the locking jaw 170 , the secondary air compression of the air compressor 220 cannot be performed after the primary air compression of the piston 110 . If the air is compressed first with the air compressor 220 and then the air is compressed with the piston 110 later, the internal air pressure cannot be precisely adjusted.

It may further include two or more piston support parts 150 mounted on the front inner circumferential surface of the chamber 100 to support the piston 110 that moves forward during firing.

The piston support 150 may be two, three, four, five or six, as long as there are two or more, the shape or number is not particularly limited. The two or more piston support parts 150 are spaced apart from each other on the front inner circumferential surface of the air chamber 100 , and the distance between each piston support part 150 is formed to be the same in order to distribute the force supporting the piston 110 . can be The piston support 150 may be formed of an elastic material to reduce the amount of impact generated by the collision with the piston 110 and reduce wear.

The chamber 100 may further include a projectile guide tube 360 that is disposed in the front portion and through which compressed air is injected from the second discharge portion 364 of the end portion.

The projectile guide tube 360 may have a hollow rod 410 or tube shape so that the projectile 500 can be inserted. When the trigger 460 is pulled, the compressed air is connected to the first outlet 102 of the air chamber 100 according to the forward movement of the piston 110 and moves to the inlet 362 of the projectile guide tube 360, It is discharged to the second discharge part 364 of the projectile guide tube 360 again. At this time, the projectile 500 is launched by the thrust of the discharged compressed air.

In an embodiment of the present application, the multi-purpose launcher may further include a projectile 500 into which the projectile guide tube 360 is inserted.

The projectile 500 may include a tubular body portion 530 into which the guide tube 360 can be inserted.

The projectile 500 may include;

The wing portion 520 may be formed in a shape such as a rod type, a blade type, or a screw type. In addition, the thin plate shape may be formed in a shape having a constant thickness and a narrow and uniform width, or a thin plate shape may be formed in a shape having a constant thickness and narrowing toward an upper portion. In addition, it may be formed in a shape that has a constant thickness in a thin plate shape and has a constant width at the lower portion, and becomes narrower toward the upper portion. Preferably, each of the blades faces in the direction in which its face rotates to generate turbulence. The surface of the wing may be formed to face the outer circumferential surface of the body portion 530 at an angle of 10° or more, specifically 20° or more, more specifically 30° or more to face in the rotational direction, and 45° or less, specifically 40 ° or less may be formed facing in the direction of rotation by making an inclination. When formed to face the surface of the wing in the rotational direction, there is an advantage in that the maximum firing distance can be obtained by reducing air resistance with the maximum rotational effect.

More preferably, the wing portion 520 may be formed of three blades and radially outward at intervals of 120 degrees, respectively.

The wing of the projectile connected to the heaving line uses a blade type to suppress rotation as much as possible, thereby preventing the connected string from being twisted or tangled by rotation and improving directionality.

The projectile 500 may include a head 540 in front of the body 530 . The head unit 540 may be provided by replacing a head for throwing a heaving line, a head for towing color transfer, a head for lifesaving or a head for shogunate.

3 is a cross-sectional view showing the flow of air according to the shape of the chamber according to an embodiment of the present application. The first discharge unit 102 of the air chamber 100 may form a venturi section.

Referring to FIG. 3 (a), in the case of a conventional straight cylinder structure, the air pushed by the piston 110 as it advances does not pass through the narrow inlet, but hits a wall, causing a reaction and a vortex, acting as a resistance when the piston moves forward. Therefore, there is a problem in that the firing pressure is lowered, thereby reducing the propulsion force. Also, the launcher can be broken or damaged due to the reaction and vortex that occurs when it hits the wall.

However, referring to FIG. 3 (b), since the first discharge part 102 of the air chamber 100 forms a venturi section, the air pushed by the piston 110 as it advances descends in the inlet direction along the smooth wall surface. Combined with the air pushing the center, it creates a higher firing pressure, which has the effect of increasing propulsion. As the flow rate rapidly increases, a venturi section having a venturi effect in which the pressure is lower than the surrounding area is formed. As a result, a suction phenomenon that sucks in the surrounding air occurs. Therefore, there is an effect that the speed of the fluid becomes faster. In addition, since the resistance generated on the wall is minimized, there is an effect of preventing damage or damage to the launcher while increasing the launch driving force.

4 is a cross-sectional view illustrating an air flow in a closed state and an open state of the first discharge part of the chamber according to the movement of the sliding valve.

The first discharge unit 102 provided in the front of the chamber 100 and the inlet 362 of the projectile guide tube 360 may be connected or blocked through the hole 310 provided in the vertical sliding valve. .

Referring to FIG. 4A , when the vertical sliding valve 300 is in a closed state, it serves to block the air chamber 100 from the outside.

Referring to FIG. 4( b ), when the vertical sliding valve 300 is moved upward, it becomes an open state, and the hole 310 provided in the sliding valve is formed between the air chamber 100 and the projectile guide tube 360 . serves as a pathway for A second spring 320 is connected to an upper portion of the vertical sliding valve to perform vertical movement.

An end diameter of the first discharge unit 102 of the air chamber 100 may be greater than an end diameter of the inlet 362 of the projectile guide tube 360 .

The vertical sliding valve is fixed to the upper surface of the housing with a second spring 320 connected thereto, and the diameter of the hole 310 is the same as or smaller than the diameter of the end of the first outlet 102, and the diameter of the end of the inlet 362 and may be equal to or greater than It is preferable that the diameter of the hole 310 is smaller than the end diameter of the first outlet 102 and larger than the end diameter of the inlet 362 . The hole 310 may be formed such that the diameter of the hole 310 in contact with the first discharge unit 102 becomes smaller as the diameter increases from the diameter of the hole 310 in contact with the inlet 362 . When the diameter of the air movement passage decreases according to the movement direction of the air, the movement speed of the air and the pressure of the air increase, so that the firing distance of the projectile 500 may also increase.

Figure 5 is a view showing the trigger and the rod according to an embodiment of the present application, Figure 6 is a view showing the trigger and the locking jaw according to an embodiment of the present application.

5 and 6 , a trigger 460 hinged at the front of the handle 200; and a rod 410 connected to the trigger 460 and horizontally disposed on the lower portion of the housing.

When the trigger 460 is pulled, the rod 410 in the rod cover 400 moves forward, and the rod end 430 moves the sliding valve upward to open the hole 310, and at the same time the trigger 460 is engaged. By moving the jaw 170 downward, the piston 110 moves forward and the compressed air is injected to the second discharge unit 364 to fire the projectile 500 . The trigger 460 may be fixed with a third spring 470 .

A connecting means 180 is connected between the trigger 460 and the locking jaw 170 , and the connecting means 180 may be disposed so that one end and the other end can move up and down based on the fixing part 182 . When the trigger 460 is pulled, one end of the connecting means 180 disposed in contact with the trigger 460 moves upward, and the other end of the connecting means 180 disposed in contact with the locking protrusion 170 moves downward. By causing 170 to move downward, it allows piston 110 to move forward. A locking jaw spring 172 may be disposed at the lower portion so that the locking jaw 170 moves downward.

A valve connection part 340 may be further included in the lower part of the sliding valve, and at the same time as the trigger 460 is pulled, the rod 410 moves horizontally while pushing up the valve connection part 340 connected to the lower part of the sliding valve in the vertical direction. The sliding valve can be moved upwards.

7 is a view illustrating a protrusion in a chamber and a protrusion receiving part provided in a piston according to an embodiment of the present application.

Referring to FIG. 7 , the piston 110 includes a protrusion accommodating part 112 formed by penetrating the center of the piston 110 , and the protrusion accommodating part 112 is, when the piston 110 moves backward, the air It can be combined with the protrusion 114 provided to protrude into the rear end of the chamber 100 to seal the air. The protrusion 114 may be formed to have a length that is the same as or more extended from the rear end of the chamber to the stopping protrusion 170 .

When the piston 110 moves forward by pulling the trigger 460 in the sealed air chamber 100 , it may be difficult to discharge the compressed air at a high speed due to the repulsive force of the internal pressure. In addition, if the air does not escape well into the first discharge part 102 of the air chamber 100 compared to the forward speed of the piston 110 while pushing the high-pressure air, a pressure load is applied inside the chamber 100 There may be a fear that the piston 110 is stopped. Due to the protrusion receiving portion 112 formed in the shape of the hole 310 of a certain size, the repulsive force of the pressure is reduced, so that the piston 110 can move forward at a faster speed.

8 is a view showing an input unit and a display unit of the air compressor according to an embodiment of the present application.

Referring to FIG. 8 , the air compressor 220 includes an input unit 222 for inputting a desired firing distance or a desired pressure; a display unit 224 indicating the firing distance or pressure; and a control unit.

The control unit may include: a calculating unit configured to calculate the pressure in the air chamber 100 and the firing distance of the projectile 500 to set the optimum pressure; and a data storage unit 234 for storing the data calculated through the calculation unit and data input through the input unit 222; the calculation unit, the input unit 222, the display unit 224, and the data storage unit (234) can be controlled.

The calculation unit may calculate the pressure in the air chamber 100 and the firing distance of the projectile 500 to set the pressure derived as a result of the calculation, and the display unit 224 may display the set pressure.

The display unit 224 may be an LCD or LED, and is not particularly limited as long as it is a material capable of displaying the firing distance and/or pressure.

The present application described above is not limited to the configuration and method of the above-described embodiments, but the embodiments may be configured by selectively combining all or part of each embodiment so that various modifications can be made.

10: housing 100: chamber
102: first discharge unit 110: piston
112: projection receiving portion 114: projection
130: bolt 150: piston support
170: locking jaw 200, 200 ': handle part
210: connection nozzle 220: air compressor
222: input unit 224 display unit
234 data storage unit 240: battery
300: vertical sliding valve 310: hole
340: valve connection 360 projectile guide tube
362 inlet 364 second outlet
410: rod 430: rod end
460: trigger 500: projectile
520: wing portion 530: body portion
540: head

Claims (14)

housing;
an air chamber provided inside the housing and storing compressed air;
a piston provided inside the chamber to move backward to primarily compress air in the air chamber;
an air compressor provided outside the chamber for secondary compression of primary compressed air;
a bolt disposed above the chamber to guide the movement of the piston;
a locking jaw mounted on the lower surface of the chamber to fix the piston moved backward; and
a connection nozzle disposed in front of the locking jaw and connecting the air compressor and the air chamber; including,
After first compressing the air in the air chamber by moving the piston backward, the air in the air chamber is secondarily compressed by operating the air compressor connected to the connection nozzle,
Double air compression multi-purpose launcher, characterized in that by firing compressed air to the first discharge unit provided in front of the air chamber to forward the projectile. delete The method according to claim 1,
a handle portion disposed in the lower portion of the chamber and having the air compressor and a battery therein; Double air compression multipurpose launcher further comprising a. 4. The method according to claim 3,
a projectile guide tube disposed in the front portion of the chamber and through which compressed air is injected from a second exhaust portion of an end portion; and
a vertical sliding valve for connecting or blocking the first outlet provided in the front of the chamber and the inlet of the projectile guide tube through a hole provided therein; Double air compression multipurpose launcher further comprising a. 5. The method according to claim 4,
A first outlet of the air chamber forms a venturi section,
The end diameter of the first discharge part is a double air compression multipurpose launcher, characterized in that larger than the diameter of the inlet end of the projectile guide tube. 6. The method of claim 5,
The vertical sliding valve is fixed to the inside of the housing by a compression spring connected thereto,
The diameter of the hole is equal to or smaller than the first outlet end diameter and the same as or larger than the inlet end diameter. 5. The method according to claim 4,
a trigger hingedly provided at the front of the handle; and
a rod connected to the trigger and disposed horizontally on the lower part of the housing; further comprising,
When you pull the trigger,
As the rod moves forward, the rod end moves the sliding valve upward to open the hole, and at the same time moves the locking jaw connected to the trigger downward to move the piston forward while injecting compressed air to the second outlet to fire the projectile. A dual air-compression multi-purpose launcher. The method according to claim 1,
Double air compression multipurpose launcher, characterized in that it is mounted on the front inner circumferential surface of the chamber and further comprises two or more piston support for supporting the piston moved forward during firing. 9. The method of claim 8,
The piston support is a dual air compression multi-purpose launcher, characterized in that spaced apart from each other on the inner peripheral surface of the front of the air chamber is arranged at the same distance from each other. The method according to claim 1,
The piston is
It includes a protrusion receiving portion formed through the center of the piston,
The protrusion accommodating part is coupled to the protrusion provided to protrude into the rear end of the air chamber when the piston moves backward, to seal the air. The method according to claim 1,
The air compressor is
an input unit for inputting a desired firing distance or a desired pressure;
a display unit indicating the firing distance or pressure; and
Double air compression multipurpose launcher comprising a control unit. delete 5. The method according to claim 4,
Further comprising a projectile into which the projectile guide tube is inserted,
The projectile is
a tubular body into which the guide tube can be inserted; and
a plurality of wing portions protruding radially from the outer peripheral surface of the body portion and formed at the same distance from each other;
Double air compression multipurpose launcher comprising a. 14. The method of claim 13,
The projectile is
Double air compression multipurpose launcher, characterized in that it comprises a head for a heaving line in front of the throwing head, a head for towing transfer, a head for lifesaving or a head for a shojo cat in front of the body part.

Images