KR101311996B1 - Air gun - Google Patents

Abstract

PURPOSE: An air gun is provided to maximize output quantity of compressed air by using a unique nozzle structure and to enhance spraying effects by reducing noise due to compressed air spray. CONSTITUTION: An air gun comprises a nozzle (300), a valve body and an air gun body (100). The air gun body comprises a valve chamber (150) in which an air passage (120) is formed inside and which is connected to the air passage as being crossed; and a pulling lever (110) which is rotatably combined in one side of the valve chamber by using an axis pin (140). The valve body comprises a Teflon seal (220) and a cushion packing (230) installed in one-way direction of the valve chamber in order; a piston (210) which is slidingly elevated by pulling the pulling lever as being penetrated through the Teflon seal and the cushion packing in a closed state; an opening and closing valve (240) which opens the air passage by elevating the piston; a compressed spring (250) which elastically supports one side of the opening and closing valve; and an air-tight cap (260) which seals the other side of the valve chamber by elastically supporting the opening and closing valve by pressing the other side of the compressed spring.

Description

Air gun {AIR GUN}

The present invention relates to an air gun, and more particularly, to increase the airtightness by reducing the wear rate as much as possible, even in the repeated operation of the valve according to the opening and closing operation of the compressed air discharge, improve the structure of the nozzle to discharge the compressed air to amplify the injection amount At the same time, it relates to an air gun that maximizes the reliability of the product through noise dispersion.

In general, in order to perform work using air in industrial sites, sports facilities, etc., an air compressor for generating air is used, and the compressed air generated in the air compressor is connected to the air gun by a connection hose, and the air gun is opened and closed. It is used to remove foreign substances such as dust, water, etc. by spraying on a predetermined part by an operation.

Techniques for such an air gun have been variously known in the art, and various techniques have been disclosed for improving the use function.

Looking at the structure, it consists of a gun-shaped body having an air passage therein, a valve for opening and closing the air passage formed in the body and the components of the nozzle coupled to the final discharge end of the air passage.

The valve is the back of the valve by pulling the lever of the trigger function installed by the shaft pin on the body to open the air passage to inject the compressed air through the nozzle, when the lever is released by the elastic force of the compression spring elastically installed on the valve As the lever returns to its original position by the forward (return), it blocks the air passage to block the flow of compressed air.

One of the important functions in such an air gun is a valve for opening and closing the flow of compressed air.

The valve is installed in a valve chamber installed on the air passage of the body, and is sealed using a rubber ring to prevent the compressed air from leaking in the valve chamber.

The airtight structure using the rubber ring requires replacement of the rubber ring parts due to leakage of compressed air due to deformation as well as wear due to repeated long / long operation of the valve.

In other words, the O-ring installed in the valve was easily worn and the sealing force was lowered, and the amount of compressed air could not be adjusted. Also, in the event of a problem with the valve device, there was a closed end to replace the entire air gun.

In order to solve this disadvantage, as disclosed in Patent Document 1, a technique having a valve structure in which airtightness is provided by close contact with the lower surface of the opening and closing portion of the valve on the upper surface of the packing coupled to the airtight support tube is disclosed.

In addition, one of the functions of the air gun is the function of the nozzle.

The conventional air gun cannot make the output of the compressed air injected from the injection nozzle larger than the output (compressed air amount) of the compressed air supplied from the air compressor.

Therefore, in order to increase the output of the compressed air amount, more compressed air should be supplied from the air compressor.

Patent Literature 2, which has improved these disadvantages, discloses a technique for generating a larger output with less energy by employing an output enhancer in place of an air gun passage to increase the amount of compressed air of the air compressor.

Patent Document 1: Republic of Korea Utility Model No. 20-0160589 (Registration Date: August 17, 1999) Patent Document 2: Republic of Korea Utility Model No. 20-0212686 (Registration Date: November 24, 2000)

The above Patent Document 1 improves the disadvantages of the rubber ring to improve the airtightness, but there is a disadvantage in that the manufacturing cost is high due to the complexity of the component parts as well as the increase of the component parts.

Moreover, the characteristics of the hermetic ring were improved, but the output injection amount of the nozzle was not increased, and the compressed gas was injected by the thin and long nozzle, so that the noise caused by the discharge of the compressed air could not be reduced.

Patent document 2 is to discharge together the external air introduced into the inlet space through the separate suction hole by the flow rate of the compressed gas discharged through the hole of the output enhancer accommodated in the internal space in order to increase the output injection amount of the compressed air Although the output is increased, this is difficult to assemble and manufacture the output enhancer installed in one side flow path of the inlet space portion of the air gun and the disadvantages of the rubber ring pointed out in the conventional valve structure.

In addition, induction of air through a single suction hole has a disadvantage in that the practical use of the output of compressed air as a limit point of induction of intake of external air does not significantly increase.

In addition, the nozzle structure is also sprayed by a thin elongated nozzle, as in Patent Literature 1, rather it did not reduce the noise caused by the discharge of compressed air.

Accordingly, an object of the present invention is to provide a gas tight structure using Teflon seals to prevent leakage of compressed air due to long-term use of the valve to increase airtightness characteristics and lifespan.

In particular, it is an object of the present invention to provide a discharge of compressed air by a unique nozzle structure and at the same time to collect the surrounding air and to provide noise reduction by increasing the injection amount and spreading effect.

Air gun of the present invention for achieving the above object,

An air gun body having an air passage formed therein and communicating with the air passage in an intersecting state with the air passage, and an air gun body having a pull lever rotatably coupled by a shaft pin on one side of the valve chamber;

A piston that rises slidably by pulling the pull lever in an airtight state through the Teflon seal and the cushion packing sequentially installed in one direction of the valve chamber, and the air passage by the rising of the piston. An open / close valve to open, a compression spring to elastically support one side of the on / off valve, and press the other side of the compression spring to elastically support the on / off valve to seal the other side of the valve chamber in a state of blocking the air passage. A valve body assembled with a cap;

A plurality of injection nozzle balls for discharging and discharging the compressed air discharged through the air passages, protruding at a predetermined height around the injection nozzle balls, each injection guide blade for partitioning each of the injection nozzle balls, each of the A nozzle body disposed at the rear of the injection nozzle hole between the injection guide vanes, and formed with a plurality of air induction grooves for guiding the inflow of external air by a pressure difference caused by compressed air discharged from the injection nozzle hole; A nozzle which is integrally formed at the rear end of the body part and integrally molded with a screw protrusion which is screwed to a screw groove formed at the front end of the air gun body;

And a control unit.

Here, the air induction groove is preferably formed in a streamlined shape of the upper and lower strait is configured to increase the flow rate of air.

In addition, the injection nozzle hole of the nozzle body portion is radially divided at the tip of the large diameter air vent in the center to form a thin, long straight line is made to be discharged by increasing the injection speed of the compressed air discharged.

In addition, the injection guide vane is formed by narrowing each of the injection nozzle holes along the inclined surface of the nozzle body portion between each of the distal end is injected with the compressed air discharged from the injection nozzle hole at the same time as the injection guide In the smallest area between the wings, the venturi tube principle is provided in which the velocity increases and the air is blown out while the space between the jet guide vanes is spread and spread.

The screw protrusion of the nozzle is formed of a stepped protrusion, and the screw groove of the air gun body is formed of a stepped screw groove corresponding to the screw protrusion, so that airtightness is maintained by screw assembly.

According to the present invention, it is possible to maximize the output of the compressed air by the unique nozzle structure, and to reduce the noise caused by the injection of the compressed air can be expected to the injection effect.

That is, in the present invention, when the compressed air is injected using the Venturi tube principle, the nozzle is injected while inhaling the surrounding air due to the air pressure difference, so as to maximize the output, and partitions the injection nozzle hole according to the injection. At the same time, it is possible to aim at noise dissipation by spreading effect.

In addition, the present invention can be expected industrially mass production effect due to the increase in the airtight characteristics, the increase in the service life and the convenience of the assembly work by the unique valve structure, it is possible to provide at low cost.

1 is a perspective view showing the appearance of the present invention.
2 is a front view of the present invention.
3 is a cross-sectional view of the assembled state of the present invention.
4 is an exploded perspective view in half of the constituent member of the present invention.
5 and 6 is an enlarged sectional view taken from the valve portion that is the main configuration of the present invention,
5 is a state diagram in which the airflow is closed by closing the valve before operation of the pull lever,
6 is a state diagram in which the air flow is opened by opening the valve by pulling the pulling lever.
7 and 8 are a front view and a cross-sectional view of the extract of the nozzle which is a main component of the present invention.
9 and 10 are cross-sectional views taken along line III-III and line IV-IV taken from FIG. 8.
11 and 12 are front and cross-sectional views showing the flow of air by the nozzle of the present invention.

The present invention is characterized by dispersing the noise generated by the compressed air injected from the nozzle injection hole while increasing the injection power of the compressed air by the adoption of a unique nozzle structure.

In addition, in order to increase the airtight characteristics of the valve body, it is replaced by Teflon seals, and at the same time, the assembly and replacement of parts are provided simply and conveniently.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention.

In addition, the components shown in the drawings for the purpose of description of the present invention may be simplified, exaggerated, or omitted as long as they do not affect the rights of the present invention.

1 is a perspective view showing the overall appearance of the assembled state of the air gun of the present invention, Figure 2 is a front view of the present invention, Figure 3 is a cross-sectional view of the present invention.

According to the present invention, the nozzle 300 is assembled at the tip of the air gun body 100, and the valve is assembled to the valve chamber 150 by the pull lever 110 assembled by the shaft pin 140 on the air gun body 100. The general configuration of opening and closing the air passage 120 by operating the sieve 200 is the same as the conventional air gun.

In addition, the air passage 120 of the air gun body 100 is connected to the handle portion by a connection hose (H) of the compressor, which is a normal compressed gas generating means, to supply compressed air.

In addition, the air gun body 100 is molded hook 131 that can be stored easily hang after use.

The air gun body 100 has an air passage 120 formed therein, the valve chamber 150 communicates with the air passage 120 in a state intersecting with the shaft pin 140 on one side of the valve chamber 150. There is provided a pull lever 110 rotatably coupled by.

Referring to FIG. 4, the valve body 200 penetrates through the Teflon seal 220 and the cushion packing 230, the Teflon seal, and the cushion packing which are sequentially installed in one direction of the valve chamber 150. The piston 210 rising in a sliding manner by pulling the pull lever 110, the on-off valve 240 for opening the air passage 120 by the piston 210, the opening and closing valve 240 Compression spring 250 to elastically support one side, by pressing the other side of the compression spring 250 to elastically support the opening and closing valve 240 to the valve chamber 150 in a state of blocking the pipeline of the air passage 120 The other side of the airtight cap 260 is composed of.

Here, the hermetic cap 260 is assembled by screwing the screw portion formed in the upper portion of the valve chamber 150, is assembled in the state in which the O-ring 270 is coupled to the O-ring groove formed on the outer circumferential surface is provided with the outside and airtight.

The valve chamber 150 of the air gun body 100 is formed by penetrating the air passage 120 in an orthogonal state with a stepped hole having a narrow lower side and an extended upper side, and each of the one valve body 200. Components are assembled or separated sequentially from top to bottom.

As a result, the disadvantages caused by the assembly on the pull lever 110 side as in the conventional, it is possible to solve the disadvantages of difficult parts replacement due to the difficult disadvantage of separation of the pull lever coupled by the riveting.

In particular, the airtight ring is composed of a Teflon seal (220) having excellent wear resistance and heat resistance, thereby minimizing deformation and wear caused by repeated movement of the piston (210) to ensure longevity.

The valve body 200 is pulled as shown in FIG. 6 in a state where the opening / closing valve 240 of the valve body 200 closes the outlet side air passage 120 as shown in FIG. 5. The lever 110 is pulled.

Accordingly, the piston 210 in the state in which the tip is in contact with the pull lever 110 retracts (raises), and elastically supports the opening / closing valve 240 closing the outlet side air passage 120 of the air gun body 100. The compression spring 250 that has been used is compressed, raised and opened.

By opening the valve, compressed air supplied in a state connected to the air passage 120 is discharged through the nozzle 300.

When the compressed air is discharged through the nozzle 300 and the pulling lever 110 is released after completing a predetermined purpose, dust removal, and the like, the on / off valve may be opened by the elastic force of the compression spring 250. By descending 240, the air passage 120 is again blocked and closed, and at the same time, the piston 210 is returned to its original position (down) and the pulling lever 110 is also returned to the original position.

3 and 4 and 7 to 11 illustrate the structure of the nozzle 300, which is a main component of the present invention.

The nozzle 300 of the present invention comprises a nozzle body portion 310 having a narrow tip and an extended rear end in a bullet shape, and a screw protrusion 360 integrally extended to the nozzle body 310. do.

The nozzle body 310 has a plurality of injection nozzle holes 320 for discharging and discharging compressed air discharged through the air passage 120 are formed through the air vent hole 350 in the center.

In this case, each injection guide blade 330 is formed to protrude to a predetermined height around the injection nozzle hole 320 to partition each injection nozzle hole 320.

In addition, to guide the inflow of external air by the pressure difference caused by the compressed air discharged from the injection nozzle hole 320 in a state disposed between the rear of each injection nozzle hole 320 and the injection guide blade 330. The plurality of air guide grooves 340 are formed.

In addition, the rear end of the nozzle body 310 is integrally molded with a screw projection 360 screwed to the screw groove 130 formed on the front end of the air gun body (100).

As shown in FIGS. 8 and 9, the nozzle body 310 is radially divided at the tip of the air vent 350 having a large diameter in the center, and is formed in a thin and long straight shape. It is made to discharge by increasing the injection speed of the compressed air discharged.

As a result, as shown in Figs. 11 and 12, the discharge is made while attracting the surrounding external air.

This is caused by the discharge of the fast air velocity while the pressure difference is generated and the compressed air discharged through the injection nozzle hole 320 is attracted by the surrounding external air is discharged to increase the discharge amount.

Collecting such external air is easily discharged when the external air in the plurality of air induction grooves 340 formed at the rear of the injection nozzle hole 320 is easily induced to increase the ejection injection amount.

In this case, the air induction groove 340 is preferably formed in a streamline of the upper and lower narrowing is configured to increase the flow rate of air.

On the other hand, the injection guide blade 330 is partitioned with each of the injection nozzle hole 320 along the inclined surface of the nozzle body 310 and at the same time formed between each tip narrowly.

As a result, the compressed air discharged from the injection nozzle hole 320 is injected and at the same time the area between the injection guide blades 330 is the smallest, the speed is increased to escape the space between the injection guide blades 330 and at the same time. The venturi tube principle is provided by spraying as it spreads to reduce air (compressed air) consumption and provide noise dispersion.

The screw protrusion 360 of the nozzle 300 is formed as a stepped protrusion, and the screw groove 130 of the air gun body 100 is formed as a stepped screw groove corresponding to the screwed protrusion to step assembly by screw assembly. Confidentiality is maintained.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of the appended claims as well as the appended claims.

The present invention is effectively used to remove dust and moisture in industrial sites, sports facilities, etc., and can be used very usefully to consumers by extending the service life.

100: air gun body 110: pull lever
120: air passage 150: valve chamber
200: valve body 210: piston
220: Teflon seal 240: on-off valve
250: compression spring 260: air tight cap
300: nozzle 310; Nozzle Body
320: nozzle injection hole 330: injection guide blade
340: air guide groove 350: air vent
360: screw projection

Claims (5)

An air passage 120 is formed therein, and the valve chamber 150 connected in a state intersecting with the air passage 120 is pulled rotatably coupled by a shaft pin 140 to one side of the valve chamber 150. Air gun body 100 having a lever 110, and the Teflon seal 220 and cushion packing 230, the Teflon seal 220 and the cushion packing 230 are sequentially installed in one direction of the valve chamber 150 Opening valve 240 for opening the air passage 120 by the piston 210, the piston 210 rises by sliding the pull lever 110 in the airtight state through the airtight state, the Compression spring 250 to elastically support one side of the opening and closing valve 240, by pressing the other side of the compression spring 250 to elastically support the opening and closing valve 240 to block the pipeline of the air passage 120 A valve body 200 assembled with an airtight cap 260 for hermetically sealing the other side of the valve chamber 150, and the air passage 120. A plurality of injection nozzle balls 320 for discharging and discharging compressed air discharged through the plurality of injection nozzles 320 and protruded to a predetermined height around the injection nozzle holes 320 to respectively separate injection guide blades 330 for partitioning the respective injection guide blades 330. A plurality of air inductions disposed between the injection guide vanes 330 at the rear of the injection nozzle holes 320 to guide the inflow of external air by a pressure difference caused by the compressed air discharged from the injection nozzle holes 320. A screw projection part which is integrally molded to the rear end of the nozzle body part 310 and the screw groove part 130 formed at the tip of the air gun body 100) is formed by forming the groove 340. In the air gun consisting of a nozzle integrally molded 360,
The injection nozzle hole 320 of the nozzle body 310 is radially divided at the tip of the large diameter air vent 350 in the center and is formed in a thin and long straight shape.
The air induction groove 340 is formed in a streamlined upper and lower narrow, the injection guide blade 330 partitions each of the injection nozzle hole 320 along the inclined surface of the nozzle body 310 and at the same time Between the tip of the narrow is formed is compressed air discharged from the injection nozzle hole 320 and at the same time the speed is increased in the smallest area between the injection guide blade 330 between the injection guide blade 330 Air gun, characterized in that the noise is dispersed by the compressed air is sprayed while leaving the space at the same time.
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