KR102362768B1 - Air distribution device for powder coated gun with enhanced air diffusion function - Google Patents

Abstract

An air distribution device for a powder-coating air gun with an enhanced air diffusion function according to the present invention, as an air distribution device mounted on a powder-coating air gun that discharges air through a nozzle protruding from the tip, comprises: a guide pipe having an open front end and a closed rear end in a state having a first hollow therein, having a smaller diameter than the inner circumferential surface of the nozzle, mounted in the hollow of the nozzle, and including an impeller mounted in the first hollow and a discharge hole penetrating along the circumference of the inner circumferential surface where the impeller is located; a guide dome having a dome shape to make an inner circumferential surface face the tip of the nozzle in a state in which a coupling hole for fitting the nozzle penetrates through the central portion and including an air space communicating from the central portion to the peripheral portion in a state of internally connected to the discharge hole and a plurality of air discharge pipes internally connected from the air space to the inner circumferential surface; and a cover pad for sealing the hollow portion located in front of the tip of the guide dome in the nozzle. According to the air distribution device for the powder-coating air gun with an enhanced air diffusion function according to the present invention, it is possible to simultaneously strengthen the air injection pressure and diffusion performance by installing the guide pipe and the guide dome on the inside and outside of the nozzle of the powder-coating air gun and then reinforcing the power of the impeller.

Description

Air distribution device for powder coated gun with enhanced air diffusion function

The present invention relates to an air distribution device for a powder coating air gun with enhanced air diffusion function, and more particularly, the air sprayed from the air gun spraying air for cleaning up the paint in the powder coating process is not necessary before reaching the object with a weak pressure For powder-coated air guns that can smoothly remove the unevenly painted paint on the object to be coated by dispersing and spraying air to a specific spot or area (area) of the object to be coated at high pressure while preventing the problem of spreading to the surroundings It relates to an air distribution device.

Generally, in the powder coating booth, as the object moves along the rail, the powder coating machine is placed at a certain distance left and right centering on the object to be coated. It provides the function of painting processing.

At this time, the powder coating machine receives the paint and sprays the paint onto the object to be coated through a plurality of nozzles.

As such, the powder coating machine performs powder coating on the object to be coated while moving along the rail of the powder coating booth. The paint is removed by air spraying through a gun-shaped powder coating air gun and then put back into the powder coating booth or sprayed with a small amount of paint compared to the powder coating machine while still in the shape of a gun. It is common to perform some painting or repainting through a powder coating gun.

At this time, the paint unevenly coated on the object to be coated is cleaned or removed by spraying air through an air gun for powder coating (hereinafter referred to as a 'powder coating air gun') and blowing it to the surroundings.

5 is a cross-sectional view showing a known powder-coated air gun.

As can be seen from FIG. 5, the known powder-coated air gun has a body having an air jetting performance in a state like a pistol, a nozzle extending like a gun barrel to spray the air generated from the body to a body to be coated, and , consisting of a handle with a trigger that acts as a switch to activate the air jet function.

However, these powder-coated air guns have a problem in that the sprayed air does not have a strong pressure due to a weak air injection pressure or various other problems, and is crushed or blown away as if a cloud is flying around the object to be coated.

The prior art, domestic patent No. 1862095, automatic recognition of the size of the coating system includes a function of automatically operating the trigger by coupling the powder coating air gun to the frame through the powder coating air gun coupling device. It provides a function of spraying the paint itself in order to repaint the powder, and does not provide a separate technology that not only sprays air, but also guarantees strong air spraying power and sufficient diffusion power.

Therefore, there is a need to develop an air distribution device specialized for a new and advanced powder coating air gun with enhanced air injection and diffusion performance that can remove uneven coating more efficiently.

The present invention has been devised to overcome the problems of the above technology, and its main object is to provide an air distribution device including a detailed configuration capable of strengthening the air pressure and diffusion performance on the inside and outside of the nozzle of a powder-coated air gun.

Another object of the present invention is to provide various means for further enhancing the air diffusion performance.

Another object of the present invention is to coat the inner circumferential surface of a guide dome having an air reflection function with a friction modifier capable of enhancing air reflection performance.

It is a further object of the present invention to enhance the friction reducing function through various properties and manufacturing methods of the friction modifier.

In order to achieve the above object, an air distribution device for a powder-coated air gun with enhanced air diffusion function according to the present invention is an air distribution device mounted on a powder-coated air gun that discharges air through a nozzle protruding from the tip, and has a first In a state with a hollow, the front end is open and the rear end is closed, and is mounted in the hollow of the nozzle with a diameter smaller than the inner circumferential surface of the nozzle. a guide pipe including a discharge hole; An air space communicating from the central portion to the peripheral portion in a state in which the coupling hole for fitting the nozzle has a dome shape while penetrating through the central portion, the inner circumferential surface faces the tip of the nozzle, and is in internal communication with the discharge hole, and, a guide dome including a plurality of air discharge tubes internally communicated from the air space to the inner circumferential surface; and a cover pad for sealing the hollow portion located in front of the tip of the guide dome in the nozzle.

In addition, the air distribution device has a second hollow and is extended toward the tip of the nozzle in a state of being tapered after rotation, and a shade coupled to the guide dome; characterized.

In addition, a direction control ring is mounted on the outer circumferential surface of the nozzle located in front of the cover pad, and the terminal shape of the direction control ring includes a rear end surface that is inclined in the front end direction of the nozzle, and at the end of the rear end surface. It is characterized in that it comprises an inclined surface extending obliquely toward the tip of the nozzle.

According to the air distribution device for the powder coating air gun with enhanced air diffusion function according to the present invention,

1) By installing a guide pipe and a guide dome on the inside and outside of the nozzle of the powder-coated air gun, and then reinforcing the power of the impeller, it has the advantage of simultaneously strengthening the air injection pressure and diffusion performance.

2) Through the unique shape of the cover pad, the reflection direction of air can be specified efficiently,

3) It is possible to further strengthen the air diffusion performance through various means such as shade or direction adjustment ring,

4) Provides the effect of promoting air reflection performance through the friction reliever coated on the inner circumferential surface of the guide dome.

1 is a cross-sectional view showing the main configuration of an air distribution device of the present invention.
Figure 2 is a cross-sectional view showing an air flow through the air distribution device of the present invention.
3 is a cross-sectional view showing a structure in which the air distribution device of the present invention further includes a shade and a direction control ring.
4 is a cross-sectional view showing a structure in which the air distribution device of the present invention further includes a diffusion ring.
5 is a cross-sectional view showing a known powder-coated air gun.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are not drawn to scale, and like reference numbers in each drawing refer to like elements.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows the main structure of the air distribution apparatus of this invention.

First of all, in the present invention, the meaning of the direction and position of 'tip' and 'front' means that air is sprayed from the nozzle 13 of the powder-coated air gun 10 and is directed toward the object, that is, relatively to the object. Proximity means direction and location. For example, if the left side is close to the object to be coated when the nozzle 13 is extended left and right, the left side becomes the front end and the front end of the nozzle 13 , and the right side becomes the rear end and the rear end of the nozzle 13 .

In this reference, a detailed description including the assembly direction and position of the detailed configuration of the present invention is performed as follows.

In the present invention, the powder-coated air gun 10 has a shape similar to that of a pistol, and includes a body 11 that sucks in external air, pumps it at a high pressure, and sprays it with a nozzle 13, and one side of the body 11 It is equipped with a handle 12 including a trigger that serves as a switch for pumping air while providing a gripping space, and a nozzle 13 that extends long to the tip like a gun barrel of a pistol and sprays air to the outside. have. At this time, the nozzle 13 is provided with a hollow 14 that is a space for air injection.

On the other hand, in the known powder coating process, there is a powder coating gun that is formed in a gun shape similar to the powder coating air gun 10 and sprays paint. It is similar, but the difference is that it sprays air to peel off the paint or blow it away, rather than spraying the paint.

The air distribution device 100 of the present invention includes several components mounted on the hollow 14 of the nozzle 13 and the outer peripheral surface of the nozzle 13 by improving the nozzle of the powder-coated air gun 10 .

Specifically, referring to FIG. 1 , it can be seen that the air distribution device 100 of the present invention includes a guide pipe 110 , a guide dome 120 , and a cover pad 130 .

The guide pipe 110 is mounted in the hollow 14 of the nozzle 13, and has a hollow inside, that is, a hollow 14 in the nozzle 13 in a state with the first hollow 111. It takes a shape similar to a pipe extending a certain length along the longitudinal direction of

Since the guide pipe 110 is mounted in the hollow 14 of the nozzle 13 as described above, the front end of the guide pipe 110 in the air spraying direction is open and the rear end in the opposite direction is closed based on the air spraying direction. (13) is made of a smaller diameter than the hollow 14 of the nozzle 13 so that a uniform gap is generated between the periphery of the outer circumferential surface of the guide pipe 110 and the inner circumferential surface of the hollow 14 of the nozzle 13. 14) is mounted on the central part.

In this gap, the air sprayed from the nozzle 13 is reflected by the cover pad 130 to be described later, and the air movement path 170 guides the air to the discharge hole 114 by the suction force of the impeller 112. becomes At this time, the guide pipe 110 has a length shorter than the length of the nozzle 13 and is mounted at a position slightly moved backward than the front among the entire length of the nozzle 13 to secure the remaining space at the tip of the nozzle 13 . do it

In addition, although not shown in the drawings, a connecting member connecting the outer circumferential surface of the guide pipe 110 and the inner circumferential surface of the hollow 14 in the nozzle 13 may be radially formed around the guide pipe 110 .

An impeller 112 is mounted in the first hollow 111 of the guide pipe 110 . The impeller 112 is rotated by the power of the motor 113 , and the wings are bent backward of the guide pipe 110 to guide the air reflected from the cover pad 130 to the rear, which is the opposite direction to the air injection direction.

In the guide pipe 110 in which the impeller 112 is located, a plurality of discharge holes 114 are penetrated along the periphery of the inner peripheral surface of the first hollow 111 .

The discharge hole 114 is penetrated in plurality at regular intervals along the circumferential direction on the inner circumferential surface of the first hollow 111 in the guide pipe 110 in which the impeller 112 is located, or the first hollow in the guide pipe 110 . It is possible to form through most of the parts except for the minimum connection part in the inner peripheral surface of (111).

The discharge hole 114 is the first movement of the air injected along the nozzle 13 to the air space 121 of the guide dome 120 to be described later, or the air reflected by the cover pad 130 is the air movement path ( 170) to provide a space for secondary movement.

At this time, in order for the air moved through the discharge hole 114 to move to the air space 121 of the guide dome 120 to be described later, the nozzle 13 also has a hole in the shape and position corresponding to the discharge hole 114 . It is, of course, perforated.

The guide dome 120 of the present invention is formed in a dome shape like a plate in a state where a coupling hole (not shown) is penetrated in the central portion, so that the inner circumferential surface (inner surface) is the extension direction of the nozzle 13 , that is, The structure toward the tip of the nozzle 13 is taken.

The guide dome 120 may be mounted to the nozzle 13 in such a way that the nozzle 13 is fitted into the coupling hole. .

The guide dome 120 includes an air space 121 that communicates from the central portion fitted to the nozzle 13 in a state of internal communication with the discharge hole 114 (including the hole of the nozzle).

The air space 121 is radially penetrated between the thickness between the inner circumferential surface and the outer circumferential surface of the guide dome 120 or penetrated inside in a range that can ensure the minimum shape and durability of the guide dome 120 . consists of structure.

That is, the air space 121 may be a space that penetrates the inside of the guide dome 120 , or may be formed of a plurality of internally communicated tubular structures from the central portion to the peripheral portion in a radial shape or the like.

The air discharge pipe 122 is internally communicated toward the inner circumferential surface of the guide dome 120 at various positions of the air space 121 . That is, it means that the air discharge pipe 122 is connected to the inner peripheral surface from several predetermined positions in the air space 121 of the guide dome 120 .

The air discharge pipe 122 provides a function of discharging the air moved from the nozzle 13 and the guide pipe 110 to the air space 121 in front of the nozzle 13, that is, in the direction of the object to be coated. do.

The cover pad 130 of the present invention has a function of sealing the portion remaining after the guide pipe 110 is mounted among the hollow 14 of the nozzle 13 , that is, a portion located in front of the tip of the guide dome 120 . to provide.

Such a cover pad 130 may be made of a thin plate like a known pad or panel, or if it provides a function of blocking the air sprayed from the nozzle 13, it may be made of a thin thickness, such as a sheet or a film.

Based on the above-described structure, the function and operation of the air distribution device 100 of the present invention will be described with reference to FIG. 2 as follows.

2 is a cross-sectional view showing an air flow through the air distribution device of the present invention.

First, the air injected from the nozzle 13 moves to the tip (front) of the nozzle along the hollow 14, and since the guide pipe 110 is mounted in the hollow 14 of the nozzle 13, the guide pipe 110 Air is moved through the gap between the and the hollow 14 of the nozzle 13 , that is, the air movement path 170 .

At this time, in the air movement path 170, a hole is drilled at the position where the discharge hole 114 of the guide pipe 110 is formed, so that it is internally communicated with the air space 121 of the guide dome 120, so that a part of the air is part of the air space 121 ) is moved to

However, as the air injected into the nozzle 13 moves to the air movement path 170 that is narrower than the hollow 14 of the nozzle 13, the movement speed is increased, and the air space ( The amount of air moving along the air movement path 170 is greater than the air moving to 121).

The air that has moved along the air movement path 170 passes through the outer peripheral surface of the guide pipe 110 and goes toward the tip of the nozzle 13 , and the cover pad is placed on the tip of the nozzle 13 that has passed through the guide pipe 110 . A 130 is mounted to block the inlet side of the hollow 14 of the nozzle 13 so that air is reflected on the cover pad 130 .

In this process, if the extended surface of the cover pad 130 extends vertically in the direction of air movement, the air may be randomly reflected or may not be efficiently guided in the guide pipe 110, that is, in the first hollow 111 direction. , the terminal shape of the cover pad 130 is convexly rounded toward the tip of the nozzle 13, and as a result, the inner surface of the cover pad 130 is rounded like a concave lens, so that the focal point is focused on the guide pipe 110 ) is located in the first hollow 111 of the cover pad 130, it is more preferable to efficiently guide the reflected air to the first hollow 111 of the guide pipe (110).

Since the rotation of the impeller 112 guides the air in the rear end direction of the nozzle 13, the air naturally reflected by the cover pad 130 can go back to the air movement path 170 again. This air movement path 170 Since there is air sprayed from the nozzle 13, the action of avoiding it and the action of rotating the impeller 112 are combined, so that most of the air flows in the direction of the tip of the guide pipe 110, that is, in the first hollow 111 direction. .

The air introduced into the first hollow 111 of the guide pipe 110 is moved backward by the rotation of the impeller 112 , and then through the hole of the discharge hole 114 and the nozzle 13 , the air space of the guide dome 120 . The air introduced into the 121 and introduced into the air space 121 is finally injected in the direction of the inner circumferential surface of the guide dome 120 through the air discharge pipe 122 .

In addition, the guide dome 120 is formed in a dome shape such as a unique concave lens, as if the focus is concentrated on a specific spot or area that has passed the tip of the nozzle 13. In the air discharge pipe 122, A kind of vortex occurs while the injected air repeatedly collides and retrogrades on the inner circumferential surface of the guide dome 120 several times. is sprayed with

In addition, due to the power of the impeller 112 and the thin thickness of the air movement path 170 along with the nature of the air being concentrated in this spot/region, the pressure of the air injected from the air discharge pipe 122 achieves a certain level of high pressure. can guarantee

In this way, in order to focus the air to a specific spot/region in front of the nozzle 13, the inner circumferential shape of the guide dome 120, that is, the terminal shape, has a semicircular shape having the same distance from the circumference to the center rather than an ellipsoid or other round shape. more preferably.

As a result, the air that has passed through the air distribution device 100 of the present invention can be sprayed while ensuring high pressure to a specific spot or area of the object to be coated. The paint that has been unevenly painted on the object cannot be naturally blown away or peeled off because it is not concentrated and spreads unnecessarily around the object. It provides features that can efficiently solve cumbersome problems.

3 is a cross-sectional view illustrating a structure in which the air distribution device of the present invention further includes a shade and a direction control ring.

Referring to FIG. 3 , the air distribution device 100 of the present invention may further include a shade 140 and a direction control ring 150 .

3 shows that the shade 140 and the direction control ring 150 are included in the air distribution device 100 together, but these are not necessarily included together, and any one of them may be included as needed.

The shade 140 performs the shape and function like a shade in the lighting device, and the tip of the nozzle is taper with a second hollow 141 and tapered after rotation. It extends toward and takes a structure coupled to the peripheral portion of the guide dome 120 .

That is, it provides a function of naturally spreading the air discharged from the air discharge pipe 122 of the guide dome 120 along the tapered surface of the shade 140, and a known powder-coated air gun indiscriminately rolls air. Unlike the spreading as shown above, through the function of the air distribution device 100 described above, the air can be spread around a specific spot or area of the object to be coated in a state where the pressure of the air is sufficiently ensured, so the operator's convenience in air injection position manipulation Not only can it be achieved, but also has a function of preventing the air from spreading to the outside of the shade 140 .

In addition, the direction control ring 150 is a structure mounted on the outer circumferential surface of the nozzle 13 located in front of the cover pad 130 as being mounted together with the above-described shade 140 or mounted alone. At this time, the direction control ring 150 may be fitted to the outer circumferential surface of the nozzle 13 with a through hole in the center.

In particular, the direction control ring 150 includes a rear end surface 151 that is inclinedly extended in the direction of the front end of the nozzle 13, and an inclined surface 152 that is inclined from the end of the rear end surface 151 toward the front end of the nozzle 13. includes

According to this structure, when the air discharged from the air discharge pipe 122 toward the inner circumferential surface of the guide dome 120 is focused on a specific point of the nozzle 13 that does not reach the object to be coated and does not reach it, the air is discharged after After reflecting toward the circumferential direction of the guide dome 120 in the cross section 151, the air that has reached the circumference of the guide dome 120 is reflected back on the inner circumferential surface of the guide dome 120 to spread the air distribution than before. .

In addition, it also serves to guide the air through the inclined surface 152 to prevent it from spreading too much outward.

That is, the direction control ring 150 may provide a characteristic for controlling the direction of the air so that the air can be spread appropriately wider than the center of the nozzle 13 while preventing the air from being biased toward the center of the nozzle 13 .

4 is a cross-sectional view illustrating a structure in which the air distribution device of the present invention further includes a diffusion ring.

As can be seen from FIG. 4 , in the outer peripheral surface of the nozzle 13 located in front of the cover pad 130 in the air distribution device 100 of the present invention, the nozzle 13 is penetrated in a direction from the rear end to the front end. It is possible to include a diffusion ring 160 having a plurality of diffusion holes 161 .

The diffusion ring 160 is a configuration that can replace the function of the direction control ring 150 or the shade 140 described above, and the air discharged from the guide dome 120 does not extend in a straight line but is partially diffused and sprayed. By diffusion-guiding the direction of air through the diffusion hole 161 so that it can be applied, it provides a property of preventing the air from being concentrated in a specific spot/region while covering a specific area of the object to be coated as described above.

As described above, the inner circumferential surface of the guide dome 120 is formed in a dome shape, and the air discharged from the air discharge pipe 122 through this repeats collision and reflection around the inner circumferential surface of the guide dome 120 to generate a vortex. Finally, a function of spraying air is provided, and above all, the inner circumferential surface of the guide dome 120 must ensure that the air can be efficiently reflected.

To this end, the inner circumferential surface of the guide dome 120 may be coated with a coating layer having slippery properties, and in the present invention, such a coating layer is referred to as a friction reducing layer and includes a specific composition.

Specifically, the inner circumferential surface of the guide dome 120 may be coated with a friction reducing layer including dodecyl alcohol polyoxyethylene ether.

Dodecyl alcohol polyoxyethylene ether (dodecyl alcohol polyoxyethylene ether) is a nonionic surfactant, and when added, increases the flexibility of the film and increases the mixability between components, as well as the slip property of the air reflected on the inner circumferential surface of the guide dome 120 improvement can be maximized.
As described so far, the configuration and operation of the air distribution device for a powder-coated air gun with enhanced air diffusion function according to the present invention have been expressed in the above description and drawings, but this is only an example and the spirit of the present invention is not limited to the above description and It is not limited to the drawings, and various changes and modifications are possible without departing from the technical spirit of the present invention.

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10: powder coating air gun 11: body
12: handle 13: nozzle
14: hollow 100: air distribution device
110: guide pipe 111: first hollow
112: impeller 113: motor
114: discharge hole 120: guide dome
121: air space 122: air discharge pipe
130: cover pad 140: shade
141: second hollow 150: direction control ring
151: rear end surface 152: inclined surface
160: diffusion ring 161: diffusion hole
170: air movement path

Claims (9)

An air distribution device mounted on a powder-coated air gun that discharges air through a nozzle protruding from the tip, comprising:
In a state with a first hollow therein, the front end is open and the rear end is closed, and is mounted in the hollow of the nozzle with a diameter smaller than the inner circumferential surface of the nozzle. 1 a guide pipe including a discharge hole penetrated along the periphery of the hollow inner circumferential surface;
An air space communicating from the central portion to the peripheral portion in a state in which the coupling hole for fitting the nozzle has a dome shape while penetrating through the central portion, the inner circumferential surface faces the tip of the nozzle, and is in internal communication with the discharge hole; a guide dome including a plurality of air discharge tubes internally communicated from the air space to the inner circumferential surface;
Air distribution device comprising a; cover pad for sealing the hollow portion located in front of the front end of the guide dome in the nozzle. The method of claim 1,
The terminal shape of the guide dome is characterized in that the semicircular shape, the air distribution device. The method of claim 1,
The terminal shape of the cover pad is,
Air distribution device, characterized in that it has a convexly rounded shape toward the tip of the nozzle. The method of claim 1,
The air distribution device,
Air distribution device comprising a; a shade extending toward the tip of the nozzle and coupled to the guide dome while having a second hollow and tapered after rotation . The method of claim 1,
On the outer peripheral surface of the nozzle located in front of the cover pad,
A direction adjustment ring is installed,
The terminal shape of the direction control ring is,
The air distribution device, characterized in that it comprises a rear end surface inclined in the direction of the front end of the nozzle, and an inclined surface extending from the end of the rear end face toward the front end of the nozzle. The method of claim 1,
On the outer peripheral surface of the nozzle located in front of the cover pad,
An air distribution device, characterized in that a diffusion ring having a plurality of diffusion holes penetrated so as to be mutually spaced apart from the rear end of the nozzle to the front end direction is mounted. delete delete delete

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