KR102625682B1 - Straight-line enhancing air film forming device and dust-free spray gun including the same - Google Patents

Abstract

The present invention relates to an apparatus for forming an air film that enhances straightness and an anti-scattering spray gun including the same. More specifically, the present invention relates to an air film forming device that enhances straightness and to an anti-scattering spray gun including the same. More specifically, it improves straightness by forming a plurality of air films on the left and right sides, and forms a closed curved surface through mutual attraction in the upper and lower directions to form a closed curved surface to form a plurality of air films on the left and right sides. It relates to an air film forming device that enhances straightness and can block scattering and improve the working environment, and to an anti-scattering spray gun including the same.
An air film forming device that enhances straightness according to an embodiment of the present invention is a device mounted on a spray nozzle that sprays paint, and includes a nozzle block surrounding the spray nozzle and a nozzle arm that extends to both sides of the nozzle block and bends forward. and a nozzle connecting means sliding in the longitudinal direction in front of the nozzle arm, and a side air nozzle connected to the nozzle connecting means and having second slits formed on both sides of the first slit.
In addition, the side air nozzle includes a pair of air nozzle bodies having a flat plate shape and a through hole formed therein, and a first gasket having a first fan-shaped cut groove formed between the air nozzle bodies, and the air nozzle body is supplied through the through hole. Air is injected through the first slit formed in the first cut groove, and a flat air nozzle body is added to both sides of the air nozzle body to form a fan-shaped second cut groove between the air nozzle body and the air nozzle body. Air supplied through the through hole, including the formed second gasket, may be sprayed through the second slit formed in the second cut groove.

Description

Straight-line enhancing air film forming device and dust-free spray gun including the same}

The present invention relates to an apparatus for forming an air film that enhances straightness and an anti-scattering spray gun including the same. More specifically, the present invention relates to an air film forming device that enhances straightness and to an anti-scattering spray gun including the same. More specifically, it improves straightness by forming a plurality of air films on the left and right sides, and forms a closed curved surface through mutual attraction in the upper and lower directions to form a closed curved surface to form a plurality of air films on the left and right sides. It relates to an air film forming device that enhances straightness and can block scattering and improve the working environment, and to an anti-scattering spray gun including the same.

The work of applying or painting paint or waterproofing agents is carried out throughout the industry. In the past, workers used brushes, brushes, and rollers to paint, but now it is common to use spray guns to paint.

A spray gun is a pistol-shaped device that an operator can hold in his hand and spray paint directly on the painted surface. It sprays paint in the form of dust (fine droplets) through a nozzle attached to the front. So that it adheres to the painted surface. However, painting work using a spray gun has the problem of scattering paint dust, causing contamination of buildings, parked cars, and other facilities.

In addition, during painting work, approximately 40% of the paint sprayed through the spray gun scatters, which not only causes loss of paint in the amount of scattering, but also reduces the rate of adhesion to the painted surface, making painting work more difficult. Problems such as reduced efficiency, loss of labor, and increased costs occur.

To solve this problem, a number of methods to prevent paint scattering have been proposed. Devices to prevent scattering typically use a method of installing a cover surrounding the nozzle or spraying air around the nozzle to form an air curtain. In particular, in the method of using an air curtain, air nozzles are arranged around the spray nozzle to form an air curtain.

Conventional air nozzles were generally hole-shaped and had a structure in which a plurality of air nozzles were arranged in a circle at regular intervals around the spray nozzle. In the case of this structure, the cross section of the injected air is circular and overlaps with the circular air coming from adjacent air nozzles, so the thickness of the formed air curtain is not constant and thick and thin parts alternately repeat.

Therefore, although the paint is well blocked in thick areas, there is a disadvantage in that the blocking of scattering may be incomplete in areas where the air curtain is thin. In addition, while the shape of the application area of the paint sprayed from the spray nozzle forms a long oval shape from top to bottom, the air curtain is made of a circle, so in order to cover the long oval, the air nozzle must be arranged in a very large circle.

Additionally, the application area of the sprayed paint varies depending on the type of work, environment, and type of spray gun. In other words, the width of the left and right sides is almost constant, but the width of the top and bottom varies, so there is the inconvenience of having to separately install an air nozzle that can create an air curtain that matches the width.

In order to solve this problem, the present inventor applied for and registered the invention titled "Air film forming discharge device and anti-scattering spray gun including the same" and improved the slit shape to obtain advanced results. Through further research and development, we aim to simplify the configuration and implement a more efficient air film forming device.

Korean Patent No. 10-2549033, title of the invention “Air film forming discharge device and anti-scattering spray gun including the same” (registration date 2023.06.23.)

The present invention was created to solve the above-mentioned problems and needs. It forms a plurality of air films on the left and right sides to increase straightness, and forms a closed curved surface with mutual attraction up and down to block paint scattering and improve the working environment. The purpose is to provide an air film forming device that enhances straightness and an anti-scattering spray gun including the same.

In order to achieve the above object, an air film forming device that enhances straightness according to an embodiment of the present invention is a device mounted on a spray nozzle that sprays paint, and includes a nozzle block surrounding the spray nozzle and both sides of the nozzle block. It includes a nozzle arm that extends and bends forward, a nozzle joint means sliding in a longitudinal direction in front of the nozzle arm, and a side air nozzle connected to the nozzle joint means and having second slits formed on both sides of the first slit.

In addition, the side air nozzle includes a pair of air nozzle bodies having a flat plate shape and a through hole formed therein, and a first gasket having a first fan-shaped cut groove formed between the air nozzle bodies, and the air nozzle body is supplied through the through hole. Air is injected through the first slit formed in the first cut groove, and a flat air nozzle body is added to both sides of the air nozzle body to form a fan-shaped second cut groove between the air nozzle body and the air nozzle body. Air supplied through the through hole, including the formed second gasket, may be sprayed through the second slit formed in the second cut groove.

According to the present invention, the air sprayed from the side air nozzle forms a vertically long side air film on the left and right sides of the paint application surface, and the force of pulling the side air film up and down acts to form an air film that touches all directions, preventing the paint from scattering. This has the advantage of preventing damage and reducing the amount of paint used.

In addition, a triple air film is formed on each of the left and right sides sprayed from the side air nozzle, so that straightness can be maintained even when strong wind blows, so there is an advantage in that the application work can proceed smoothly.

In addition, since a strong triple air film is formed, workers can be free from respiratory diseases and various diseases caused by spraying paint, and there is an advantage in resolving inconveniences in the working environment, such as paint getting on the worker's body.

In addition, the side air nozzle forms an oval-shaped side air film that is elongated up and down, surrounding the central paint application surface to block scattering, and creates a vortex, which causes collisions between paints and pulverizes them, thereby increasing roughness.

Figure 1 is a perspective view showing an anti-scattering spray gun including an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing an anti-scattering spray gun including an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 3 is a projection perspective view showing a part of an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 4 is a perspective view showing the AA cross section of Figure 1.
Figure 5 is a cross-sectional perspective view showing a portion of an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 6 is a front perspective view showing a portion of an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 7 is an exploded perspective view illustrating a part of an air film forming device that enhances straightness according to an embodiment of the present invention.
Figure 8 is a cross-sectional exploded perspective view of Figure 7.
Figure 9 is an exploded perspective view from another direction to explain a part of the straightness-enhancing air film forming device according to an embodiment of the present invention.
Figure 10 is an exemplary diagram for explaining the problem to be solved by the present invention.
11 and 12 are conceptual drawings for explaining the present invention.

Since the present invention can be subject to various changes and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

Figure 1 is a perspective view showing an anti-scattering spray gun including an air film forming device that enhances straight ability according to an embodiment of the present invention, and Figure 2 shows a spray gun that includes an air film forming device that enhances straight ability according to an embodiment of the present invention. It is an exploded perspective view showing an anti-scattering spray gun, FIG. 3 is a projected perspective view showing a part of a device for forming a straight-line enhanced air film according to an embodiment of the present invention, and FIG. 4 is a perspective view showing a cross section A-A of FIG. 1. .

In addition, Figure 5 is a cross-sectional perspective view showing a part of an air film forming device that enhances straight-line ability according to an embodiment of the present invention, and Figure 6 shows a part of an air film-forming device that enhances straight-line ability according to an embodiment of the present invention. It is a front perspective view, and FIG. 7 is an exploded perspective view for explaining a part of the straightenability-enhanced air film forming device according to an embodiment of the present invention, and FIG. 8 is a cross-sectional exploded perspective view of FIG. 7.

In addition, Figure 9 is an exploded perspective view from another direction to explain a part of an air film forming device for enhancing straightness according to an embodiment of the present invention, and Figure 10 is an exemplary diagram for explaining the problem to be solved by the present invention. , FIGS. 11 and 12 are conceptual drawings for explaining the present invention.

Now, the configuration and operation of the straight-line enhanced air film forming device 100 and the anti-scattering spray gun 10 including the same according to embodiments of the present invention will be described in detail as follows.

As shown in Figures 1 and 2, the straightness-enhanced air film forming device 100 proposed by the present invention includes a nozzle block 110, a nozzle arm 120, a nozzle joint means 130, and a side air nozzle ( 140) and may further include an air supply line 150, etc.

As shown in FIGS. 1 to 3, the nozzle block 110 may be directly connected to or mounted on the spray nozzle 210 that sprays paint. In addition, the nozzle block 110 has a block shape with an internal air passage, and a branch pipe 111 branching into two branches may be formed therein.

Here, the branch pipe 111 branches into first and second pipes 111a and 111b, as shown in FIG. 3, and the first pipe 111a branches to the left of the nozzle block 110, and the first pipe 111a branches to the left of the nozzle block 110. 2 The pipe (111b) branches off to the right of the nozzle block (110) and is connected to the air supply line (150) so that the supplied air branches and flows into the first and second pipes (111a, 111b).

In addition, the nozzle block 110 may be formed to be integrated with or in close contact with the spray nozzle 210, or may be manufactured integrally without a fastening member, and may surround the linear flow path from the outside so as not to be disturbed when the paint is sprayed, thereby preventing external shock. It can prevent and protect etc.

As shown in FIG. 4, the nozzle arm 120 extends to both sides of the nozzle block 110 as if spreading both arms and is bent forward, and is connected to the branch pipe 111 along the internal longitudinal direction to allow air to flow. A guide pipe 121 that can pass may be formed.

In addition, the nozzle arm 120 has a tilting rotation portion 122 formed on a portion that is bent toward the front, allowing the nozzle arm 120 to be tilted and rotated at a predetermined angle. This is to adjust the air sprayed to both sides of the front to narrow or widen a predetermined interval, and the left and right tilting rotation angle does not exceed 30°.

In particular, the nozzle arm 120 has a length adjustment part 123 formed on the outside of the straight section facing forward, so that the exposed length of the nozzle joint means 130, which will be described later, can be adjusted.

That is, the length adjustment part 123 is formed in a straight section of the nozzle arm 120, so that the nozzle joint means 130 within the nozzle arm 120 can be pulled out and then fixed with a fastening member (headless bolt).

In addition, the nozzle arm 120 is a left and right pair, and includes a first nozzle arm 120a connected to the left side of the nozzle block 110, and a second nozzle arm 120b connected to the right side of the nozzle block 110. Includes.

Therefore, the first nozzle arm 120a has a first guide pipe 121a connected to the first pipe 111a to provide a passage through which air can pass, and the second nozzle arm 120b has a first guide pipe 121a inside it. 2 The induction pipe 121b is connected to the second pipe 111b to provide a passage through which air can pass.

In addition, the tilting and rotating portion 122 includes a first tilting and rotating portion 122a that tilts and rotates the first nozzle arm 120a left and right, and a second tilting rotating portion 122b that tilts and rotates the second nozzle arm 120b left and right. ) will be included.

Furthermore, the length adjustment unit 123 is a first length adjustment unit 123a that slides within the first nozzle arm 120a to adjust the exposed length of the nozzle joint means 130 so that the length is adjusted, and a second nozzle arm ( It includes a second length adjustment unit 123b that slides within 120b) to adjust the exposed length of the nozzle joint means 130 so that the length can be adjusted.

The nozzle joint means 130 is a member that slides in the longitudinal direction in front of the nozzle arm 120, and has a hollow passage surrounding the guide pipe 121 of the nozzle arm 120 formed therein and connected to the guide pipe 121. It can be connected to the side air nozzle 140 through the joint pipe 131.

In particular, since the nozzle joint means 130 can expand and contract along the longitudinal direction within the nozzle arm 120, the drawing length can be adjusted according to the distance at which the paint is to be sprayed.

That is, when the spraying distance needs to be adjusted according to the workplace environment or the characteristics of the product to be applied, it can be pulled out to an appropriate length through the nozzle joint means 130 and fixed by the length adjustment unit 123.

The nozzle joint means 130 secures multiple injection intervals by creating a joint pipe 131 with the tip bent in an 'ㄱ' shape so that each of the pair of side air nozzles 140 can simultaneously form a plurality of air films. Provide space to do so.

In addition, the nozzle connecting means 130 is a pair formed on the left and right sides of the nozzle block 110, and the first nozzle connecting means 130a and the second nozzle arm 120b slide within the first nozzle arm 120a. ) Includes a second nozzle joint means (130b) sliding within.

Therefore, the first nozzle connecting means 130a has a first connecting pipe 131a connected to the first induction pipe 121a to provide a passage through which air can flow, and the second nozzle connecting means 130b has a Inside, the second joint pipe 131b is connected to the second guide pipe 121b to provide a passage through which air can flow.

At this time, the connection portion of the nozzle joint means 130 may be sealed by a sealing member such as an O-ring to prevent air from leaking.

A pair of side air nozzles 140 proposed by the present invention will be described with reference to FIGS. 5 to 9, etc.

The present invention includes an air nozzle body 310, a first gasket 320, an air nozzle subbody 330, and a second gasket 340 for the common configuration of a pair of side air nozzles 140. can be explained together, including

The side air nozzle 140 extends to both left and right sides of the nozzle block 110 and is coupled to the left and right nozzle joint means 130, respectively, which slide in the longitudinal direction of the forward-bent nozzle arm 120 to provide air. By spraying (air), an air film (air curtain) is formed on the left and right sides.

That is, the side air nozzle 140 is provided with air nozzles at the 3 o'clock and 9 o'clock directions of the nozzle block 110, and can form an air film by surrounding the paint sprayed from the spray nozzle 210 from side to side. Additionally, the side air nozzle 140 may have a common structure as shown in FIGS. 7 and 8.

Specifically, the side air nozzle 140 may have a sandwich structure in which the first gasket 320 is inserted between a pair of air nozzle bodies 310 that can be separated into two.

The air nozzle body 310 is made of a flat plate shape with a predetermined thickness, and a pair is formed in close contact. At this time, the contact surface of the air nozzle body 310 may be a vertical surface, but as shown in Figures 7 to 9, etc., it has an inclined surface and guides the path of the injected air to be inclined outward, so that the air film (air curtain) spreads up and down. You can make it go out.

The first gasket 320 has a constant thickness and the same cross-sectional shape as the air nozzle body 310, but is cut forward to form a first cut groove 321 in which the first opening 322 is formed. At this time, the first cutting groove 321 is 'U', 'V', '┗┛' or ' It may have a fan-shaped shape such as '.

That is, inclined inclined portions 323 may be formed on the upper and lower sides of the first opening 322 of the first cutting groove 321, and are inclined in the direction in which the first opening 322 is expanded. In addition, a through hole 311 through which air is supplied is formed in the center of the air nozzle body 310.

For reference, as described above, the through hole 311 of the side air nozzle 140 may be connected to the joint pipe 131 and ultimately communicate with the air supply line 150.

With this structure, the two air nozzle bodies 310 combined are spaced apart by a width corresponding to the thickness of the first gasket 320, and a nozzle space is formed in the area where the first cut groove 321 is located. , the air nozzle body 310 and the first opening 322 form a first slit 141 forming a long gap.

Therefore, when compressed air flows in through the through hole 311, it can be sprayed forward through the first slit 141, and the air can spread like a fan at a certain angle by the first inclined portion 323. Here, the first slit 141 of the side air nozzle 140 is arranged vertically long on the left and right sides.

In addition, as shown in FIG. 7, the air nozzle body 310 in which the through hole 311 is formed has a first first slit that temporarily accommodates the air supplied through the through hole 311 and is injected through the first slit 141. A chamber 312 may be formed.

In particular, the side air nozzle 140 further includes a pair of air nozzle units 330 on both sides of the air nozzle body 310, so that the air discharged through the first slit 141 is directed to the second slit 142 formed on the left and right sides. You can further increase straightness by guiding the route.

That is, the air nozzle body 330 can be separated into two, and the air nozzle body 310 is interposed between a pair of air nozzle bodies 330, and one side of the air nozzle body 310 and the air nozzle It may have a three-layer sandwich structure in which a second gasket 340 is inserted between the floating bodies 330 and between the other side of the air nozzle body 310 and the air nozzle floating body 330 (see FIG. 6, etc.).

The air nozzle body 330 is made of a flat plate shape with a predetermined thickness, is divided into two, and is placed in close contact with the air nozzle body 310 on both sides. At this time, the contact surface of the air nozzle body 330 may be a vertical surface, but it has an inclined surface as shown in FIGS. 7 to 9, so that the path of the injected air is inclined outward.

The air nozzle body 330 guides the air discharged through the first slit 141 to the second slit 142 formed on the left and right sides, thereby improving straightness and concentrating the discharge of air at a distance. .

In particular, the air discharged from the first slit 141 and the second slit 142 has a high pressure of 5 to 7 bar, so it has a certain degree of straightness, but the main compressed air discharged from the first slit 141 flows in all directions at a certain limit. Even if it tries to spread, the sub-compressed air discharged from the second slit (142) prevents the main compressed air from the first slit (141) from spreading and helps it travel more straight.

In addition, as shown in FIG. 5, the air discharged from the second slit 142 due to the Coanda effect flows along both sides of the air nozzle body 310 along with the surrounding air, so that the flow rate of the discharged compressed air It amplifies and allows it to spread out straight.

And the second gasket 340 has a constant thickness and a cross-sectional shape corresponding to the air nozzle body 330, and is cut forward to form a second cut groove 341 in which the second opening 342 is formed. . At this time, the second cutting groove 341 is 'U', 'V', '┗┛' or ' It may have a fan-shaped shape such as '.

That is, inclined inclined portions 343 may be formed on the upper and lower sides of the second opening 342 of the second cutting groove 341, and are inclined in the direction in which the second opening 342 is expanded. In addition, the center of the air nozzle float 330 is connected to a through hole 311 through which air is supplied.

In addition, as shown in FIG. 7, the air nozzle body 330 connected to the through hole 311 temporarily accommodates the air supplied through the through hole 311 and sprays it through the second slit 142. Two chambers 332 may be formed.

Consists of this structure, one of the pair of air nozzle bodies 330 has a width corresponding to one side of the air nozzle body 310, and the other has a width corresponding to the thickness of the other side of the air nozzle body 310 and the second gasket 340. are spaced apart from each other, a nozzle space is formed in the portion where the second cutting groove 341 is located, and the air nozzle body 330 and the second opening 342 form a second slit 142 forming a long gap. . At this time, one of the second gaskets 340 is between the air nozzle body 330 and one side of the air nozzle body 310, and the other one of the second gaskets 340 is between the air nozzle body 330 and the air nozzle body ( 310) is inserted between the other sides, and the second slit 142 is also formed on both sides of the air nozzle body 310 corresponding to the left and right sides of the first slit 141.

Therefore, when compressed air flows in through the hole 311 and the main air is sprayed forward through the first slit 141, the second slits 142 formed on both sides of the first slit 141 assist the sub air. It can be sprayed forward, and the air can spread like a fan at a certain angle by the second inclined portion 343. Here, the second slit 142 of the side air nozzle 140 is disposed long up and down on both sides of the first slit 141.

In addition, the side air nozzles 140 are spaced forward on both sides of the nozzle block 110 and can be divided into a first side air nozzle 140a on the left and a second side air nozzle 140b on the right. The nozzle 140a may include first and second slits 141a and 142a, and the second side air nozzle 140b may include first and second slits 141b and 142b.

On the other hand, when the slit is arranged to form a rectangle, it receives a lot of air pressure toward the center and opens convexly, weakening the straight flow of air, and it has been confirmed through experiments and research that the larger the slit width (w) is, the more it spreads toward the center.

Therefore, the air nozzle proposes first and second slits 141 and 142 with the slit thickness at both ends gradually narrowing toward the center, as shown in Figures 10(b) and 11.

That is, as shown in Figure 10 (b), the slits 141 and 142 of the air nozzle proposed by the present invention have a slit thickness at both ends gradually narrowing toward the center, so that the slit thickness at both ends is "t". If the center slit thickness is "d", 0.2mm < t < 0.4mm, forming 0.4t < d < 0.8t.

Here, the slit of the air nozzle differs slightly depending on the application field, such as automobiles or ships, but is so fine as 0.2 to 0.4 mm that the gap is so small that it cannot be perceived by the eye.

However, the examples of slits are exaggerated to easily explain the present invention, and the thickness (t) of the slit is very fine, but the quality of the paint varies greatly due to this slight difference.

Therefore, in the present invention, if the slit thickness at both ends is "t", as shown in Figure 10 (b), the slit thickness (d) in the middle must be smaller than "t" and the smaller amount is the width of the slit ( It depends on w) and air pressure, and the optimal experimental data result is to keep the center thickness (d) between 0.4 and 0.8 times less than the end thickness (t).

Furthermore, the slits 141 and 142 proposed by the present invention have a shape in which one side and the other side are concave together in the center, as shown in Figures 11 (a) and (d), or Figure 11 (b) ,(c), (e), and (f), one side may remain flat while the other side may be concave toward the center.

In addition, the slits 141 and 142 are round and concave in the center, as shown in (a), (b), and (c) of Figures 11, or (d), (e), and (f) of Figures 11 (d), (e), and (f). ), it may have a shape that is bent at an angle at the centers P1 and P2 and narrows to the center.

' 형상의 제1 절개홈(321)이 형성된 제1 가스켓(320)을 포함하여 상기 통공(311)을 통해 공급되는 에어가 상기 제1 절개홈(321)이 형성되는 상기 제1 슬릿(141)을 통해 분사될 수 있다.In summary, the side air nozzles 140 are spaced a predetermined distance apart on both sides in front of the nozzle block 110 and are connected to the first and second slits 141a and 142a of the first side air nozzle 140a and the second side air nozzle. The first and second slits (141b, 142b) of (140b) are formed. In addition, the first side air nozzle 140a and the second side air nozzle 140b formed on both sides of the front of the nozzle block 110 are a pair of air nozzle bodies 310 that have a flat plate shape and have a through hole 311, and , 'U', '┗┛', or 'between the air nozzle body 310.

The air supplied through the through hole 311, including the first gasket 320 in which the 'shaped first incision groove 321 is formed, is directed to the first slit 141 in which the first incision groove 321 is formed. It can be sprayed through.

At this time, the air nozzle body 330, which can be separated into two, is separated and adhered to both sides of the air nozzle body 310, between one side of the air nozzle body 310 and the air nozzle body 330, and the air nozzle body 310. 'U', '┗┛', or 'between the other side and the air nozzle float (330) '-shaped second cut groove 341 is formed in the second gasket 340, and the air supplied through the through hole 311 is formed in the second slit 142 in which the second cut groove 341 is formed. The air sprayed through the first slit 141 can be guided from both sides to further increase straightness, thereby increasing spraying efficiency.

In addition, high-pressure air simultaneously sprayed from the side air nozzle 140 into three layers (one first slit and two second slits) passes through the spray nozzle 210 and surrounds and pulls the sprayed paint from side to side. It accelerates and moves straight, and forms an air curtain (air curtain) that contacts the top and bottom at a distance of 300 ~ 500mm (L) to prevent the paint (P) from scattering and protect the surrounding environment.

In other words, in the past, respiratory diseases and various diseases could occur in workers due to the scattering of paint, and the working environment was very poor, with scattered paint getting on the workers' bodies.

However, a triple high-pressure air film is formed through the first and second slits 141 and 142 proposed by the present invention, thereby preventing scattering of the paint, thereby improving the health of workers, and reducing the amount of paint used by 10%. It is economically very advantageous as it can save a certain amount of money.

In particular, even without the upper and lower air nozzles, a triple air film (air curtain) is formed on each of the left and right sides with only the side air nozzle 140 proposed by the present invention, and the high pressure compressed air on the upper and lower sides is mutual. The pulling force narrows it into contact, allowing an air film to form in all directions, up, down, left and right.

In other words, conventionally, an air membrane (air curtain) was created by spraying air from the top, bottom, left, and right sides using four nozzles, but in the present invention, an air membrane (air curtain) was created using only two nozzles, left and right. ) can be formed.

This means that when compressed air, which replaces the use of the upper air nozzle and lower air nozzle, is sent from the side air nozzle 140 proposed by the present invention, the compressed air is blown a certain distance from the upper and lower sides of the left and right air membranes, respectively. When they reach , a pulling effect occurs and they overlap, forming an air film (air curtain) as shown in Figure 12. At this time, the internal area where the paint P is sprayed is in a vacuum state, allowing it to have an oval shape that extends vertically.

That is, as shown in FIG. 12, the air simultaneously sprayed from the first side air nozzle 140a and the second side air nozzle 140a passes through the spray nozzle 210 and is around the sprayed paint P. As it becomes a vacuum state, it is surrounded by a 3-layer (141a, 142a) side barrier (F) on the left and 3-layer (141b, 142b) on the right, allowing for more straight movement than before, but pulling the side barrier (F) up and down. Since the force acts to form an air film on the top and bottom, the conventional upper and lower air nozzles are eliminated.

Meanwhile, the air nozzle body 310 and the air nozzle subbody 330 according to another embodiment of the present invention have the first gasket 320 between the air nozzle bodies 310, as shown in FIG. It may be formed to extend integrally from the surface to a predetermined height. That is, the air nozzle body 310 can be applied without a separate first gasket 320 by integrally protruding from either the left or right surface as much as the thickness of the first gasket 320.

This is because it is cumbersome to insert and assemble the first gasket 320 between the air nozzle bodies 310, and also for the purpose of increasing the precision of the slit thickness between the air nozzle bodies 310.

Likewise, the second gasket 340 may be formed to extend integrally to a predetermined height from either the surface of the air nozzle body 330 attached to one side of the air nozzle body 310 or the other side.

As shown in FIG. 4, etc., air can be supplied along the red line through the air supply line 150.

The air supply line 150 is connected to the side air nozzle 140 from an air supply source such as an air compressor through the branch pipe 111, the guide pipe 121, and the joint pipe 131, and the connected side air nozzle 140 ) may communicate so that air is sprayed into the first and second slits 141 and 142 through the through hole 311.

Accordingly, the straight-line enhanced air film forming device 100 and the anti-scattering spray gun 10 including the same according to an embodiment of the present invention operate as follows.

When the operator holds and presses the handle 220, air is supplied through the air supply line 150 and at the same time, the paint is sprayed like fog with fine particles through the spray nozzle 210.

Generally, the sprayed paint is applied in an oval shape that is elongated up and down.

When air is supplied through the air supply line 150, it branches to the branch pipe 111 of the nozzle block 110, passes through the guide pipe 121 and the joint pipe 131, and flows into the side air nozzle 140, After being delivered to the first and second chambers 312 and 332 of the side air nozzle 140 through the through hole 311 of the side air nozzle 140, the first and second slits ( It is sprayed through 141 and 142, and the air is spread by the first and second inclined portions 323 and 343.

At this time, the air sprayed from the side air nozzle 120 forms a vertically long side air film (F) on the left and right sides of the paint application surface, and as shown in FIG. 12, the side air film (F) is formed at the end of the spray distance. Mutual attraction acts upward and downward, forming an air film with closed curves above and below, which can block the scattering of paint.

In other words, the paint blocks the center of the side air membrane (F), allowing a certain gap to be maintained, but the paint is thinned on the top and bottom, so it does not prevent the left and right air membranes from sticking to each other due to the air flow rate.

In addition, a triple air film is formed on each of the left and right sides discharged from the side air nozzle 120, so that straight movement can be maintained even when strong wind blows, allowing the application process to proceed.

In addition, the side air nozzle 120 forms an oval-shaped side air film (F) up and down and surrounds the central paint application surface, thereby blocking scattering and causing eddy currents to cause collisions between paints, reducing roughness. can be raised.

As such, the straightness-enhanced air film forming device 100 according to embodiments of the present invention is a device mounted on a spray nozzle 210 that sprays paint, and includes a nozzle block 110 surrounding the spray nozzle 210 and , a nozzle arm 120 extending to both sides of the nozzle block 110 and bent forward, a nozzle connecting means 130 sliding in the longitudinal direction in front of the nozzle arm 120, and the nozzle connecting means 130, and It includes a side air nozzle 140 in which first and second slits 141 and 142 of upper and lower length are connected and formed in parallel.

In addition, the side air nozzle 140 includes a pair of air nozzle bodies 310 in a flat plate shape with a through hole 311, and a first cut groove 321 in the shape of a fan between the air nozzle bodies 310. Air supplied through the through hole 311, including the formed first gasket 320, is sprayed through the first slit 141 formed in the first cut groove 321.

In addition, flat air nozzle sub bodies 330 are added to both sides of the air nozzle main body 310, and a fan-shaped second cut groove 341 is formed between the air nozzle main body 310 and the air nozzle sub body 330. Air supplied through the through hole 311, including the second gasket 340, is injected through the second slit 142 formed in the second cut groove 341.

In addition, the air simultaneously sprayed from the side air nozzle 140 passes through the spray nozzle 210 and surrounds the sprayed paint in three layers on the left and right, respectively, so that it travels straight, but mutual attraction acts upward and downward to form a closed curved surface. This is formed.

That is, the air simultaneously injected from the side air nozzle 140 passes through the spray nozzle 210 and forms a vertically long side air film (F) on the left and right sides of the sprayed paint application surface, and the side air film (F) The forces pulling each other up and down act to form a closed curved surface.

In addition, the side air nozzle 140 includes a first side air nozzle 140a connected to be spaced apart in front of one side of the nozzle block 110, and a second side air nozzle 140a connected to be spaced apart in front of the other side of the nozzle block 110. Includes a nozzle 140b.

In addition, the paint sprayed from the spray nozzle 210 for spraying the paint is air sprayed from the first and second slits of the first side air nozzle 140a on one side, and the second side air nozzle (140a) on the other side. It may be surrounded on all sides by air sprayed from the first and second slits of 140b), forming an oval shape.

Additionally, the first slit of the first side air nozzle 140a and the first slit of the second side air nozzle 140b may be left and right symmetrical so that the inner surface is concave to the outside.

In addition, a first chamber is formed in the air nozzle body in which the through hole is formed to temporarily accommodate the air supplied through the through hole and causes it to be sprayed through the first slit, and the air nozzle body in communication with the through hole is provided with the through hole. A second chamber may be formed to temporarily accommodate the air supplied through the air and allow it to be sprayed through the second slit.

In addition, the anti-scattering spray gun 10 according to an embodiment of the present invention may include any one of the straight-line enhancement air film forming devices 100 according to various embodiments of the present invention.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications, changes, and substitutions can be made by those skilled in the art without departing from the essential characteristics of the present invention. will be.

Accordingly, the embodiments disclosed in the present invention and the attached drawings are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments and the attached drawings. .

The scope of protection of the present invention should be interpreted in accordance with the claims described below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

10: Anti-scattering spray gun of the present invention
100: Air film forming device of the present invention
110: nozzle block 111: branch pipe
111a, 111b: Buildings 1 and 2
120, 120a, 120b: nozzle arm, first and second nozzle arms
121, 121a, 121b: guide tube, first and second guide tubes
122, 122a, 122b: Tilting rotating portion, first and second tilting rotating portions
123, 123a, 123b: length adjustment unit, first and second length adjustment units
130, 130a, 130b: nozzle connection means, first and second nozzle connection means
131, 131a, 131b: joint pipes, first and second joint pipes
140, 140a, 140b: side air nozzle, first and second side air nozzles
141, 141a, 141b: first slit, 1st a and 1b slits
142, 142a, 142b: second slit, 2nd a and 2b slits
310: Air nozzle body 311: Through hole
312: first chamber 320: first gasket
321: first cut groove 322: first opening
323: first inclined portion
330: Air nozzle float 332: Second chamber
340: second gasket 341: second cut groove
342: second opening 343: second inclined portion
150: Air supply line
210: spray nozzle 220: handle

Claims (5)

In the straight line-enhancing air film forming device mounted on the spray nozzle that sprays paint,
A nozzle block surrounding the spray nozzle;
Nozzle arms extending to both sides of the nozzle block and bent forward;
a nozzle joint means sliding in a longitudinal direction in front of the nozzle arm; and
It includes a side air nozzle connected to the nozzle joint means and having second slits formed on both sides of the first slit,
The side air nozzle is,
It includes a pair of air nozzle bodies having a flat plate shape and a through hole, and a first gasket having a fan-shaped first cut groove formed between the air nozzle bodies, so that air supplied through the through hole is connected to the first cut groove. is sprayed through the formed first slit,
A flat air nozzle body is added to both sides of the air nozzle body, and a second gasket is formed with a second fan-shaped cut groove between the air nozzle body and the air nozzle body, so that the air supplied through the hole is supplied to the second gasket. It is sprayed through the second slit formed in the incision groove,
The air simultaneously sprayed from the side air nozzle passes through the spray nozzle to form a vertically long side air film on the left and right sides of the sprayed paint application surface, and a closed curved surface is formed by the force of pulling the side air film up and down.
Air film forming device that enhances straightness. According to claim 1,
The side air nozzle includes a first side air nozzle connected to be spaced apart in front of one side of the nozzle block, and a second side air nozzle connected to be spaced apart in front of the other side of the nozzle block,
The paint sprayed from the spray nozzle is sprayed by air sprayed from the first and second slits of the first side air nozzle on one side, and air sprayed from the first and second slits of the second side air nozzle on the other side. An air membrane forming device that enhances straightness, in which the side air membrane is formed vertically to the left and right, forming an oval shape where the upper and lower sides are connected. In clause 2
The first slit of the first side air nozzle and the first slit of the second side air nozzle are left and right symmetrical, and the inner surface is concave to the outside,
Air film forming device that enhances straightness. According to claim 1,
A first chamber is formed in the air nozzle body in which the through hole is formed to temporarily accommodate the air supplied through the through hole and spray the air through the first slit,
A second chamber is formed in the air nozzle body in communication with the through hole to temporarily accommodate the air supplied through the through hole and allow it to be sprayed through the second slit.
Air film forming device that enhances straightness. An anti-scattering spray gun comprising the straight-line enhancement air film forming device of any one of claims 1 to 4.