JPH07213954A - Method and apparatus for preventing stain of deflecting and distributing nozzle device - Google Patents

Abstract

PURPOSE:To provide a stain-preventing method and apparatus by which a rebounding coating agent is prevented from adhering to a nozzle hole part of a deflecting and distributing nozzle device. CONSTITUTION:A masking guide apparatus 29 which composes a chamber 30 for positive pressure gases and has a coating agent-passing hole small enough not to prevent a coating agent from being deflected and sprayed is installed in front of a deflecting and distributing nozzle device 21, a positive pressure gas is introduced into the chamber for positive pressure gases, and while the chamber for positive pressure gases being kept at slightly higher gas pressure than the outside of the chamber for positive pressure gases, a coating agent is sprayed out of the deflecting and distributing nozzle device to coat an article to be coated.

Description

Detailed Description of the Invention

[0001]

[Field of Industrial Application] Japanese Patent Application Laid-Open No. 3-238061
For the outflow of liquid or melt flowing out of the nozzle hole,
Pressure gas jets for distribution are jetted independently from a plurality of gas jet holes provided around the nozzle hole, and the jetted jets of the pressure gas are struck against the outflow stream of the liquid or melt to thereby discharge the liquid or melt. The technique of deflecting and dispensing coating in which the jet direction of the outflow is deflected and a desired composite pattern is obtained by combining the plurality of deflected patterns is described in detail. The present invention relates to an improvement in such a deflecting dispensing coating technique, and more particularly to a method and an apparatus for preventing contamination of a deflecting dispensing nozzle device used in deflecting coating an outflow of a liquid or a melt. is there.

[0002]

2. Description of the Related Art As described above, with respect to an outflow of a liquid or a melt that flows out of a nozzle hole, a plurality of gas injection holes provided around the nozzle hole are used to independently generate a pressure gas injection flow for distribution. Of the liquid or the melt, thereby deflecting the jetting direction of the outflow of the liquid or melt, and by combining the deflected patterns, a desired composite is obtained. Japanese Patent Application Laid-Open No. 3-2 for a technique relating to deflective distribution coating for obtaining a pattern.
No. 3,8061, which is described in detail.

Further, regarding a technique for preventing the nozzle from being contaminated by a part of the paint or coating agent that rebounds from the object to be coated when the paint or coating agent ejected from the nozzle is applied to the object to be coated. , Japanese public Sho 62-4
No. 2668, "Method and apparatus for cleaning spray nozzle for painting" and the like are known.

[0004]

The above-mentioned conventional techniques have the following problems. That is, JP-A-3
In the technique disclosed in Japanese Patent No. 238061, the amount of the reflection flow from the object to be coated, so-called rebound paint or coating agent, etc. is reduced as compared with the continuous spray coating which is generally and conventionally used in the art. However, it is difficult to eliminate these rebound amounts at all.

In particular, in the case of coating the inner surface of a bottomed can, so-called a two-piece can, a rebound is made as compared with the conventional coating method using a nozzle such as Japanese Patent Publication No. 54-6256. Although the amount of coating agent to be applied was reduced, it was unavoidable that the deflection dispensing nozzle was contaminated by the coating agent due to the effect of the rebounding coating agent.

That is, in the technique disclosed in JP-A-3-238061, when coating the inner surface of a can called a two-piece can, the rebound paint or coating agent causes a nozzle hole or a nozzle hole for ejecting the coating agent. It adheres to the vicinity of the gas ejection holes of the airless spray nozzle or the distribution gas ejection holes, which causes viscosity changes over time and solidifies and accumulates, which prevents stable application of coating agents over a long period of time. It was

Further, a technique known from Japanese Patent Publication No. 62-42668 is to spray a solvent from a separately provided solvent spray nozzle on the outer peripheral surface of a spray nozzle for coating so that the outer peripheral surface of the spray nozzle for coating is always wet. At the same time, the paint residue attached on the nozzle is washed away. However, such a technique is directly applied to the above-mentioned JP-A-3-2380.
In order to apply to the technique of deflecting and distributing coating agent as shown in No. 61, a large number of ejection holes such as a nozzle hole for ejecting a coating agent, a gas ejection hole of an airless spray nozzle, or a distribution gas ejection hole are provided. Since the holes are provided, it is impossible to clean a large number of ejection holes with one solvent spray nozzle, and it is structurally difficult to provide a plurality of solvent spray nozzles corresponding to the plurality of ejection holes. It was very difficult.

The present invention has been made in view of the above problems, and a first object of the present invention is to prevent the rebound coating agent from adhering to the nozzle holes of the deflecting distribution nozzle device. SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and an apparatus for preventing stains on a deflection distribution nozzle device.

A second object of the present invention is to rebound to a masking guide device provided to prevent the rebound coating agent or the like from adhering to and contaminating the nozzle holes of the deflecting distribution nozzle device. It is an object of the present invention to provide a method and an apparatus for preventing the deflection distribution nozzle device from being contaminated, which is capable of removing the coating agent that adheres.

Further, a third object of the present invention is to provide a deflecting distribution nozzle for removing a coating agent which rebounds and adheres to the masking guide device and which prevents the cleaning liquid from scattering and contaminating the surrounding environment. It is an object of the present invention to provide an antifouling device.

[0011]

The method of the present invention has the following constitution in order to achieve the above object. That is, as a method for achieving the first object, a coating agent passage hole is provided on the front surface of the deflection distribution nozzle device to such an extent that the deflection ejection of the coating agent ejected from the deflection distribution nozzle device is not hindered, and the positive pressure gas is supplied. The masking guide device that configures the positive pressure gas chamber is provided, and the positive pressure gas is introduced into the positive pressure gas chamber, and the inside of the positive pressure gas chamber is maintained at a slightly higher gas pressure than the outside of the positive pressure gas chamber. At the same time, the coating agent is ejected from the deflection distribution nozzle device to be applied to the object to be coated, which is a method for preventing the deflection distribution nozzle device from becoming dirty.

Further, as a method for achieving the second object, in addition to the above-mentioned method for preventing the stain of the deflection distribution nozzle device, the masking guide device is configured to be rotatable, and the coating is performed while rotating it by the rotating means. The agent was jetted from the deflecting distribution nozzle device and applied to the object to be coated.

Further, in addition to the above-mentioned method, a method of spraying a cleaning liquid on the outer surface of the masking plate constituting the masking guide device for cleaning is adopted.

As a device for achieving the first object, the deflection and ejection of the coating agent ejected from the deflection and distribution nozzle device is not obstructed on the front surface of the deflection and distribution nozzle device attached to the tip of the spray gun. A positive pressure gas introducing hole which has a coating agent passage hole and which is rotatably provided in the positive pressure gas chamber and which communicates with the positive pressure gas chamber. Is provided to prevent the deflection and distribution nozzle device from becoming dirty.

Further, as a device for achieving the second object, there is provided a device for preventing contamination of a deflection distribution nozzle, wherein the masking guide device is rotated by a rotating means.

Furthermore, toward the outer surface of the masking plate constituting the masking guide device described above,
The stain preventing device for the deflecting distribution nozzle is provided with a cleaning liquid ejecting nozzle for ejecting the cleaning liquid for cleaning the surface of the masking plate.

Further, as a device for achieving the third object, the above-mentioned cover for catching the coating agent and / or the cleaning liquid scattered from the masking plate is provided, and the deflection distribution nozzle is contaminated. As a preventive device.

[0018]

Next, the operation of the present invention will be described. In the present invention, since the method and apparatus for preventing the contamination of the deflection distribution nozzle having the above-described configuration are used, the coating agent rebound from the object to be coated is stored in the positive pressure gas chamber provided on the front surface of the deflection distribution nozzle apparatus. Is maintained at a higher pressure than the outside of the positive pressure gas chamber, so that it does not invade into the positive pressure gas chamber, and is therefore prevented from adhering to the nozzle holes or front surface of the deflection distribution nozzle device.

However, a part of the rebound coating agent may adhere to the front surface of the masking guide device, that is, the outer surface of the masking plate constituting the masking guide device. In order to prevent this, the masking guide device is rotated, and the centrifugal force causes the coating agent that is trying to adhere to the outer surface of the masking plate to be shaken off, so that the coating agent adheres and accumulates on the outer surface of the masking plate. To be prevented.

Depending on the properties of the coating agent, some of them tend to adhere, and when such a coating agent is used, the cleaning liquid is ejected from a cleaning liquid ejection nozzle provided toward the outer surface of the masking plate. Then, the attached coating agent and the cleaning liquid are shaken together by the centrifugal force, so that the outer surface of the masking guide plate is always kept clean.

Further, due to the centrifugal force of rotation of the masking guide device, the coating agent or the cleaning liquid that is shaken off may become a mist and float in the air, thus contaminating the environment around the device or surrounding equipment. If such contamination is disliked, it is prevented by providing a cover on the outer periphery of the masking guide device and capturing mist scattered from the masking plate.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A method and an apparatus for preventing stains on a deflecting and distributing nozzle device according to the present invention will be described in detail below with reference to explanatory views showing its embodiments. The present embodiment shows a two-fluid spray system. FIG. 1 is a diagram showing an overall configuration of a stain preventing device for a deflecting distribution nozzle device according to the present invention.
FIG. 3 is an enlarged view of a main part of FIG. 1, and FIG. 3 is a view showing a positional relationship of various ejection holes provided in the deflection nozzle body.

In the figure, a fluid spray gun 1 for spraying a coating agent is fixed to a mount 2 with bolts 3. A fluid supply port 4 for introducing a coating agent to the fluid ejection gun 1,
An operation air supply port 6 for opening and closing the needle valve 5 is provided, and a pipe joint 7 and a hose 8 are connected to the operation air supply port 6.

Further, the male thread portion 9 provided at the tip of the fluid ejection gun 1 is provided with a collar portion 12 of the coating agent ejection nozzle 11.
The deflection nozzle body 10 is screwed with the pinch clamped. The deflection nozzle body 10 is provided with an atomization gas introduction hole 13 and an atomization gas ejection hole 14 which communicates with the atomization gas introduction hole 13 so as to surround the coating agent ejection nozzle 11 and eject the deflection distribution gas. A plurality of distribution gas ejection holes 15 are provided,
Further, a plurality of positive pressure gas introduction holes 16 are provided. A hose 18 is connected to the distribution gas ejection hole 15 through a pipe joint 17.
However, hoses 20 are connected to the positive pressure gas introduction holes 16 via pipe joints 19, respectively. The coating agent ejection nozzle 11, the deflection nozzle body 10 and the like constitute a deflection distribution nozzle device 21.

On the outer periphery of the deflection nozzle body 10, a rotary wheel 22 having a spacer 24 fixed by a plurality of bolts 23 is rotatably mounted via a bearing 25. A gear for transmitting the rotational force is formed on the outer circumference of the rotary wheel 22. Further, a disk-shaped masking plate 26 provided with a coating agent passage hole 27 at the center of the spacer 24, the coating agent passage hole 27 having a size not obstructing the ejection of the coating agent ejected from the deflecting distribution nozzle device 21, is attached by a screw 28. .
The outer diameter of the disk-shaped masking plate 26 is the spacer 2.
It is slightly larger than the outer diameter of 4. The rotating wheel 22, the spacer 24, the masking plate 26 and the like constitute a masking guide device 29.

A positive pressure gas chamber 30 is formed between the deflection distribution nozzle device 21 and the masking guide device 29, and the positive pressure gas chamber 30 is provided with a plurality of positive pressure gas introductions provided in the deflection nozzle body 10. It communicates with the hole 16.

A motor 31 is provided on the pedestal 2 via a bracket 32 for position adjustment.
The output shaft of the rotary wheel 2 meshes with the gear of the rotary wheel 22.
A gear 33 for transmitting the rotational force is attached to 2.

Further, two cleaning liquid ejection nozzles 34 for ejecting the cleaning liquid toward the outer surface of the masking plate 26 constituting the masking guide device 29 are provided. The cleaning liquid jet nozzle 34 is connected to a cleaning liquid supply device (not shown) by a hose.

A cover 35 for capturing the coating agent and / or the cleaning liquid scattered from the masking plate 26 is provided around the masking guide device 29.
Is provided. The cover 35 has an exhaust port 36 for discharging the captured coating agent and / or volatile components in the cleaning liquid to the outside of the system through a duct or the like, and a liquid outlet 37 for discharging the liquid component to the outside of the system. It is provided. Further, the two-piece can 38, which is the object to be coated tested in this example, is indicated by a two-dot chain line to show the positional relationship.

Next, the operation of this embodiment will be described. The coating agent is supplied from the fluid supply port 4 to the fluid ejection gun 1 and the gas introduction hole 1 provided in the deflection nozzle body 10 is provided.
When the needle valve 5 is opened by the operation of the operation air supplied from the operation air supply port 6 to the fluid ejection gun 1 by supplying the atomization gas from the atomization gas 3
The gas for atomization ejected from No. 4 is ejected from the tip of the coating agent ejection nozzle 11 and atomized together with the atomizing gas.

When the deflected distribution gas, which is independently controlled, is ejected from the distribution gas ejection holes 15 and hits the coating agent ejection flow, the traveling direction of the coating agent ejection flow is deflected and The deflection distribution gas flow merges to form a deflection pattern, which is applied to the inner surface of the object to be coated, in this embodiment, the two-piece can 38. However, in the case of the two-piece can 38, since there is less air escape because of the shape compared to a flat plate, a part of the coating agent that did not adhere, together with the air jetted with the coating agent
It will rebound from the inside of the two-piece can 38 toward the deflecting nozzle body 10.

At this time, the positive pressure gas is introduced into the positive pressure gas chamber 30 formed between the deflection distribution nozzle device 21 and the masking guide device 29 from the positive pressure gas introduction hole 16 provided in the deflection nozzle body 10. By introducing and maintaining the inside of the positive pressure gas chamber 30 to have a slightly higher gas pressure than the outside of the positive pressure gas chamber 30,
Since the rebound flow cannot enter the inside through the coating agent passage hole 27 of the masking plate 26, it is prevented from adhering to the deflection nozzle body 10.

However, the slight rebounding coating agent does not enter the inside of the masking plate 26, but tends to adhere to the outer surface of the masking plate 26. This prevention is solved by rotating the masking guide device 29 with the motor 31 and the gear 33. That is, the rotating wheel 22 meshed with the gear 33 by the motor 31 attached to the gantry 2 and the gear 33 attached to the output shaft of the motor 31 via the bracket 32 for position adjustment.
By rotating the masking guide device 29
Is rotated, whereby the masking plate 26 is also rotated, and the slight amount of coating agent that adheres to the surface of the masking plate 26 is scattered around by the centrifugal force and does not adhere.

Further, in the case of handling a coating agent having a particularly easy-to-adhere characteristic such that the adhesion cannot be prevented only by the centrifugal force due to the rotation of the masking plate 26, it is provided toward the outer surface of the masking plate 26. The cleaning liquid is sprayed from the cleaning liquid jet nozzle 34 to the masking plate 2
Adhesion can be prevented by jetting it to the outer surface of 6 and washing it away with the washing liquid by centrifugal force.

In this embodiment, two cleaning liquid jet nozzles 34 are provided, but the number is not limited to two. The reason for providing two cleaning liquid ejecting nozzles 34 is that when a small amount of cleaning liquid is ejected to the tip portion of the coating agent passage hole 27 of the masking plate 26, that is the masking plate 26.
Due to the centrifugal force, the film is gradually thinned and flows in the outer peripheral direction, and the film is broken in the middle to cause insufficient cleaning ability. Therefore, the second cleaning liquid ejection nozzle 34 is provided in the radial intermediate portion of the masking plate 26. , To supplement the cleaning ability.

Further, by making the outer diameter of the masking plate 26 slightly larger than the outer diameter of the spacer 24, it is possible to prevent the cleaning liquid and the like from flowing around to the spacer 24 and the rotary wheel 22.

The outer surface of the masking plate 26 is preferably coated with a fluororesin having excellent water repellency or a mirror finish so that the coating agent does not easily adhere thereto.

The cover 35 provided on the outer periphery of the masking guide device 29 captures the coating agent or the like scattered from the masking plate 26, and the volatile components contained in the coating agent or the like are discharged from the exhaust port 36 through a duct or the like. Is discharged to the outside of the system, and the liquid component is discharged to the outside of the system from the liquid discharge port 37, so that it does not pollute the surrounding environment.

Experiments were conducted under the following conditions using the apparatus of this example. 1: The object to be coated is a two-piece can, and the feed rate is 120-per minute
400 cans 2: the number of rotations of the masking guide device is 300 to 150
0 rpm 3: The pressure of the positive pressure air is 1.0 to 3.0 kg / cm ² 4: The pressure of the atomizing air is 1.0 to 2.5 kg / cm ² 5: The pressure of the deflecting distribution air is 1. 0-3.0kg / cm
² 6: where the cleaning liquid, which after the coating agent is applied to the inner surface of the continuous 54,000 cans in intermittently applied above conditions trace to the extent that the surface of the masking plate is wet at all times, to inspect the device, the deflection No adhesion of the coating agent or the like was found on the distribution nozzle device or the masking guide device. Further, the coating film thickness on the inner surface of the two-piece cans was extremely good because a uniform film thickness was obtained in all the cans. Very good results were also obtained in the ERV coating test method commonly used in the art.

In this embodiment, the two-fluid spray type is shown, but the airless spray type has the same effect. The masking guide device is rotated by a method of transmitting a rotational force by a gear, but the method is not limited to this, and a belt or chain system may be used.

[0041]

As described above, the method and apparatus for preventing the stain on the deflection distribution nozzle device according to the present invention has the above-described structure. Therefore, it is possible to completely prevent the rebound coating agent from adhering and depositing on the nozzle holes of the deflection distribution nozzle device. It is possible to prevent this and apply the coating agent stably over a long period of time. Further, no coating agent is attached to the masking guide device and the environment around the device is not polluted.

[Brief description of drawings]

FIG. 1 is a diagram showing an entire configuration of a stain prevention device for a deflecting distribution nozzle device according to the present invention.

FIG. 2 is an enlarged view of a main part of FIG.

FIG. 3 is a diagram showing a positional relationship of various ejection holes provided in a deflection nozzle body.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Fluid ejection gun 10 ... Deflection nozzle body 21 ... Deflection distribution nozzle device 26 ... Masking plate 29 ... Masking guide device 30 ... Positive pressure gas chamber 31 ... Motor 34 ... Cleaning liquid ejection nozzle 35 ... Cover

Claims (7)

[Claims] 1. A masking guide device for forming a positive pressure gas chamber, which has a coating agent passage hole on the front surface of the deflecting and distributing nozzle device, the coating agent passing hole having an extent that does not prevent the deflecting and ejecting of the coating agent ejected from the deflecting and distributing nozzle device. Provided,
The positive pressure gas is introduced into the positive pressure gas chamber to maintain the inside of the positive pressure gas chamber at a slightly higher gas pressure than the outside of the positive pressure gas chamber, and to apply the coating agent from the deflection distribution nozzle device. A method for preventing contamination of a deflecting and distributing nozzle device, which is sprayed and applied to an object to be coated. 2. The masking guide device is configured to be rotatable, and while being rotated by a rotating means, the coating agent is jetted from a deflecting distribution nozzle device to be applied to an object to be coated. A method for preventing the deflection distribution nozzle from being soiled. 3. A masking guide device constituting a masking guide device is sprayed with a cleaning liquid onto the outer surface thereof to clean the outer surface of the masking plate.
A method for preventing the deflection and distribution nozzles from becoming dirty. 4. A positive pressure gas having a coating agent passage hole on the front surface of a deflection distribution nozzle device attached to the tip of a spray gun to the extent that it does not hinder the deflection ejection of the coating agent ejected from the deflection distribution nozzle device. A masking guide device forming a chamber is rotatably provided, and a positive pressure gas introduction hole communicating with the positive pressure gas chamber is provided in the positive pressure gas chamber. Stain prevention device for nozzle device. 5. The stain prevention device for a deflection distribution nozzle according to claim 4, wherein the masking guide device is rotated by a rotating means. 6. The deflection according to claim 5, further comprising a cleaning liquid ejection nozzle for ejecting a cleaning liquid for cleaning the surface of the masking plate toward the outer surface of the masking plate constituting the masking guide device. Anti-dirt device for distribution nozzle. 7. The anti-fouling device for a deflection distribution nozzle according to claim 5, further comprising a cover for capturing the coating agent and / or the cleaning liquid scattered from the masking plate.