JP2000167446A - Coating head - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coating head capable of forming the coating head having many nozzles without using a special gun in air spray coating, freely designing the number of the nozzles or the nozzle pitch, adjusting the spray pattern width fixed by the coating distance or the discharged quantity of the coating material to the optimum overlap coating pitch and securing high coating efficiency. SOLUTION: The coating head is constituted of a 1st narrow pipe group arranged at an equal interval, a 1st manifold communicated with each narrow pipe and for uniformly supplying the coating material, a 2nd narrow pipe group arranged at the equal interval similar to the 1st narrow pipe group and having a diameter larger than that of the 1st narrow pipe group and a 2nd manifold communicated with each narrow pipe and connected to the 1st manifold. In such a case, the 1st narrow pipe is positioned inside of the 2nd narrow pipe, the double cylindrical nozzle is formed from each narrow pipe of the 1st narrow pipe group 1 and the 2nd narrow pipe group 3 and the coating material discharged from the 1st narrow pipe group 1 is atomized with the compressed air discharged from the 2nd narrow pipe group.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coating head for forming an atomizing nozzle for spray-coating paint.

[0002]

2. Description of the Related Art Conventionally, spray coating is performed by spraying a spray gun so as to have a constant film thickness while applying a spray pattern in a circular (round) or elliptical (flat) spray pattern. Drive. In order to paint a wide area efficiently with one spray gun, it is necessary to increase the spray pattern width as much as possible and apply the paint with a small number of coatings.

[0003] In general, the spraying efficiency of spray coating is very low as compared with brush or roller coating, and is usually about 50 to 60%. In the case of spray coating such as air spray or airless spray, compared to the center of the spray pattern,
The coating efficiency tends to decrease as it approaches the end of the pattern. This is because the atomized air flow and the accompanying air flow act as a carrier air flow that collides with the object and carries away the atomized particles, so that the atomized particles at the end of the pattern are closer to the object. Since the inertia force is low, it is easily affected by the carrier air flow. For this reason, increasing the pattern width has been a factor that causes a decrease in coating efficiency.

[0004] In order to improve the coating efficiency, a spray is used.
It is necessary to reduce the pattern as much as possible to increase the inertial force of the atomized paint particles in the direction of the object to be coated, and it is effective to spray the paint particles at a short distance as one means. That is, spray
By spraying while moving the gun at a coating distance of several centimeters, it is possible to cause the atomized paint particles to collide with the object to be coated at a high coating speed. As a result, the coating efficiency becomes 90%. % Or more can be secured. However, in this case, the spray pattern opening angle must be at most about 30 degrees.

However, when the spray distance is reduced as described above, the spray pattern width becomes extremely small, and as a result, the wet coating film sprayed by one spray gun moving operation becomes too thick. This causes paint film defects such as sagging and Nagare.

In order to appropriately reduce the thickness of a wet coating film sprayed by a single spray gun moving operation, it is necessary to reduce the discharge rate. Must be used together.

In a normal spray gun, the outer diameter of the body is several times as large as the outer diameter of the nozzle portion for atomization. The maximum pitch is about 2 cm. In general, it is known that in order to obtain a uniform film thickness distribution, the coating pitch of the spray pattern is set to 1/2 or less of the effective spray pattern width. Therefore, the pitch between nozzles is 2c
m indicates that if the effective spray pattern width is 4 cm or less, the film thickness distribution may be non-uniform.

[0008] The coating distance of close-range coating in which a coating efficiency of 90% or more can be expected is within about 5 cm. If an effective spray pattern width of 4 cm or more is to be secured at this distance,
The spray pattern opening angle must be about 90 degrees or more, which is difficult to achieve with a conventional spray gun or spray nozzle. Even if the pattern is forcibly expanded, it is difficult to secure a coating efficiency of 90% due to the influence of the flow of the conveying air.

An object of the present invention is to prepare a coating head having a large number of nozzles without using a special gun in air spray coating, to freely design the number of nozzles and the nozzle pitch, and to control the coating distance and the like. An object of the present invention is to provide a coating head which can adjust a spray pattern width determined by a paint discharge amount to an optimum coating pitch and ensure high coating efficiency.

[0010]

That is, the present invention provides a first group of thin tubes arranged at equal intervals, a first manifold which communicates with each of the thin tubes and supplies paint uniformly, and A second group of small tubes arranged at the same interval as the group of small tubes and having a larger diameter than the first small tube, and a second group formed in communication with each of the small tubes and connected to the first manifold. A first thin tube located inside the second thin tube and forming a double cylindrical nozzle with each of the first thin tube group and the second thin tube group; Paint atomized by compressed air discharged from a second group of thin tubes.

[0011]

DETAILED DESCRIPTION OF THE INVENTION In the present invention, a concentric double tube formed by a first group of thin tubes and a second group of thin tubes is a coating having a large number of nozzles each acting as one atomizing nozzle. A head is provided. The mounting pitch of each atomizing nozzle can be freely designed as long as it is equal to or larger than the outer diameter of the second thin tube group.

The first group of thin tubes discharges paint, and the supply of paint to the group of thin tubes is performed by a first manifold that communicates with the first group of thin tubes.
Since the paint is evenly distributed between the nozzles, ON / OFF of the paint discharge of each atomizing nozzle can be performed by turning ON / OFF the paint supply path to the first manifold. Further, the second group of small tubes discharges atomized air, and the supply of atomized air to the group of small tubes is also equally distributed by the communicating second manifold as described above. ON / OFF of the atomizing air discharge of each atomizing nozzle can be performed by turning ON / OFF the atomizing air supply path to the second manifold. In the coating head of the present invention, the first manifold and the second manifold are connected, and each manifold is connected.
When the atomizing nozzle is formed by combining the capillary groups communicating with the nozzle, the space formed by the first capillary group and the second capillary group incorporates a spiral molded wire into the space. −
Can be Thereby, the first thin tube group and the second thin tube group can form accurate concentric double cylindrical nozzles.

In this case, the spirally formed wire is
The nozzle is set in the atomizing air path of the concentric double cylindrical nozzle, and the atomizing air is discharged from the nozzle in a spiral shape according to the spiral shape of the wire. A good spray pattern can be formed.

According to the present invention, a third group of thin tubes arranged at the same interval as the first and second group of thin tubes and having a diameter larger than that of the first and second thin tubes, and communicating with each of the thin tubes. Alternatively, it is also possible to combine a third manifold formed in connection with the first and second manifolds. In that case, if two colors of paint are supplied from the first and second manifolds and atomized air is supplied from the third manifold, color mixing at a short distance and high coating efficiency can be realized. Atomization coating becomes possible.

[0015]

1 is an explanatory view showing one embodiment of a coating head according to the present invention, and FIG. 2 is an enlarged sectional view of the coating head shown in the embodiment.

FIG. 1 shows (a) a sectional view of a coating head and (b) a front view of the coating head. First, the inner diameter is 1m
A first group of small tubes 1 having a diameter of 2 mm, an outer diameter of 2 mm, and a tube length of 50 mm was brazed to the first manifold 2 at intervals of 10 mm to communicate the inside of the manifold 2 with each of the small tubes 1. Next, a second group of small tubes 3 having an inner diameter of 3 mm, an outer diameter of 4 mm, and a tube length of 30 mm is brazed to the second manifold 4 at intervals of 10 mm, and the inside of the manifold 4 and each of the small tubes 3 are connected. Communicated. The coating head 5 has an area of about 42 cm ² (vertical 6 cm,
A total of 23 double-cylindrical nozzles composed of the first thin tube group 1 and the second thin tube group 3 were arranged in a zigzag pattern at a width of 7 cm). The inner volumes of the manifolds 2 and 4 are designed to secure about 200 cc in consideration of discharge stability.

Further, as shown in FIG. 2, a stainless steel wire 6 having a thickness of 1 mm is spirally wound around the outer periphery of the first thin tube group 1 and molded to form a concentric double cylinder with the second thin tube group 3. It was brazed and fixed to a portion (30 mm from the tip).

The first manifold 2 is connected to a pressurized tank (both not shown) through a paint valve of an air operation type.
It is pressurized to a constant pressure by a regulator (not shown) and fed to the first manifold 2 by pressure.

The second manifold 4 is connected to the first manifold 2 to form a closed space, and is provided with an air operation valve which is turned on / off by pilot air and a regulation. It is connected to an atomizing air supply via a heater (neither is shown).

Here, the paint (“Amirac # 1000 White”, manufactured by Kansai Paint Co., Ltd.) was diluted to a viscosity of 20 seconds (Ford Cup # 4), and the pressure of the pressurized tank was reduced to 1.5 k.
g / cm ² . In the steady state, the discharge amount from the first capillary group 1 communicating with the first manifold 2 is about 2
At 0 cc / min, the variation in the discharge amount between the nozzles is ± 1
It was stable within%. Compressed air adjusted to 3 kg / cm ² was supplied to the second manifold 4 by a regulator and discharged from each nozzle as atomizing air. Further, the main coating head 5 was attached to a coating robot, and the flat coated object was coated at an operation speed of 0.5 m / sec.

As a result, at a spray distance (distance from the nozzle to the object to be coated) of 5 cm, the average particle size of the atomized paint particles generated by each nozzle is about 25 microns (with a particle sizer manufactured by Malvern Co., Ltd.). The effective spray pattern width (the length between the film thicknesses that gives a half of the maximum film thickness) is about 2.5 cm, and the film thickness distribution due to the overlap of the spray patterns of the nozzles is measured. A good film thickness distribution with a variation within 0.5% was obtained. The coating efficiency was about 95%.

[0022]

According to the present invention, a two-fluid nozzle (air spray nozzle) can be easily formed without using a special spray gun, so that a coating head having a large number of nozzles can be manufactured at low cost. can do.

Further, since the nozzle pitch and the number of nozzles can be freely designed, not only can the spray pattern width determined by the coating distance and the amount of paint discharged be adjusted to the optimum coating pitch, but also By providing a separate stop valve for each nozzle, the discharge of each nozzle can be turned on.
/ OFF, so that the size of the entire pattern formed by all the nozzles can be controlled.

Therefore, the effective spray pattern at each coating distance
Spray-coating with high coating efficiency while keeping the width of the coating possible.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing one embodiment of a coating head of the present invention.

FIG. 2 is an enlarged cross-sectional view of a coating head shown in an embodiment of the present invention.

[Description of Signs] 1 First thin tube group 2 First manifold 3 Second thin tube group 4 Second manifold 5 Painting head 6 Spiral stainless wire 7 Spray pattern

Claims (2)

[Claims] 1. A first group of small tubes arranged at equal intervals, a first manifold communicating with each of the small tubes and supplying paint uniformly, and a first group of small tubes arranged at the same intervals as the first group of small tubes. A second capillary group having a diameter larger than that of the first capillary, and a second manifold formed in communication with each capillary and connected to the first manifold. One thin tube is located inside the second thin tube and forms a double-cylindrical nozzle with each of the first thin tube group and the second thin tube group, and paints discharged from the first thin tube group are formed. A coating head for atomizing with compressed air discharged from a second group of thin tubes. 2. A first thin tube group and a second thin tube group are wound around an outer periphery of each first thin tube in a helical manner and are used as spacers so as to be in contact with the inner surface of each second thin tube. 2. The coating head according to claim 1, wherein said group of thin tubes are combined in a concentric cylindrical shape.