Rotary atomizer for particulate paints

Abstract

A rotary atomizer applies particulate paints with good color matching by reducing paint droplet size deviation and then optimizing the other paint spraying parameters. Paint droplet size parameters are reduced by using a bell cup having reduced flow deviations, including an overflow surface having a generally constant angle between a deflector and an atomizing edge.

Description

BACKGROUND OF THE INVENTION

The present invention relates generally to rotary atomizers and more particularly to a rotary atomizer having improved performance for particulate paints.

Currently, many paints are applied by rotary atomizers to work pieces, such as automobile bodies. Rotary atomizers include a rotating bell cup having a generally conical overflow surface between a radially inward central axial opening and a radially outward atomizing edge. At or near the atomizing edge, the angle of the overflow surface relative to the axis of the bell cup decreases sharply to form a lip adjacent the atomizing edge. The purpose of this lip is to generally direct the atomized paint more axially forward and reduce radial scatter. The known atomizer bell cups further include a deflector, also of generally rotational symmetry, disposed in front of the central axial opening. Paint entering the bell cup through the central axial opening contacts the rear surface of the deflector and is disbursed radially outwardly towards the overflow surface.

In the known atomizer bell cups, the paint follows a tortuous, turbulent path from the nozzle to the atomizing edge. As a result, the paint flow to the atomizing edge is turbulent and fluctuates cyclically. As a result, paint from the atomizer is atomized to a wide variety of paint droplet sizes. The paint droplets can vary by up to 100 microns or more.

Current rotary atomizers are unable to obtain good color matching applying paints with particulates, such as mica. Generally, the mica comprise particles on the order of 3 microns by 200 microns. When this paint is applied by rotary atomizers, the mica particles are oriented generally perpendicular to the application surface. As a result, the paint has a different tint or color than intended, i.e. with the mica particles laying flat. In order to correct this problem, a second coat of the paint is typically applied with air atomized spray guns rather than rotary atomizers. This second coat provides the proper color; however, air atomized spray guns have a low transfer efficiency (approximately 50%) compared to rotary atomizers (approximately 80%). The air atomized spray guns therefore increase the amount of paint lost, increasing the cost of the paint process and cause environmental concerns regarding the disposal of the lost paint.

SUMMARY OF THE INVENTION

The present invention provides a rotary atomizer which provides improved color matching. Generally, the improved atomizer provides a more uniformed paint droplet size, which in turn facilitates control of the particulates in order to assure proper orientation of the particulates and obtain good color matching.

The rotary atomizer bell cup according to the present invention provides several inventive features directed toward reducing deviation in paint droplet size. First, the bell cup includes a generally conical overflow surface having a generally constant flow angle between a deflector and the atomizing edge. Further, the exposed surface area of the overflow surface is increased by decreasing the size of the deflector relative to previous bell cups in order to cause evaporation of solvent from the paint from the overflow surface. The diameter of the atomizing edge is also increased, thereby reducing the thickness of the paint film at the atomizing edge. The bell cup is designed to reduce flow deviations of the paint as it travels from the axial opening to the spray edge in order to provide laminar flow of the paint across the overflow surface and the atomizing edge.

The bell cup is made hollow in order to reduce the weight of the bell cup. A rear cover is secured to the rear of the bell cup body, enclosing an annular cavity.

BRIEF DESCRIPTION OF THE DRAWINGS

The above, as well as other advantages of the present invention, will become readily apparent to those skilled in the art from the following detailed description of a preferred embodiment when considered in the light of the accompanying scale drawings in which:

FIG. 1 is a scale drawing of the atomizer of the present invention;

FIG. 2 is a scale drawing in cross section of the atomizer of FIG. 1;

FIG. 3 is a scale drawing front view of the bell cup of FIG. 2;

FIG. 4 is a scale enlarged view of the deflector of FIG. 2;

FIG. 5 is a scale cross-sectional view of an alternate bell cup;

FIG. 6 is an enlarged scale view of the deflector in the bell cup of FIG. 5;

FIG. 7 is a scale bottom view of the bell cup of FIG. 5; and

FIG. 8 illustrates one possible layout for applying a base coat with the atomizer of FIG. 1 and the bell cup of FIG. 2 or 5.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 illustrates a rotary atomizer 20 and a bell cup 22 according to the present invention. The atomizer includes a shaping air ring 23 which preferably includes 30 nozzles generally parallel to the axis of the atomizer. The shaping air ring 23 supplies shaping air, preferably at 100 liters per minute. With the reduced number of holes from the known shaping air ring (typically 40), this produces increased turbulence by the shaping air.

The bell cup 22 is shown in more detail in FIGS. 2-3. Bell cup 22 includes a central axial opening 24 at the base of the bell cup 22. The central axial opening 24 includes a coaxial passageway onto a front surface 26 of the bell cup 24. The front surface 26 of the bell cup 22 includes a central flat portion 28 generally perpendicular to the axis of the bell cup 22 and a generally conical overflow surface 30 from the perpendicular portion 28 to a spray edge 32. Between the perpendicular surface 28 and the spray edge 32, the overflow surface 30 has a smooth continuous surface of a constant flow angle α relative to the annular spray edge 32, preferably 5-40 degrees, more preferably 26-30 degrees and most preferably 28.25 degrees. The diameter of the annular spray edge 32 is preferably 63-75 mm, and most preferably 64.6 millimeters.

An annular hub 33 extends rearwardly from the bell cup 22 and includes an externally threaded portion 34. A frustoconical rear cover 35 is threaded onto the threaded portion 34 of the annular hub 33 and welded or glued to the rear of the bell cup 22 behind the spray edge 32. As a result, the body of the bell cup 22 behind the overflow surface 26 is hollow, reducing the weight of the bell cup 22. A concentric inner hub 36 extends rearwardly from the bell cup 22 and is externally threaded for mounting to the atomizer 20. Other means for attaching the bell cup 22 to the atomizer 20 can also be utilized. The spray edge 32 forms a sharp edge between the overflow surface 30 and a small bevel 38 leading to the outer rear surface of the bell cup 22.

If the atomizer 20 is to be used to apply basecoat, the bell cup 22 preferably comprises a titanium alloy, preferably Ti—6Al—4V. If the atomizer 20 is to be used to apply clear coat or primer, the bell cup 22 is preferably Aluminum, most preferably 6Al—4V, 6Al—25N—4Zr—2MO. If the bell cup 22 is titanium, the rear cover 35 is preferably welded to the rear of the bell cup 22 behind the spray edge 32. If Aluminum is used, the rear cover 35 is preferably glued to the rear of the bell cup 22 behind the spray edge 32. Small serrations may be formed on the surface 26 at the spray edge 32 for clearcoat spraying. These serrations are well known and utilized in the art.

Positioned in front of the central axial opening 24 is a deflector 40 which includes a rear surface 42 generally parallel to the perpendicular surface 28 of the bell cup 22 and a rear conical surface 44 which is preferably parallel to the overflow surface 30 of the bell cup 22. The deflector 40 is preferably approximately 22.3 millimeters in diameter, and preferably approximately ⅓ of the diameter of the spray edge 32. More particularly, the diameter of the deflector is less than 40 percent, and most preferably approximately 34.5 percent the diameter of the spray edge 32.

The deflector 40 is shown in more detail in FIG. 4. A passageway 50 leads from the rear surface 42 to a front surface 52 of the deflector 40 and includes four tubular passageways 54 (two shown) leading from the rear surface 42. The deflector 40 is retained on the bell cup 22 with a plurality, preferably 3, press fit, barbed connectors 56 having spacers 58 preferably 0.7 millimeters wide.

The improved bell cup 22 provides a reduced deviation in particle size, which in turn facilitates control of the particulates. In other words, if the size of the atomized paint particles from the spray edge 32 is known, the shaping air velocity, turbulence and RPM of the bell cup 22 and paint flow can be adjusted to ensure that the particles are forced to lay flat on the painted surface by the shaping air from the shaping air ring 23. With a reduced deviation in particle size, these parameters can be optimized for a greater percentage of the paint droplets, thereby providing better color matching.

The reduced deviation in particle size is a result of several inventive aspects of the bell cup 22 and deflector 40. First, the larger annular surface 30 causes more of the solvent (such as water) to evaporate before reaching the spray edge 32. The large diameter spray edge 32 provides a thin film of paint at the spray edge 32. The reduced ratio of the deflector disk 40 to the spray edge 32 provides a more constant, laminar flow across the overflow surface 30 to the spray edge 32. Because the conical surface 30 is continuous and smooth from the deflector 40 to the spray edge 32 and has a constant angle α, the paint flow rate to the spray edge is constant (i.e. does not oscillate). As a result, better control over paint particle size is achieved. Further, as can be seen in FIG. 2, the bell cup 22 of the present invention provides only three flow deviations between the central axial opening 24 and spray edge 32, thus providing a constant, substantially laminar paint flow at the spray edge 32 and therefore a reduced deviation in particle size.

FIGS. 5 through 7 disclose an alternative embodiment of a bell cup 100 having a deflector 110. This bell cup 100 provides only two flow deviations between the central axial opening 112 and the spray edge 132. The conical portion 130 of the overflow surface extends directly from the central axial opening 112 to the spray edge 132. Thus, the overflow surface 126 does not include a perpendicular portion (like perpendicular portion 28 of FIG. 2). This further improves the laminar flow of the paint and reduces further the particle size deviation. The deflector 110 includes a generally conical rear surface 144 which extends to a generally rounded central rear surface 142, thus reducing the flow deviation for the paint. A passageway 150 leads through the deflector 110 and includes four diverging tubular passageways 151. Alternatively, the passageways 151 may converge. The bell cup 100 can also be mounted on atomizer 20 of FIG. 1 in place of bell cup 22.

FIGS. 1-7 are scale drawings.

FIG. 8 illustrates one potential layout of a paint spray zone 150 for applying a basecoat to a vehicle body 152 utilizing the atomizer 20 of the present invention shown in FIGS. 1-7. The vehicle body 152 travels in the direction 154 through the zone 150 while atomizers 20 apply basecoat paint. The zone 150 is a two-pass, thirteen-bell zone which would apply basecoat with good color matching with the efficiency of rotary atomizers. In known systems, the basecoat would be applied by nine rotary atomizers and six air atomizers. The length of the zone 150 could be reduced to approximately thirty feet, compared to forty-five feet for the known basecoat zones. In the zone 150, an overhead machine 156 includes two atomizers 20 and applies a first coat to the center of the horizontal surfaces. A pair of side machines 158 preferably each oscillate an atomizer 20 the full length of the doors of the vehicle 152 on the first pass. A pair of side machines 160 each include a pair of vertically and horizontally offset atomizers each mounted on arms 161. A first arm 161a provides three axes of motion to contour the pillars and paint the edge of the hood and trunk. The second arm 161b is fixed with pivot and horizontal capp. to process the rocker. A pair of side machines 162 provide a second pass on the doors of the vehicle 152. A second overhead machine 164 includes three atomizers 20 to provide a second pass on the horizontal surfaces.

An example will be given utilizing the inventive atomizer 20 of FIGS. 1-4 in the arrangement of FIG. 8 to spray BASF Prairie Tan Metallic Solvent based paint M6818A in a two-pass bell basecoat application with the following parameters: bell cup 22 rotation: 60,000 RPM; fluid flow: 200 cc/min on a first pass and 75 cc/min on a second pass; shaping air: 200 L/min on the first pass and 50 L/min on the second pass. Preferably, any resonant frequencies of the atomizer bearing are avoided. The atomizer 20 produces reduced droplet size deviation, typically 80% of the droplets will be within an 8-50 μm size deviation. With reduced size deviation, the other parameters: can be adjusted to ensure that the mica particles lie flat, thereby providing good color matching. Most preferably, the particle size deviation is reduced below 30 μm. The atomizer 20 produces improved color matching over previous bell zones. The colorimetry data for the example is: ΔL<2.0, ΔA<1.0 and ΔB<1.0. By providing good color matching with rotary atomizers rather than air atomizers, efficiency is greatly improved.

More generally, the bell speed rotation is preferably between 60,000 and 80,000 RPM. Also, the fluid flow of paint preferably does not exceed 250 ml/min.

In accordance with the provisions of the patent statutes and jurisprudence, exemplary configurations described above are considered to represent a preferred embodiment of the invention. However, it should be noted that the invention can be practiced otherwise than as specifically illustrated and described without departing from its spirit or scope.

Claims

1. A method of atomizing a metallic based particulate paint using a bell cup, wherein the bell cup includes a central flat portion leading to an overflow surface providing substantially laminar flow at a spray edge, and a deflector having a rear surface substantially parallel to the central flat portion and a generally conical surface substantially parallel to the generally conical surface of the bell cup, the method comprising: atomizing the metallic based particulate paint by rotating the bell cup at approximately 60,000 to 80,000 rpm with a paint flow not exceeding 250 ml/min and a shaping air flow not exceeding 200 L/min, such that 80% of the droplets are within a 8-50 micron size deviation;wherein a diameter of the spray edge is between approximately 63 millimeters and approximately 75 millimeters.

2. A method as in claim 1 wherein fluid flow of the paint is approximately 75 ml/min.

3. A method as in claim 1 wherein paint is applied to a first pass and a second pass and provides color match.

4. A method as in claim 3 wherein the spray edge includes a diameter and the deflector includes a diameter approximately one third the diameter of the spray edge.

5. A method as in claim 4 wherein the substantially conical overflow surface has a constant angle between approximately 26 and 30 degrees.

6. A method as in claim 5 wherein the spray edge includes a bevel.

7. A method as in claim 1, further comprising establishing the overflow surface as substantially conical from the central flat portion to the spray edge.

8. A rotary atomizer used to atomize a metallic based particulate paint comprising: a bell cup, including: a central flat portion leading to a substantially conical overflow surface providing a color matching flow at a spray edge, the spray edge having a diameter; the particulate paint delivered to the bell cup through a central axial opening, wherein the substantially conical overflow surface extends from the central flat portion substantially to the spray edge; anda deflector having a diameter approximately one third the diameter of the spray edge; the deflector including a rear surface parallel to the central flat portion and a generally conical surface substantially parallel to the overflow surface of the bell cup; anda rear cover attached to the bell cup such that the atomizer is hollow, the rear cover cooperating with the bell cup to form an annular cavity, the annular cavity extending about a perimeter of the bell cup; wherein the rear cover extends from the bell cup to a hub such that the rear cover is substantially frustoconical from the bell cup to the hub.

9. A rotary atomizer as in claim 8 wherein the substantially conical overflow surface includes a constant flow angle.

10. A rotary atomizer as in claim 8 wherein the substantially conical overflow surface is straight.

11. A rotary atomizer as in claim 8 wherein the flow angle is between 26 and 30 degrees.

12. A rotary atomizer as in claim 8 wherein the spray edge includes a bevel.

13. A rotary atomizer as in claim 8 wherein the deflector includes at least one passageway leading from the deflector rear surface.

14. A rotary atomizer as in claim 8, wherein the substantially conical overflow surface defines substantially a single cone shape that extends from the central flat portion to the spray edge.

15. A rotary atomizer as in claim 8, wherein the substantially conical overflow surface extends from the central flat portion to the spray edge.

16. A rotary atomizer as in claim 8, wherein the color matching flow meets at least one of a group of colorimetry values, the group of colorimetry values including: (a) ΔL<2.0;(b) ΔA<1.0; and(c) ΔB<1.0.

17. A rotary atomizer as in claim 8, wherein the color matching flow meets each of a group of colorimetry values, the group of colorimetry values including: (a) ΔL<2.0;(b) ΔA<1.0; and(c) ΔB<1.0.