US3630442A - Electrostatic coating method and apparatus - Google Patents

Electrostatic coating method and apparatus Download PDF

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US3630442A
US3630442A US833401A US3630442DA US3630442A US 3630442 A US3630442 A US 3630442A US 833401 A US833401 A US 833401A US 3630442D A US3630442D A US 3630442DA US 3630442 A US3630442 A US 3630442A
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solid particles
orifice
spray
electrode
elongated
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Richard O Probst
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Randburg Electro-Coating Corp
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B05SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
    • B05BSPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
    • B05B5/00Electrostatic spraying apparatus; Spraying apparatus with means for charging the spray electrically; Apparatus for spraying liquids or other fluent materials by other electric means
    • B05B5/025Discharge apparatus, e.g. electrostatic spray guns
    • B05B5/03Discharge apparatus, e.g. electrostatic spray guns characterised by the use of gas, e.g. electrostatically assisted pneumatic spraying
    • B05B5/032Discharge apparatus, e.g. electrostatic spray guns characterised by the use of gas, e.g. electrostatically assisted pneumatic spraying for spraying particulate materials

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  • a method and apparatus for electrostatically applying solid particles to an article employs a nozzle forming the solid particles into a pattern and directing them at the article, preferably in a relatively flat, fanlike spray.
  • the forward portion of the nozzle is formed of insulating material and includes an ionizing electrode.
  • An electrostatic field is established between the article and an electrode that creates a single highly ionized zone offset from and rearwardly of the spray.
  • the percentage of solid particles which are sprayed but remain undeposited is reduced using this method and ap- Patented Dec. 28, 1971 lllllglglgl l gllg INVENTOR RICHARD O.
  • PROBST ELECTROSTATIC COATING METHOD AND APPARATUS BACKGROUND OF THE INVENTION This invention relates to a method and apparatus for electrostatically charging and depositing a spray of solid particles on an article.
  • coatings are more advantageously applied in dry powder form than as resins dissolved in a liquid carrier.
  • Such coatings include those formed from pigmented resins of polyethylenes, nylon, polyvinyl chloride and epoxides among others. Because of the expense of such materials, it is desirable, when applying such coating, to reduce the amount of material which is not deposited on the articles being coated.
  • thermoplastic or thermosetting powder material is to be applied to an article
  • the article in some instances is raised to a temperature above the fusion temperature of material but below the temperature at which the material is deleteriously affected.
  • the solid particles of material upon being deposited upon the article are fused into a continuous film.
  • heating is sometimes unnecessary and the solid particles which are deposited on the article are retained on the surface of the article as a coating of discrete particles by virtue of their electrostatic charge until they can be fused.
  • Such powdered resin material generally is in the form of solid particles having an average size in the range of 200 to 400 mesh. Solid particles other than thermoplastic or thermosetting materials having sizes outside of this range may also be applied using this invention.
  • ionizing charging electrodes disclosed for use with nozzles having an elongated spray-emitting orifice and creating an elongated, flat spray pattern of solid particles have included elongated ionizing electrodes forming one or both edges of the elongated orifice. Elongated ionizing electrodes have also been positioned in an elongated flat spray pattern of solid particles with their long dimension coextensive with the long dimension of the elongated spray pattern.
  • solid particles can be formed into a spray pattern and charged by adjustably positioning particle deflectors, which have been connected to a source of high voltage, in front of an orifice emitting the solid particles.
  • particle deflectors have included ellipsoidal, cylindrical and hemispherical shapes, among others, located on the axis of the orifice to electrostatically charge and deposit solid particles.
  • a single-wire ionizing and charging electrode projecting forwardly along the axis of a nozzle and within a spray pattern of solid particles is known. Such single-wire electrodes, however, have not proved to achieve satisfactory results. Also known is the use of a wire electrode projecting forwardly beyond the orifice at one side of and space slightly from the spray. Such an electrode arrangement, however, provides lower transfer efficiency (the ratio of the weight of material deposited on an article to the weight of material discharged from a gun) in a powder gun than does an annular electrode of I the types described above.
  • the solid particles are formed into a pattern and directed at the article upon which the particles are to be deposited.
  • An electrostatic field is established to the article from a point offset from the spray pattern and located rearwardly of the pattern. At this point a single highly ionized zone is created.
  • Apparatus to practice this method may be achieved by providing, in a system including a source of solid particles and means to provide a flow of solid particles, a nozzle of nonconducting material to form the solid particles into a pattern that is emitted from an orifice and directed at an article, and a single elongated electrode, preferably carried by the nozzle, having a tip located offset from and rearwardly of the orifice.
  • a single elongated electrode when the single elongated electrode is charged to high voltage with respect to the articles, it creates a single highly ionized zone and a strong electrostatic field to the article.
  • the number of solid particles emitted from the nozzle that are not ultimately deposited upon the article being coated is greatly reduced.
  • the percentage of solid particles not deposited upon the article can be reduced by 20 percent to 30 percent over prior solid-particle electrostatic spray methods and apparatus, under similar conditions.
  • FIG. 1 is a perspective drawing of a system for electrostatically charging and applying solid particles to the articles to be coated using the method and apparatus of this invention.
  • FIG. 2 is a front view of a nozzle and electrode embodying this invention.
  • FIG. 3 is a cross-sectional view of this nozzle and electrode along the plane illustrated by line 3-3 of FIG. 2, through the center of the nozzle.
  • the articles to be coated which may be platelike members 10 as illustrated in FIG. I, are hung from conductive supporting members 11 depending from a conveyor 12, which is maintained at ground potential.
  • the articles I0 are electrically connected to ground potential by electrical contact with the conductive depending members 11 and the grounded conveyor 12.
  • Source 13 of coating material for the spray gun 14 includes a foraminous plate (not shown) upon which the solid particles of coating material rest. Compressed air is supplied below and flows through the foraminous plate within the source of coating material I3. In operation, the flow of compressed air to the chamber is controlled by a regulator (not shown). The air passing through the foraminous plate produces a fluidized bed of solid particles within the source 13. An injection pump within the fluidized bed is used to withdraw coating material particles from the bed and to entrain them as a suspension in a flow of compressed air for delivery to spray gun 14.
  • Solid particles of coating material are conveyed through an elongated flexible tube 15, as a suspension in compressed air, into spray gun 14. Delivery of coating material to spray gun 14 is controlled by the operator of the spray gun by manipulation of a trigger which actuates solenoid valve (not shown) controlling the flow of air through the injection pump. Coating material particles are withdrawn from the fluidized bed I3 and entrained in the compressed air by the injection pump. When the operator of the spray gun wishes to apply coating material particles to an article to be coated, he merely depresses the trigger of the spray gun. Coating material particles are withdrawn from the source 13 in the manner described and delivered through the elongated flexible tube to an orifice in spray nozzle 16 on the spray gun.
  • Actuation of the trigger also turns on a source of high voltage 17. Electric charge is delivered through a high-voltage conductor 18 to spray gun 14. Coating material particles issuing from the orifice are formed into a pattern suitable for application of the solid materials to the article and directed at the article. Solid particles emitted from the orifice are electrostatically charged and deposited by establishing an electrostatic field to the article from a highly ionized zone offset from and rearwardly of the spray pattern. Using such a method, the operator can apply solid particles to the article to be coated with little waste. The method can be practiced with apparatus permitting the ,operator to easily manipulate the spray gun directing a flow of charged solid particles at the article 10 to achieve a uniform coating on the article.
  • FIGS. 2 and 3 show the front end of spray gun 14.
  • the front end of barrel 20 is adapted to accept spray nozzle 16 and charging electrode 21.
  • the barrel contains a threaded portion 22 to accept nut 23 which attaches spray nozzle 16 to the front end of barrel 20.
  • Spray nozzle 16, nut 23, and barrel 20 are all made of nonconductive material such as nylon, acetal resin sold under the trade mark Delrin by E. I. du Pont de Nemours Co., polyethylene, polypropylene, polytetraflourethylene, phenolic, or nonconductive ceramics and the like.
  • the solid particles are conveyed as a suspension in a flowing gas through passageway 24 in barrel 20.
  • Spray nozzle 16 includes a body 16 of nonconductive material including a bore within the body defined by walls 25 that converge at an elongated, orifice 26 at its forward end.
  • the structure includes means 27 carried within the bore including a surface protruding into the bore rearwardly of the orifice 26 and an elongated electrode 21 carried by the body with its forwardmost tip 19 offset from and rearwardly of the orifice 26.
  • the tip of the electrode 21 is offset laterally from the orifice 26 in a direction perpendicular to the common plane of the elongated orifice 26 and the spray discharged therefrom. Also as is clear from the drawing, the tip of the electrode is displaced rearwardly from the orifice of the nozzle. It is in this respect that the electrode of this invention differs from the fine-wire electrodes previously used in electrostatic guns. The distance between the electrode tip and the plane of the front face of the nozzle may vary.
  • electrode 21 When charged to high voltage, typically 40,000 to 100,000 volts DC, electrode 21 establishes an electrostatic field to the articles to be coated 10.
  • the tip 19 of the electrode 21 creates a single highly ionized zone. This zone being located offset from and rearwardly of the spray pattern emitted from orifice 26 charges the solid particles in the pattern and results in a greatly reduced percentage of undeposited powder.
  • Offset from and rearwardly of the spray pattern refers to the location for the tip of the electrode and the highly ionized zone it creates that is rearwardly of the orifice of the nozzle up to on the order of 1 inch or more and offset from the axis of the orifice a distance of about be inch although the offset can be up to l inch.
  • a specifically preferred embodimentof my invention is the pattern-forming and electrostatic-charging structure shown in FIGS. 2 and 3.
  • the bore in the body of spray nozzle 16 has walls 25 that are hemispherical in form and converge at an elongated orifice 26.
  • the elongated orifice 26 is formed at the intersection of a V-shaped groove 28 extending transversely across the front end of the nozzle with the hemispherical walls 25 of the interior bore of the spray nozzle.
  • the body of spray nozzle 16 is formed of Teflon (registered trade mark of E. I. du Pont de Nemours Co.) reinforced with glass fibers.
  • the means 27 Spaced rearwardly within the nozzle are means 27 to intercept and deflect a portion of the gaseous suspension of solid particles flowing through nozzle 16.
  • the means 27 is a cylindrical pin within the bore of the spray nozzle and spaced rearwardly from the orifice.
  • the nozzle shown in FIG. 3 acts upon the flowing gaseous suspension of solid particles emitted from passageway 24, forming the suspension into an expanding fanlike spray at the orifice 26 and creating an elongated spray pattern with uniformly distributed particles.
  • An elongated wirelike electrode 21 is carried by spray nozzle 16 with its tip 19 rearwardly about one-half inch of the orifice from which the spray is emitted and laterally offset from the plane of the spray pattern about one-half inch.
  • Such an electrode is desirably a short length (about I inch) of music wire having a diameter of 0.020 of an inch.
  • the high voltage from voltage supply 17 is carried to the gun by high-voltage cable 18 within the barrel 20 in the spray gun 14.
  • the highvoltage cable 18 is connected to resistor 29 which is connected at its forward end with conductive plug 30 and wire 31.
  • Electrode 21 is electrically connected to wire 31 when noule 16 is attached to the front of the gun barrel.
  • the spray nozzle 16 can be formed with a conductive plastic ring in the rear surface in contact with the rear end of the elongated wirelike electrode.
  • Resistor 29 typically has a value of megohms.
  • All parts at the forward end of the gun except the electrode 21 and the conductive elements through which high voltage is applied to the electrode are made of insulating material in order to avoid shielding of the electrode tip.
  • the electrode 21 of the specifically preferred embodiment is charged with a high voltage of about 90,000 volts DC, the spray nozzle 16 is spaced about 7 inches from a grounded article and supplied wit powder at a rate of about 375 grams per minute, the percentage of powder not deposited on the article is reduced below that obtainable with anyother relationship between the spray pattern and the tip of the electrode and the single highly ionized zone it creates.
  • An apparatus for electrostatically depositing entrained solid particles on an article at a particle attracting potential comprising,
  • means including a passageway for conveying entrained particles adapted to be connected to a source of entrained solid particles,
  • nozzle means of nonconducting material connected to the passageway, the nozzle means to form the solid particle into a spray pattern issuing from an orifice and direct the solid particles at the article, and
  • a single elongated electrode having a tip located offset from and rearwardly of the orifice.
  • a pattem-forming and electrostatic-charging structure for an apparatus for electrostatically depositing entrained solid particles comprising,
  • means including a passageway for conveying entrained solid particles adapted to be connected to a source of entrained solid particles,
  • a body of nonconducting material having an elongated orifice at its forward end and a bore within the body defined by walls that converge at the orifice, the bore of the body connected to the passageway,
  • an elongated wirelike electrode carried by the body with its forwardmost tip offset from and rearwardly of the orifice.
  • the pattern-forming and electrostatic charging structure of claim 5 wherein the walls that converge at the orifice are hemispherical in form, the elongated orifice is formed at the intersection of the walls and a V-shaped groove in the forward end of the body, the means carried by the-body is a pin extending into the bore, and the tip of the wirelike electrode offset from the orifice about one-half inch and rearwardly of the orifice about one-half inch.
  • An apparatus for electrostatically charging and depositing a spray of solid particles entrained in a gas on an article at a particle attracting potential comprising,
  • means including a barrel of nonconductive material including a passageway adapted to be connected to a source of entrained solid particles in gas,
  • a body of nonconductive material connected to the passageway of the barrel, the body including an orifice for forming the solid particles into a spray pattern, and
  • an elongated charged electrode adjacent the body the forwardmost tip of the electrode offset from and rearwardly 1 of the orifice establishing an electrostatic field between the article and the electrode and a single highly ionized zone offset from and rearwardly of the spray to charge the solid particles of the spray.

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  • Electrostatic Spraying Apparatus (AREA)
  • Application Of Or Painting With Fluid Materials (AREA)

Abstract

A method and apparatus for electrostatically applying solid particles to an article employs a nozzle forming the solid particles into a pattern and directing them at the article, preferably in a relatively flat, fanlike spray. The forward portion of the nozzle is formed of insulating material and includes an ionizing electrode. An electrostatic field is established between the article and an electrode that creates a single highly ionized zone offset from and rearwardly of the spray. The percentage of solid particles which are sprayed but remain undeposited is reduced using this method and apparatus.

Description

United States Patent 72 Inventor RichardQPr-obat 3,279,429 Indianapolis, Ind. 3,393,662 [21] AppLNo. 833,401 3,408,985 [22] Filed Jnne16,1969 3,463,395 [45] Patented Dec.28,l971 3,476,319 [73] Assignee RandburgEleetm-CoatingCor-p. 3,498,541
lndianapoklnd.
59,514 54 ELECTROSTATIC COATING METHODAND M51979 APPARATUS 1,125,446 7Claims,3DrawingFigs.
[521 U.S.Cl 239/15, 239/3 51] [61.01. B05b5/00, F23d11/28 [so] Fieldolsearell 239/15,3
[56] References Cited UNITED STATES PATENTS 3,248,606 4/1966 Fraser 239/15 3,263,127 7/1966 PointetaL 239/15 3,327,948 6/1967 Gignoux 239/15 2,995,393 8/1961 Charp 239/15x 3,195,264 7/1965 Ward,Jr.... 239/15 3,268,171 8/1966 Walberg 239115 Pam",
\ Ill/1 Primary Examiner--Lloyd L. King Attumeys-Merrill N. Johnson, Harry E. Downer, David H.
Badger and Charles W. l-lofi'rnann ABSTRACT: A method and apparatus for electrostatically applying solid particles to an article employs a nozzle forming the solid particles into a pattern and directing them at the article, preferably in a relatively flat, fanlike spray. The forward portion of the nozzle is formed of insulating material and includes an ionizing electrode. An electrostatic field is established between the article and an electrode that creates a single highly ionized zone offset from and rearwardly of the spray. The percentage of solid particles which are sprayed but remain undeposited is reduced using this method and ap- Patented Dec. 28, 1971 lllllglglgl l gllg INVENTOR RICHARD O. PROBST ELECTROSTATIC COATING METHOD AND APPARATUS BACKGROUND OF THE INVENTION This invention relates to a method and apparatus for electrostatically charging and depositing a spray of solid particles on an article.
Many coatings are more advantageously applied in dry powder form than as resins dissolved in a liquid carrier. Such coatings include those formed from pigmented resins of polyethylenes, nylon, polyvinyl chloride and epoxides among others. Because of the expense of such materials, it is desirable, when applying such coating, to reduce the amount of material which is not deposited on the articles being coated.
Where thermoplastic or thermosetting powder material is to be applied to an article, the article in some instances is raised to a temperature above the fusion temperature of material but below the temperature at which the material is deleteriously affected. The solid particles of material upon being deposited upon the article are fused into a continuous film. In other instances where electrostatic charging is used, heating is sometimes unnecessary and the solid particles which are deposited on the article are retained on the surface of the article as a coating of discrete particles by virtue of their electrostatic charge until they can be fused.
Such powdered resin material generally is in the form of solid particles having an average size in the range of 200 to 400 mesh. Solid particles other than thermoplastic or thermosetting materials having sizes outside of this range may also be applied using this invention.
Guns for spraying an air suspension of solid particles and for electrically charging the spray of solid particles are now in common use. Many combinations of spray nozzles and charging electrodes in a variety of configurations and arrangements are known. For example, it has been common in such guns irrespective of whether the discharged spray is of either conical or flat, fanlike form, to effect the charging of powder by the use of an annular ionizing electrode surrounding the spray. Such an annular electrode has been formed at one or both edges of an annular slot in a nozzle that forms the solid particles into a conical spray. Annular ionizing electrodes have also been fonned on one edge of a male that forms the solid particles into a spray having a flat, fanlike form so that they surround the spray near its source. An annular ionizing electrode located rearwardly of the spray, in some instances, supplemented the electrode formed on the edge of the nozzle.
Other ionizing charging electrodes disclosed for use with nozzles having an elongated spray-emitting orifice and creating an elongated, flat spray pattern of solid particles have included elongated ionizing electrodes forming one or both edges of the elongated orifice. Elongated ionizing electrodes have also been positioned in an elongated flat spray pattern of solid particles with their long dimension coextensive with the long dimension of the elongated spray pattern.
In addition, it has been suggested that solid particles can be formed into a spray pattern and charged by adjustably positioning particle deflectors, which have been connected to a source of high voltage, in front of an orifice emitting the solid particles. Such deflectors have included ellipsoidal, cylindrical and hemispherical shapes, among others, located on the axis of the orifice to electrostatically charge and deposit solid particles.
A single-wire ionizing and charging electrode projecting forwardly along the axis of a nozzle and within a spray pattern of solid particles is known. Such single-wire electrodes, however, have not proved to achieve satisfactory results. Also known is the use of a wire electrode projecting forwardly beyond the orifice at one side of and space slightly from the spray. Such an electrode arrangement, however, provides lower transfer efficiency (the ratio of the weight of material deposited on an article to the weight of material discharged from a gun) in a powder gun than does an annular electrode of I the types described above.
FEATURES OF THE INVENTION In the method of electrostatically depositing solid particles which comprises this invention, the solid particles are formed into a pattern and directed at the article upon which the particles are to be deposited. An electrostatic field is established to the article from a point offset from the spray pattern and located rearwardly of the pattern. At this point a single highly ionized zone is created. Apparatus to practice this method may be achieved by providing, in a system including a source of solid particles and means to provide a flow of solid particles, a nozzle of nonconducting material to form the solid particles into a pattern that is emitted from an orifice and directed at an article, and a single elongated electrode, preferably carried by the nozzle, having a tip located offset from and rearwardly of the orifice. In such a system when the single elongated electrode is charged to high voltage with respect to the articles, it creates a single highly ionized zone and a strong electrostatic field to the article. In using this invention, the number of solid particles emitted from the nozzle that are not ultimately deposited upon the article being coated is greatly reduced. With a nonconducting nozzle that forms solid particles into a flat, fanlike spray and that includes an electrode formed of 0.020 wire and having a tip located offset 1% inch laterally from the plane of the spray and about k inch rearwardly of the orifice, the percentage of solid particles not deposited upon the article can be reduced by 20 percent to 30 percent over prior solid-particle electrostatic spray methods and apparatus, under similar conditions.
DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective drawing of a system for electrostatically charging and applying solid particles to the articles to be coated using the method and apparatus of this invention.
FIG. 2 is a front view of a nozzle and electrode embodying this invention.
FIG. 3 is a cross-sectional view of this nozzle and electrode along the plane illustrated by line 3-3 of FIG. 2, through the center of the nozzle.
DESCRIPTION OF THE PREFERRED EMBODIMENT The articles to be coated, which may be platelike members 10 as illustrated in FIG. I, are hung from conductive supporting members 11 depending from a conveyor 12, which is maintained at ground potential. The articles I0 are electrically connected to ground potential by electrical contact with the conductive depending members 11 and the grounded conveyor 12.
Solid particles of the coating material to be applied are placed in the material source 13. Source 13 of coating material for the spray gun 14 includes a foraminous plate (not shown) upon which the solid particles of coating material rest. Compressed air is supplied below and flows through the foraminous plate within the source of coating material I3. In operation, the flow of compressed air to the chamber is controlled by a regulator (not shown). The air passing through the foraminous plate produces a fluidized bed of solid particles within the source 13. An injection pump within the fluidized bed is used to withdraw coating material particles from the bed and to entrain them as a suspension in a flow of compressed air for delivery to spray gun 14.
Solid particles of coating material are conveyed through an elongated flexible tube 15, as a suspension in compressed air, into spray gun 14. Delivery of coating material to spray gun 14 is controlled by the operator of the spray gun by manipulation of a trigger which actuates solenoid valve (not shown) controlling the flow of air through the injection pump. Coating material particles are withdrawn from the fluidized bed I3 and entrained in the compressed air by the injection pump. When the operator of the spray gun wishes to apply coating material particles to an article to be coated, he merely depresses the trigger of the spray gun. Coating material particles are withdrawn from the source 13 in the manner described and delivered through the elongated flexible tube to an orifice in spray nozzle 16 on the spray gun. Actuation of the trigger also turns on a source of high voltage 17. Electric charge is delivered through a high-voltage conductor 18 to spray gun 14. Coating material particles issuing from the orifice are formed into a pattern suitable for application of the solid materials to the article and directed at the article. Solid particles emitted from the orifice are electrostatically charged and deposited by establishing an electrostatic field to the article from a highly ionized zone offset from and rearwardly of the spray pattern. Using such a method, the operator can apply solid particles to the article to be coated with little waste. The method can be practiced with apparatus permitting the ,operator to easily manipulate the spray gun directing a flow of charged solid particles at the article 10 to achieve a uniform coating on the article.
FIGS. 2 and 3 show the front end of spray gun 14. The front end of barrel 20 is adapted to accept spray nozzle 16 and charging electrode 21. The barrel contains a threaded portion 22 to accept nut 23 which attaches spray nozzle 16 to the front end of barrel 20. Spray nozzle 16, nut 23, and barrel 20 are all made of nonconductive material such as nylon, acetal resin sold under the trade mark Delrin by E. I. du Pont de Nemours Co., polyethylene, polypropylene, polytetraflourethylene, phenolic, or nonconductive ceramics and the like. The solid particles are conveyed as a suspension in a flowing gas through passageway 24 in barrel 20. Solid particles are formed by nozzle 16 into a spray pattern issuing from an orifice 26 at the front of the gun. Spray nozzle 16 includes a body 16 of nonconductive material including a bore within the body defined by walls 25 that converge at an elongated, orifice 26 at its forward end. The structure includes means 27 carried within the bore including a surface protruding into the bore rearwardly of the orifice 26 and an elongated electrode 21 carried by the body with its forwardmost tip 19 offset from and rearwardly of the orifice 26.
As will be clear from the drawings, the tip of the electrode 21 is offset laterally from the orifice 26 in a direction perpendicular to the common plane of the elongated orifice 26 and the spray discharged therefrom. Also as is clear from the drawing, the tip of the electrode is displaced rearwardly from the orifice of the nozzle. It is in this respect that the electrode of this invention differs from the fine-wire electrodes previously used in electrostatic guns. The distance between the electrode tip and the plane of the front face of the nozzle may vary.
When charged to high voltage, typically 40,000 to 100,000 volts DC, electrode 21 establishes an electrostatic field to the articles to be coated 10. The tip 19 of the electrode 21 creates a single highly ionized zone. This zone being located offset from and rearwardly of the spray pattern emitted from orifice 26 charges the solid particles in the pattern and results in a greatly reduced percentage of undeposited powder. Offset from and rearwardly of the spray pattern refers to the location for the tip of the electrode and the highly ionized zone it creates that is rearwardly of the orifice of the nozzle up to on the order of 1 inch or more and offset from the axis of the orifice a distance of about be inch although the offset can be up to l inch.
A specifically preferred embodimentof my invention is the pattern-forming and electrostatic-charging structure shown in FIGS. 2 and 3. The bore in the body of spray nozzle 16 has walls 25 that are hemispherical in form and converge at an elongated orifice 26. In this specifically preferred embodiment, the elongated orifice 26 is formed at the intersection of a V-shaped groove 28 extending transversely across the front end of the nozzle with the hemispherical walls 25 of the interior bore of the spray nozzle. The body of spray nozzle 16 is formed of Teflon (registered trade mark of E. I. du Pont de Nemours Co.) reinforced with glass fibers. Spaced rearwardly within the nozzle are means 27 to intercept and deflect a portion of the gaseous suspension of solid particles flowing through nozzle 16. As shown in FIG. 3, the means 27 is a cylindrical pin within the bore of the spray nozzle and spaced rearwardly from the orifice. The nozzle shown in FIG. 3 acts upon the flowing gaseous suspension of solid particles emitted from passageway 24, forming the suspension into an expanding fanlike spray at the orifice 26 and creating an elongated spray pattern with uniformly distributed particles.
An elongated wirelike electrode 21 is carried by spray nozzle 16 with its tip 19 rearwardly about one-half inch of the orifice from which the spray is emitted and laterally offset from the plane of the spray pattern about one-half inch. Such an electrode is desirably a short length (about I inch) of music wire having a diameter of 0.020 of an inch. The high voltage from voltage supply 17 is carried to the gun by high-voltage cable 18 within the barrel 20 in the spray gun 14. The highvoltage cable 18 is connected to resistor 29 which is connected at its forward end with conductive plug 30 and wire 31. Electrode 21 is electrically connected to wire 31 when noule 16 is attached to the front of the gun barrel. If desired, the spray nozzle 16 can be formed with a conductive plastic ring in the rear surface in contact with the rear end of the elongated wirelike electrode. Resistor 29 typically has a value of megohms. When short, wirelike electrode 21 is connected to high voltage through a sufficiently small wire 31, a plug 30 comprised of material having a high resistivity, and a 160- megohm resistor, the electrostatic method and apparatus of this invention can be used safely.
All parts at the forward end of the gun except the electrode 21 and the conductive elements through which high voltage is applied to the electrode are made of insulating material in order to avoid shielding of the electrode tip. When the electrode 21 of the specifically preferred embodiment is charged with a high voltage of about 90,000 volts DC, the spray nozzle 16 is spaced about 7 inches from a grounded article and supplied wit powder at a rate of about 375 grams per minute, the percentage of powder not deposited on the article is reduced below that obtainable with anyother relationship between the spray pattern and the tip of the electrode and the single highly ionized zone it creates.
While I have shown and described the preferred embodiment of my invention, it is to be understood that it is capable of modification. For example, the electrostatic field and highly ionized zone may be created by charging the articles to be coated and grounding the electrode adjacent the spray pattern. Changes, therefore, in the construction and arrangement may be made without departing from the spirit and scope of the invention as disclosed in the following claims.
lclaim:
1. An apparatus for electrostatically depositing entrained solid particles on an article at a particle attracting potential comprising,
means including a passageway for conveying entrained particles adapted to be connected to a source of entrained solid particles,
nozzle means of nonconducting material connected to the passageway, the nozzle means to form the solid particle into a spray pattern issuing from an orifice and direct the solid particles at the article, and
a single elongated electrode having a tip located offset from and rearwardly of the orifice.
2. A pattem-forming and electrostatic-charging structure for an apparatus for electrostatically depositing entrained solid particles comprising,
means including a passageway for conveying entrained solid particles adapted to be connected to a source of entrained solid particles,
a body of nonconducting material having an elongated orifice at its forward end and a bore within the body defined by walls that converge at the orifice, the bore of the body connected to the passageway,
means carried by the body within the bore including a surface protruding into the bore rearwardly of the orifice, and
an elongated wirelike electrode carried by the body with its forwardmost tip offset from and rearwardly of the orifice.
3. The pattern-forming and electrostatic charging structure of claim 5 wherein the walls that converge at the orifice are hemispherical in form, the elongated orifice is formed at the intersection of the walls and a V-shaped groove in the forward end of the body, the means carried by the-body is a pin extending into the bore, and the tip of the wirelike electrode offset from the orifice about one-half inch and rearwardly of the orifice about one-half inch.
4. The structure of claim 2, wherein the body carries a conductive plastic ring in its rear surface in contact with the rear end of the elongated wire.
5. An apparatus for electrostatically charging and depositing a spray of solid particles entrained in a gas on an article at a particle attracting potential comprising,
means including a barrel of nonconductive material including a passageway adapted to be connected to a source of entrained solid particles in gas,
a body of nonconductive material connected to the passageway of the barrel, the body including an orifice for forming the solid particles into a spray pattern, and
an elongated charged electrode adjacent the body, the forwardmost tip of the electrode offset from and rearwardly 1 of the orifice establishing an electrostatic field between the article and the electrode and a single highly ionized zone offset from and rearwardly of the spray to charge the solid particles of the spray.
6. The apparatus for electrostatically charging and depositing a spray of solid particles entrained in gas as claimed in claim 5, wherein the body includes means for forming the solid particles into a spray pattern having solid particles sub stantially uniformly distributed therein.
7. The apparatus for electrostatically charging and depositing a spray of solid particles entrained in a gas as claimed in claim 5, wherein the orifice is elongated and the tip of the electrode is laterally offset from and rearwardly of the orifice in a direction substantially perpendicular to the common plane of the elongated orifice and the spray emitted therefrom.
UNITED STATES PATENT OFFICE CERTIFECATE 0F CORRECTION Patent No- 3,630,442 Dated December 28. 1971 Inventor(s) Richard O. Probst It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
On the cover sheet [73] "Randburg Electro-Coating Corp. Indianapolis, Ind." should read Ransburg Electro-Coating Corp. Indianapolis, Ind. Column 4, line 35, "wit" should read with Column 5, line 2, "5" should read 2 Signed and sealed t'his 3lst day of October 1972.
(SEAL) Attest:
EDWARD M..FLETCHER,JR. ROBERT GOTTSCHALK Attesting Officer v Commissioner of Patents FORM PO-1050 (10-69) I USCOMM-DC scam-Pen 1 U.S. GOVERNMENT PRINTING OFFICE: 1965 0*365'3ll

Claims (7)

1. An apparatus for electrostatically depositing entrained solid particles on an article at a particle attracting potential comprising, means including a passageway for conveying entrained particles adapted to be connected to a source of entrained solid particles, nozzle means of nonconducting material connected to the passageway, the nozzle means to form the solid particle into a spray pattern issuing from an orifice and direct the solid particles at the article, and a single elongated electrode having a tip located offset from and rearwardly of the orifice.
2. A pattern-forming and electrostatic-charging structure for an apparatus for electrostatically depositing entrained solid particles comprising, means including a passageway for conveying entrained solid particles adapted to be connected to a source of entrained solid particles, a body of nonconducting material having an elongated orifice at its forward end and a bore within the body defined by walls that converge at the orifice, the bore of the body connected to the passageway, means carried by the body within the bore including a surface protruding into the bore rearwardly of the orifice, and an elongated wirelike electrode carried by the body with its forwardmost tip offset from and rearwardly of the orifice.
3. The pattern-forming and electrostatic charging structure of claim 5 wherein the walls that converge at the orifice are hemispherical in form, the elongated orifice is formed at the intersection of the walls and a V-shaped groove in the forward end of the body, the means carried by the body is a pin extending into the bore, and the tip of the wirelike electrode offset from the orifice about one-half inch and rearwardly of the orifice about one-half inch.
4. The structure of claim 2, wherein the body carries a conductive plastic ring in its rear surface in contact with the rear end of the elongated wire.
5. An apparatus for electrostatically charging and depositing a spray of solid particles entrained in a gas on an article at a particle attracting potential comprising, means including a barrel of nonconductive material including a passageway adapted to be connected to a source of entrained solid particles in gas, a body of nonconductive material connected to the passageway of the barrel, the body including an orifice for forming the solid particles into a spray pattern, and an elongated charged electrode adjacent the body, the forwardmost tip of the electrode offset from and rearwardly of the orifice establishing an electrostatic field between the article and the electrode and a single highly ionized zone offset from and rearwardly of the spray to charge the solid particles of the spray.
6. The apparatus for electrostatically charging and depositing a spray of solid particles entrained in gas as claimed in claim 5, wherein the body includes means for forming the solid particles into a spray pattern having solid particles substantially uniformly distributed therein.
7. The apparatus for electrostatically charging and depositing a sPray of solid particles entrained in a gas as claimed in claim 5, wherein the orifice is elongated and the tip of the electrode is laterally offset from and rearwardly of the orifice in a direction substantially perpendicular to the common plane of the elongated orifice and the spray emitted therefrom.
US833401A 1969-06-16 1969-06-16 Electrostatic coating method and apparatus Expired - Lifetime US3630442A (en)

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BE (1) BE752060A (en)
CH (1) CH518742A (en)
DE (1) DE2028549B2 (en)
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US3724755A (en) * 1971-09-27 1973-04-03 Allis Chalmers Powder-air venturi for electrostatic spray coating system
US3752404A (en) * 1971-11-08 1973-08-14 Curtis Helene Ind Inc Compressed air spray apparatus
US3793049A (en) * 1969-06-16 1974-02-19 R Probst Electrostatic coating method
US3903321A (en) * 1972-01-25 1975-09-02 Hans J Schaad Method for charging plastic powder electrostatically by friction only

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FR59514E (en) * 1948-08-03 1954-06-28 Improvements to powdering methods used in agriculture
US2995393A (en) * 1957-10-30 1961-08-08 Nalco Chemical Co Method and apparatus for increasing the coefficient of friction between metal surfaces
US3195264A (en) * 1963-10-01 1965-07-20 Robert P Bennett Nozzle for electrostatic dusting devices
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US3263127A (en) * 1961-04-14 1966-07-26 Sames Mach Electrostat Means for electrostatic coating
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US3279429A (en) * 1962-04-25 1966-10-18 Sames Sa De Machines Electrost Spray-coating apparatus
US3327948A (en) * 1964-07-07 1967-06-27 Cosmic Inc Method of electrostatic coating including velocity reduction
US3393662A (en) * 1964-12-30 1968-07-23 Ronald J. Blackwell Apparatus for electrostatic spray coating
GB1125446A (en) * 1964-09-16 1968-08-28 Ashdee Corp Electrostatic spraying gun
US3408985A (en) * 1966-11-07 1968-11-05 Interplanetary Res & Dev Corp Electrostatic spray coating apparatus
GB1151079A (en) * 1965-12-06 1969-05-07 Gema Ag Appbau Improvements in or relating to Guns for the Electrostatic Spray Coating of Objects with a Powder.
US3463395A (en) * 1966-01-06 1969-08-26 S K V Sa Spray gun nozzle heads
US3476319A (en) * 1968-11-25 1969-11-04 Ransburg Electro Coating Corp Electrostatic powder-coating apparatus
US3498541A (en) * 1968-03-25 1970-03-03 Goodyear Tire & Rubber Apparatus for altering the shape of an electrostatic spray pattern

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR59514E (en) * 1948-08-03 1954-06-28 Improvements to powdering methods used in agriculture
US2995393A (en) * 1957-10-30 1961-08-08 Nalco Chemical Co Method and apparatus for increasing the coefficient of friction between metal surfaces
US3263127A (en) * 1961-04-14 1966-07-26 Sames Mach Electrostat Means for electrostatic coating
US3248606A (en) * 1961-12-08 1966-04-26 Sames Mach Electrostat Apparatus for dispersing and electrically charging substances in discrete particulate form
US3279429A (en) * 1962-04-25 1966-10-18 Sames Sa De Machines Electrost Spray-coating apparatus
US3268171A (en) * 1962-07-19 1966-08-23 H G Fischer & Company Electrostatic coating system
US3195264A (en) * 1963-10-01 1965-07-20 Robert P Bennett Nozzle for electrostatic dusting devices
US3327948A (en) * 1964-07-07 1967-06-27 Cosmic Inc Method of electrostatic coating including velocity reduction
GB1125446A (en) * 1964-09-16 1968-08-28 Ashdee Corp Electrostatic spraying gun
US3393662A (en) * 1964-12-30 1968-07-23 Ronald J. Blackwell Apparatus for electrostatic spray coating
GB1151079A (en) * 1965-12-06 1969-05-07 Gema Ag Appbau Improvements in or relating to Guns for the Electrostatic Spray Coating of Objects with a Powder.
US3463395A (en) * 1966-01-06 1969-08-26 S K V Sa Spray gun nozzle heads
US3408985A (en) * 1966-11-07 1968-11-05 Interplanetary Res & Dev Corp Electrostatic spray coating apparatus
US3498541A (en) * 1968-03-25 1970-03-03 Goodyear Tire & Rubber Apparatus for altering the shape of an electrostatic spray pattern
US3476319A (en) * 1968-11-25 1969-11-04 Ransburg Electro Coating Corp Electrostatic powder-coating apparatus

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3793049A (en) * 1969-06-16 1974-02-19 R Probst Electrostatic coating method
US3724755A (en) * 1971-09-27 1973-04-03 Allis Chalmers Powder-air venturi for electrostatic spray coating system
US3752404A (en) * 1971-11-08 1973-08-14 Curtis Helene Ind Inc Compressed air spray apparatus
US3903321A (en) * 1972-01-25 1975-09-02 Hans J Schaad Method for charging plastic powder electrostatically by friction only

Also Published As

Publication number Publication date
SE371783B (en) 1974-12-02
AT307593B (en) 1973-05-25
CH518742A (en) 1972-02-15
DE2028549A1 (en) 1971-05-06
FR2052588A5 (en) 1971-04-09
DE2028549B2 (en) 1975-04-10
BE752060A (en) 1970-12-01
NL7008639A (en) 1970-12-18
GB1315531A (en) 1973-05-02

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