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Publication numberUS2994165 A
Publication typeGrant
Publication dateAug 1, 1961
Filing dateFeb 6, 1959
Priority dateFeb 6, 1959
Publication numberUS 2994165 A, US 2994165A, US-A-2994165, US2994165 A, US2994165A
InventorsBrevik Elmer L
Original AssigneePurex Corp Ltd
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Equipment and process for deburring and burnishing metal parts
US 2994165 A
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Description  (OCR text may contain errors)

E- L. BREVIK Aug. 1, 1961 EQUIPMENT AND PROCESS FOR DEBURRING AND BURNISHING METAL PARTS Filed Feb. 6, 1959 2 Sheets-Sheet 1 INVENTOR.

Aug. 1, 1961 E. L. BREVIK 2,

EQUIPMENT AND PROCESS FOR DEBURRING AND BURNISHING METAL PARTS Filed Feb. 6, 1959 2 Sheets-Sheet 2 INVENTOR.

United States Patent 2,994,165 EQUIPMENT AND PROCESS FOR DEBURRING AND BURNISHING METAL PARTS Elmer L. Brevik, Los Angeles, Calif., assignor, by mesne assignments, to Purex Corporation, Ltd., a corporation of California Filed Feb. 6, 1959, Ser. No. 791,763 7 Claims. (Cl. 51-164) This invention relates to new and novel equipment and process for debur-ring and burnishing of small parts.

In the manufacture of small components, particularly metal parts, it has been the practice to remove metal burrs, such as the flashings of die castings and the burrs produced by drilling operations either by hand operation with an abrasive tool, by electrolytic dissolution in a chemical solution or by the use of tumbling barrels containing abrasive particles. The tumbling barrels are usually considered the most efficient method of performing a deburring operation in mass-produced small dimensional articles because of the elimination of most manual handling of the parts.

It has also been found that after the parts are deburred, it is frequently necessary to burnish or polish the part either for reason of surface finish requirements; for reasons of utility; for the esthetic value of a highly lustrous part or for subsequent plating operations. Numerous methods have also been employed for burnishing or smoothing the small parts such as hand buffing, electro polishing, grit blasting, chemical polishing or tumbling in the presence of burnishing balls. This latter method has found widespread usage because of the low cost for manual labor, low power requirements, and small consumption of chemical agents. It has also been attractive from the standpoint of operational equipment as the deburn'ng and burnishing operations can be conducted in the same equipment. Therefore, for the purpose of clarity, both burnishing and deburring shall hereinafter be referred to by the generic term tumbling.

Although conventional tumbling procedures have been found both economical and eflicient, there have been several inherent difliculties with the operation. It is generally recognized that in the deburring operation the time required to deburr a part was a function of the ductility, strength and hardness; a material of low duetility, low strength and relatively soft metal such as pot metal can be readily deburred in -30 minutes and burnished in minutes to one hour, whereas a part of tempered chrome steel which is highly ductile, high strength and extremely hard may require from 8 to 24 hours to deburr and an equally long time to burnish or polish.

It is also generally recognized in the art that the longer a' metallic part is tumbled the greater is the loss of metallic color or luster. This phenomenon is attributed to a number of factors including corrosion of the metal, hard water salt deposition, deposition from impurities in the tumbling media itself, and a number of other reasons.

It is also known that certain types of tumbling media, particularly porous abrasive used for deburring or grinding will tend to load up; that is, the pores become filled with small metallic particles which are removed from the metallic object being tumbled. In this instance, when an abrasive media has been used to grind or deburr brass, small particles of brass become deposited in the pores of the abrasive and the abrasive cannot be subsequently used on alloys such as aluminum, zinc or iron as the copper in the brass tends to be dissolved by chemicals present'in the aqueous solution and redeposit on the above mentioned alloy, thereby causing unsightly appearing work and a poor base for plating or painting.

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It is the object of my invention to overcome all of the aforementioned difiiculties and provide a process and the equipment used therein which will greatly reduce the time necessary to produce comparable results now obtained with conventional equipment.

It is a further object to provide a process and the equipment used therewith, that is effective in cleaning media such as porous abrasive material, by removing the foreign matter from the media.

It is a further object of the invention to provide equipment that will produce a rapid and efficient method of cleaning the parts to be tumbled as well as cleaning all media of soil, hard water salt deposition and other soils.

I have found that when ultrasonic energy is applied to tumbling operation, which tumbling operation consist-s of treating parts, or parts and media, contained in a liquid such as water or an organic solvent, that a much more efficient operation results both from the standpoint of quality and time.

It has long been known that ultrasonic energy, that is, compressional waver of the sound type but of frequencies above audible sound and generally considered to be of the ranges of 10,000 to 400,000 cycles per second, are very effective in cleaning of metal parts in water or solvent systems; it has not been known, however, that the addition of ultrasonic energy to implement tumbling operations would produce any outstanding results. I have found, however, that the time required to produce deburring or burnishing of a specific metallic part can be reduced as much as 70% when ultrasonic energy is applied to the tumbling media.

The invention further resides in certain novel features of the combination of ultrasonic generating equipment and tumbling equipment, and further objects and advanatges thereof will be apparent to those skilled in the art of which the invention pertains from the following description of the presently preferred embodiment of the invention, and certain modifications thereof, taken in conjunction wtih the accompanying drawings, forming apart of this application, in which:

FIGURE 1 is a front view of a tumbling barrel to which has been attached an ultrasonic generator and associated equipment for producing ultrasonic energy within the barrel.

FIGURE 2 is a side view of FIGURE 1, ultrasonic generation and attached wiring.

FIGURE 3 is a cross section taken along line 1-1 of FIGURE 1.

FIGURE 4 is a view of the rotary switch for transferring the electric currents from the stationary ultrasonic generator to the rotary barrel.

FIGURE 5 is a cross sectional view along line 3-3 of FIGURE 4.

A shown in FIGURES 1 and 2, a hexagonal tumbling barrel 11 is mounted on legs 12 by means of an axle 13 riding in a bearing housing 14. The barrel is driven in a rotary manner by means of sheave 15 which is attached to axle 13 and driven by means of belt 16 which is in turn driven by motor 17. On one of the hexagonal faces of the barrel, a removable water tight door 18 is mounted for ingress and egress to and from the barrel. Fixably mounted on the legs 12 is an ultrasonic generator 19 of the electronic type which is connected electrically to a rotating switch 20 by means of a coaxial cable 21. After passing through the switch 20, the ultrasonic electrical showing the energy is fed to the various internally mounted vibration side. The barrel is lined with a resilient material 24, the resilient material is usually rubber such as neoprene but may be of any other type rubber or plastic suitable for the purpose. Mounted in the rubber or covered with a suitable plastic or rubber material to prevent wear and shock, is an ultrasonic generating head 47 such as a barium titanate crystal or a magnetostrictive device which is supplied with ultrasonic frequency electrical energy through coaxial cables 22. Contained in the barrel is deburring aggregate 27 shown in its approximating angle of inclination resulting from the rotation of the barrel in the counter-clockwise direction. It will be noted that the aggregate will at all times cover at least one of the three ultrasonic generator heads 47.

As the barrel is rotated in the counter-clockwise direction, the aggregate 27 tends to pile up on the side of the barrel until the plane surface of the aggregate reaches an angle of incline which exceeds the critical angle and the aggregate at the top of the incline tends to roll down the slope such that as the barrel 11 is rotated, the angle of slope of the aggregate remains constant at its critical angle; to maintain this critical angle, the top surface of the aggregate must be continually in motion; which motion of aggregate over itself causes the actual deburring or finishing of the part contained in the aggregate 27.

As shown in FIGURES 4 and 5, the rotary switch is fixably attached to the axle 13. The switch is con structed of two split ring concentric conductors, with outer split ring and inner split ring 41; the inner split ring 41 is electrically insulated from the axle 13 by means of insulation 45 and the outer split ring 40 is electrically insulated from the inner split ring 41 by means of electrical insulation 45a. Each of the split ring conductors 40 and 41 consist of three individual segments, which segments are electrically insulated from each other by means of electrical insulation 42. The three pairs of segments of the outer and inner concentric split rings 40 and 41 respectively are connected to the ultrasonic generator heads in the barrel 11 by means of coaxial cables 22 which are constructed of an outer shield conductor 43 and an inner conductor 44.

The ultrasonic electrical energy from the ultrasonic electrical generator 19 is fed to the rotary switch 20 by means of coaxial cable 21 which is constructed with an internal conductor 48 and an external shield conductor 49. The internal conductor 48 is attached to a brush and the external shield conductor 49 is attached to brush 51. The brushes 50 and 51 are pressed against the surfaces of the rotary switch by means of positive pressure exerted by means of helical springs 53 and 52 respectively. It is the principle of operation that electrical ultrasonic energy is generated by the generator 19 which energy is fed up through coaxial cable 21 and to the brushes 52 and and 53; which ride on the surface of the concentric split ring conductor 40 and 41 and thereby pass electrical energy from the brushes 52 and 53 to one pair of segments of the split ring conductors, which pair of segments is electrically connected to one of the ultrasonic generating heads 47 located in the barrel 11 by means of coaxial cable 22 which is fixably connected to the pair of conductors. The brushes 50 and 51 are so positioned with relationship to the barrel 11 that only the ultrasonic generator head 47 which is nearest the bottom of the barrel 11 during the revolution thereof is activated. The ultrasonic generating head 47, in this bottom position is therefore always adjacent to the aggregate 27 and as the ultrasonic generator head 47 is excited by an ultrasonic electrical current from ultrasonic electrical generator 19, compressional ultrasonic Waves are created within the body of the aggregate 27 and the fluid surrounding it.

on the. inside of an hexagonal tumbling barrel and imbedded in the rubber lining thereof so that the surface t 4 a of the plastic was flush with the inside surface of the rubber lining. The crystal was activated with a 40,000 cycle per second electrical impulse operated with maximum pulse power of approximately 2 kilowatts. The barrel was charged to about one half full with fused aluminum oxide chips; one hundred zinc die cast desk drawer knobs were placed in the barrel; about two ounces per gallon of water treating and inhibiting compound composed of sodium tripolyphosphate 20%, borax 70%, sodium chromate 5%, non-ionic wetting agent 5% was added and water was added to fill the barrel to about one inch below the top of the chips; the barrel was then rotated at 25 revolutions per minute and inspection of the parts was made every minute to determine when the deburring was completed. It was found that nine minutes was required to completely remove the flashing from the parts employing this procedure. When identical parts were treated in the same manner without the use of ultrasonic energy, fifteen minutes were required to produce a comparable result in removal of the flashing from the part. Therefore the time reduction in this operation was 40%. It was also observed that the part produced by conventional procedures without ultrasonic energy was much darker in color, in other words, had much less metallic lustre, than the part produced in nine minutes employing ultrasonic energy.

Example B The deburred parts of Example A were then burnished in the same barrel. The barrel was charged to approximately one half full with steel burnishing balls, burnishing compound composed of coconut oil soap 98% sodium salt of ethylene diamine tetrasetic acid 2%, was added in a quantity of one ounce per gallon of water; water was then added to the barrel in an amount to just cover the burnishing balls; the parts were then added to the barrel; the barrel was then rotated at a speed of 35 revolutions per minute and the parts inspected for lustreevery minute. With conventional procedures, the parts were burnished to a high lustre in 35 minutes. The test was then repeated using the same ultrasonic energy sound as discussed in Example A above. It was found that at the end of 12 minutes the parts had achieved a lustre comparable to that achieved in 35 minutes with conventional procedures and in addition the metallic color of the parts produced using ultrasonic energy was much superior.

Example "C The same barrel as Example A was then used for deburring of a brass washer that had been stamped from sheet stock. The charge was identical to that used in Example A but new aluminum oxide chips were employed. It was found that the brass Washers were deburred in 45 minutes using conventional methods but only 27 minutes was required to produce comparable results when ultrasonic energy was used. It was also observed that when conventional methods were employed, the aluminum oxide chips loaded up with brass chips to a much greater extent than when ultrasonic energy was employed.

Example D" When the chips used by the conventional method of Example C above were placed in the barrel, the barrel filled with water sufiicient to just cover the chips and a burnishing compound composed of coconut oil soap 98% and sodium salt of ethylene diamine tetracetic acid 2% was added to the extent of one ounce per gallon of solution and the barrel rotated at 25 revolutions per minute for a period of 10 minutes employing the ultrasonic energy, the chips were then washed with water and were found to be relatively free of brass chips and the suds produced by the soap and water contained visable chips of brass which had been removed from the aluminum oxide chips and were suspended in the foam.

Example E A batch of polished steel burnishing balls were specifically contaminated with a tarry mixture of coal-tar nitrogen bases. One-half of the balls were then introduced into a tumbling barrel and one-half of the zinc die cast desk drawer knobs of Example B were introduced together with water and 2 oz./gal. of burnishing soap. It was found that at the end of 35 minutes, the parts were very smooth but had acquired a very dark color which was not acceptable.

The remaining one-half of the tar treated balls was then charged into the machine together with the remaining one-half of the zinc die cast desk drawer knobs and water was added to just cover the balls; the deburring compound was then added in a quantity of 2 oz./gal. of water and the ultrasonic energy was applied. At the end of 15 minutes rotation of the tumbling barrel at 30 revolutions per minute, it was found the balls were clean and free of tar as evidenced by the water wetability of the balls and the desk drawer knobs were highly burnished with good metallic lustre without darkening.

It is therefore obvious that the use of ultrasonic energy in combination with conventional tumbling procedures produce an unexpected utilitarian result.

Although one modification of the equipment useful in employing the process is graphically described, it will be obvious to those skilled in the art that other and varied combinations will produce similar results and that such other and varied combinations of ultrasonic generators and tumbling equipment are within the spirit of the invention.

What I claim is:

1. Deburring and burnishing apparatus comprising a tumbling barrel mounted for rotation about an essentially horizontal axis, means connected to said barrel for transmitting rotation thereto, a plurality of separate means for converting ultrasonic electrical energy into ultrasonic mechanical energy mounted approximately equidistant from each other in the horizontal surfaces of said barrel and means for cyclically supplying ultrasonic electrical energy to the single one of said separate means which is nearest the bottom of said barrel during revolution thereof.

2. The apparatus of claim 1, wherein the separate means for converting ultrasonic electrical energy into ultrasonic mechanical energy is a magnetostrictive ultrasonic mechanical generator.

3. The apparatus of claim 1, wherein the said separate means for converting ultrasonic electrical energy into ultrasonic mechanical energy is a piezo-electric crystal.

4. In a tumbling barrel consisting of a barrel for retaining aggregate, solution and parts rotated about an axis essentially in a horizontal plane by means of an external mechanical power source, the improvement which comprises an ultrasonic frequency electrical generator, a plurality of ultrasonic mechanical generators mounted approximately equidistantly from each other in the horizontal surfaces of said barrel and means for activating said generators by said ultrasonic electrical generator only when said mechanical generators are in contact with the aggregate and solution contained in the barrel during the rotation thereof.

5. The improved apparatus of claim 4, wherein said mechanical generators are magnetostrictive ultrasonic generators.

6. The improved apparatus of claim 4 wherein the mechanical generators are piezo-electric crystals.

7. The improved apparatus of claim 4 wherein the means for transferring the output current of the electrical generator to said independent mechanical generators comprises a pair of concentric split ring conductors, each of said rings having a plurality of segments of substantially equal length and corresponding in number to the number of said mechanical generators, means for electrically connecting each of said segments to one of said generators disposed on the same side of said barrel as said segment and a pair of brushes electrically connected to said electrical generators and being disposed to contact said conductor rings at the lowermost position thereof.

References Cited in the file of this patent UNITED STATES PATENTS 2,439,156 Castle Apr. 6, 1948 2,476,505 McIntyre July 19, 1949 2,651,148 Carwile Sept. 8, 1953 2,723,386 Camp Nov. 8, 1955 2,796,702 Bodine June 25, 1957 2,809,473 Heaphy Oct. 15, 1957 2,825,186 Palush Mar. 4, 1958

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2439156 *Jan 12, 1946Apr 6, 1948Sturgis Products CompanyMethod of tumbling barrel finishing and material and production thereof
US2476505 *Oct 1, 1945Jul 19, 1949Wilkinson Rubber Linatex LtdLining for ball mills
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Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3118253 *Jul 18, 1961Jan 21, 1964 Bowl for vibratory machine
US3129536 *May 4, 1961Apr 21, 1964Link Belt CoRotary tumbler
US3148485 *Apr 12, 1961Sep 15, 1964Garvey Thomas GApparatus for finishing metal parts
US3157004 *May 18, 1960Nov 17, 1964Chain Belt CoTiltable vibrating burnishing machine
US3259272 *Jun 19, 1964Jul 5, 1966Korad CorpMethod and apparatus for dispensing powder
US3451375 *Jan 3, 1967Jun 24, 1969A Wander Sa DrRotating drum coating apparatus
US3533928 *Apr 21, 1969Oct 13, 1970Inoue KMethod of and apparatus for the deburring of workpieces
US3535159 *Dec 7, 1967Oct 20, 1970Branson InstrMethod and apparatus for applying ultrasonic energy to a workpiece
US3596406 *Oct 15, 1968Aug 3, 1971Shell Oil CoSonic polishing apparatus
US3979858 *Jul 24, 1975Sep 14, 1976International Lead Zinc Research Organization, Inc.Chemically accelerated metal finishing process
US4122602 *Jun 3, 1977Oct 31, 1978The Gillette CompanyProcesses for treating cutting edges
US4122603 *Jun 3, 1977Oct 31, 1978The Gillette CompanyProcesses for treating cutting edges
US4835911 *Dec 24, 1987Jun 6, 1989The Abbott Ball CompanyMethods of making steel abrading elements for mass finishing of workpieces and for using same
US4909266 *Mar 10, 1989Mar 20, 1990Frank MassaUltrasonic cleaning system
US5447465 *Aug 19, 1993Sep 5, 1995United States Surgical CorporationMethod of treating needle blanks
US5829131 *Nov 21, 1997Nov 3, 1998Chrysler CorporationMethod of making camshaft lobes
US5997383 *Apr 16, 1998Dec 7, 1999Tseng; Shao-ChienIsostatic pressure plastic grinding method
US6193410Dec 16, 1998Feb 27, 2001Puckett, Ii Robert A.Method for agitating the liquid contents of paint balls
US6206755Oct 19, 1994Mar 27, 2001United States Surgical CorporationMethod and apparatus for making blunt needles
US6280080Sep 22, 2000Aug 28, 2001Puckett, Ii Robert A.Method for agitating the liquid contents of paint balls
Classifications
U.S. Classification451/328, 451/35, 68/3.00R, 451/34, 451/113, 422/128, 366/220, 451/37
International ClassificationB24B31/027, B24B31/00
Cooperative ClassificationB24B31/027
European ClassificationB24B31/027