US3855441A

US3855441A - Method and apparatus for activation of an abrasive slurry by an electric arc

Info

Publication number: US3855441A
Application number: US00459080A
Authority: US
Inventors: C Kimmelmann
Original assignee: Individual
Current assignee: Individual
Priority date: 1974-04-08
Filing date: 1974-04-08
Publication date: 1974-12-17
Anticipated expiration: 1991-12-17
Also published as: DE2515243A1

Abstract

The method of reducing the surface of a body by applying an abrasive slurry to the portion of the surface of the body to be reduced and forming successive electric arcs at the portion of the surface to be reduced, to drive the abrasive slurry away from the portion and allow it to return to the portion in the interval between the successive arcs. The apparatus for reducing the surface of a body wherein an abrasive slurry is maintained on the portion of the surface of the body to be reduced, and electric arcs are formed successively at the portion of the body to be reduced, whereby the slurry is driven away from the portion and returned and replenished between successive arcs.

Description

United States Patent [1 1 BY AN ELECTRIC ARC [75] Inventor: Carl E. Kimmelmann, White Twp.,

Warren County, NJ.

[73] Assignee: David B. Braelow, West Orange,

NJ. a part interest [22] Filed: Apr. 8, 1974 [21] Appl. No.: 459,080

[52] US. Cl 219/68, .51/7, 51/26, 51/317, 2'19/76 [51] Int. Cl B23p l/00 [58] Field of Search 51/7, 26, 31 7; 219/68, 219/76 [56] References Cited UNITED'STATES PATENTS 2,850,854 9/1958 Levy 51/317 2,974,215 3/1961 lnoue 219/68 3,277,267 10/1966 Blaszkowski 219/76 3,338,808 8/1967 Johnson..' 219/68 X Kimmelmann Dec. 17, 1974 [54] METHOD AND APPARATUS FOR 3,423,880 1/1969 Hersliler .1. 51/7 ACTIVATION OF AN ABRASIVE SLURRY 3,523,834 8/1970 Hewms 219/68 X Primary Examiner-.1. V. Truhe Assistant ExaminerN. D. Herkamp Attorney, Agent, or Firm-Popper, Bain, Bobis, Gilfillan & Rhodes 57 ABSTRACT The apparatus for reducing the surface of a body wherein an abrasive slurry is maintained on the portion of the surface of the body to be reduced, and electric arcs are formed successively at the portion of the body to be reduced, whereby the slurry is driven away from the portion and returned and replenished between successive arcs.

16 Claims, 5 Drawing Figures .AN ABRASIVE SLURRY BY AN ELECTRIC ARC BACKGROUND OF INVENTION 1 Field of Invention r This invention relates generally to the reduction of surfaces by abrasive slurries, and particularly to methods and apparatus wherein the abrasive slurry is activated by successive electrical arcs.

2. Description of Prior Art The reduction of surfaces by electric arcs through the use of what is generally referred to as an electrodischarge machine (E.D.M.) is a well-known apparatus for conducting a well-known procedure wherein an are between a conductive workpiece and an electrode or between two electrodes disposed closely adjacent-to a surface to be reduced, willvaporize a portion of the surface, or will break a portion of the surface into small fragments. The result of practicing this method will reduce the surface but may cause an undesireable pitted surface. The material whose surface is reduced may be damaged by the heat of the arc, and will show'cracks in microphotographs. Moreover, the surface may be overheated and lose as much as approximately 30 percent of its normal tensile strength. If holes are made by this electro-discharge method, they may have a rather coarse, mottled appearance due to the presence of numerous craters and cracks. The reduction of surfaces by electro-discharges is believed to be due in part to shock waves generated by the are. In addition, the material of the surface may be heated and vaporized. Exotic materials may be severely impaired for they may melt under the heat of the arc, or microcracks may be formed.

If the reductionof surfacesby electro-discharge machine is undersireable because of the harmful side effectsreferred to, another methodsuch as drilling with a bit may be resorted to. This procedure has its disadvantages because a hard steel bit used to make a hole 0.0015 inch in diameter is usually subject to frequent breaking of the bit. Not only is'this a problem but re-. traction of the brokenpiece of the bit from the hole drilled may prove difficult;-besides, the bit'very quickly los'es its sharpness. If the workpiece is of hi-chrome steel, hi-nickel steel'especially tempered steel, or tungsten-carbidesteel, the drilling may be even moredifficult.

Even when conventional methods are used to reduce surfaces, the control of the size within acceptable tolerances is quite difficult and machine marks impair the smoothness of the surface of the workpiece so that a smooth finish is not obtained or must be obtained by separate procedures.

The application of an abrasive slurry to the drilling site does very little to improve the action of the bit.

SUMMARY OFlNVENTlON It has been found that activating an abrasive slurry at the point or reduction by the application of an electric arc, can accomplish a rapid reduction of the surface, and produce a smooth, unpitted surface, without impairing the workpiece, by cracking or pitting it. The slurry is formed of a dielectric liquid medium carrying abrasive particles, and is maintained at the site where the surface of the workpiece is to be reduced. The passage of an electric arc between an electrode and the workpiece (if the workpiece is electrically conductive) or between two electrodes adjacent to the portion of the workpiece to be reduced, causes a disturbance in the abrasive slurry at the point of the arc where the surface reduction is desired to be accomplished. In so doing the slurry is moved aside to permit the formation of an are when the electric potential overcomes the resistance of the slurry. In so moving, the abrasive particles in the slurry are carried with the slurry displaced by the arc, thereby moving to abrade the surface. Upon the cessation of the arc, the next arc is in a different position and the abrasive slurry will be displaced at that new location. It is believed that the particles may be moved by ultrasonic shock wave through the slurry and pressed against the surface. It is also believed that spatial displacement of the slurry by the arc is also accomplished. It is further believedthat the arc may vaporize a portion of the surface to be reduced, perhaps softening it so that it yields more readily to the abrasives in the slurry. In any event, the surface is reduced with little or no evidence of pitting or cracking, and a relatively smooth area results.

An apparatus for producing a smooth bore in a workpiece involves the pumping of the abrasive slurry into the bore of the workpiece. When the workpiece-is revolved and reciprocated an electrode intruded into the bore is energized with the workpiece so that electric arcs are successively formed between the workpiece and the electrode. A mirror-like bore is produced in the workpiece, generally devoid of any pits or cracks.

THE DRAWING workpiece at a point wherean abrasive slurry is applied;

FIG. 2 is an enlarged partial sectional view of'the workpiece and the electrode shown in FIG. '1;

FIG. 3 is circuit diagram of the apparatus for producingthearc;

FIG. 4 is a view of a modification of the apparatus which forms successive electric arcs between an electrode positioned adjacent to the surface 'of a flat conductive workpiece whose surface is to be reduced, and

FIG. 5 is a view of a modification of the apparatus which forms successive electric arcs between two electrodes disposed adjacent to the surface of a flat dielectric workpiece whose surface is to be reduced.

PREFERRED EMBODIMENT Referring now to the drawings in detail, an abrasive slurry 11 is prepared from a dielectric liquid such as an oil having no flash point or a very high flash point. Ultrapure water may be'used as the dielectric vehicle for the liquid slurry, but it soon loses its dielectric character. Once it becomes electrically conductive, it inhibits the arc formation by reason of condition of the electric impulses. It must then be replaced. On the other, oil is not readily rendered electrically conductive. Particles of garnet, sand, orpumice are mixed with the liquid.

The particles are preferably uniformly graded. Lanthanum or cerrium oxide, diamond dust or other well known standard abrasives may be used. The ratio of the liquid to the abrasive is preferably 1:10, but this ratio may be varied, depending upon the character of the workpiece, character of the abrasive, and the speed of reduction desired. A few simple tests will readily determine a proper ratio of liquid to abrasive, dependent upon the nature of the abrasives and the nature of the workpiece. The abrasive particles in the slurry may be in the range of 500 to 1,000 grit, again dependent upon the fineness of the finish desired, the character of the workpiece, and the character of the abrasive.

. It may be necessary to use initially a rather coarse abrasive particle in the slurry to accomplish the rapid reduction of the surface, and later to finish off with a fine abrasive, in order to obtain the ultimate smooth finish.

The slurry is deposited in a tank l2'provided with an agitator 13, driven by a motor 14. This insures the homogeneous character of the slurry-abrasive mixture. A conduit carries the slurry to a nozzle 16 from which it is discharged intothe bore 17 of a workpiece 18. The gravitational discharge of the slurry 11 from the nozzle 16 may be sufficient, but a pump may be added to accomplish the forceable discharge of the slurry 11. The

workpiece 18 is held in a collet 19, mounted on a rotatable shaft 20. The shaft .20 is mounted for rotation on bearings 21. A pulley 22 on the shaft rotates it. An eccentric cam 23 will reciprocate the shaft 20, and overcome a spring 24 causing the shaft to reciprocate as it revolves.

An electrode 25 is mounted at an angle of at least l to the bore 17 in the workpiece 18. This insures the generation of an arc generally from the tip of the electrode, rather than from random points thereon. The electrode 25 is held in a collet 26 on the end of a rod 27. The rod 27 is slidably mounted in a support block 28. The end of the rod 27 extends throughthe block and carries a pin 29. A spring 30 is compressed between the block 28'and the pin and normally urges "the electrode collet 26- toward the block 28. A threaded shaft 31 is mounted coaxially with the rod 27; a wheel 32 is mounted on the threaded shaft 31 and enables the advancing and retractingof the electrode 25 to the desired location with respect to the bore 17in the workpiece 18. Thus when thegap between the electrode25 and the workpiece 18 becomes so great as to inhibit arcing the wheel 32 may' be-turned to bring the tip of l the electrode closer to the workpiece 18, so that arcing will proceed uninhibited.

The are generator 10 is of conventional design, power being supplied by either standard direct current (pulse type), or rectifier-capacitor type. The conventional rectifier-capacitor type power supply is preferred but it should be modulated by a choke. A suitable arc generator circuit is shown in FIG. 3. A voltage regular 33 provides suitable gap voltage to an isolation transformer 34. The secondary 35 of the transformer 34 is connected to a rectifier 36. The output of the rectifier is conducted to a group of capacitors 37 connected in parallel. Switches 38 can selectively connect the capacitors into the circuit, depending upon the are potential desired. The capacitors 37 may be in the range of 0.1 to 10 mfd. An indicator light 39 controlled by the across the choke coil 42. When this switch 44 is open, the arc will have its energy drastically reduced so that the possibility of cracking, burning, pitting, or melting at the point of discharge is eliminated. A voltmeter 45 is indicated to measure the arc potential at discharge, so that if the voltage reaches so high a level that there is danger of cracking, etc., the voltage of the discharge may be reduced. It has been found that an arc discharge in the range of 100-400 V. will generally have no undesired effect in the workpiece. However, the arc voltage may be varied within wide limits depending upon the dielectric valve of the slurry, the gap distance,

the material of the workpiece. None of these parame-' ters can be predetermined but must be worked out by trail under the circumstances of operation, with due regard to the nature of the slurry, the gap distance, and the material of the workpiece.

Electrical energy is stored in the capacitors 37 over a relatively short period of time and is discharged with sudden violence at the instant switch 9 is effectively closed. The switch 9 may be mechanically operated or may be an electronic device.

Many designs of arc generators, gaps and switches may be devised for different applications. The operating capacities and voltages may be varied widely but it is found that 60 to 400 volts with 0.001 microfarad across choke coil is acceptable. The circuit produced a spark sufficiently'intense and of sufficiently short a duration so that it may activate the slurry as required.

A trigger circuit of conventional design may be used.

rate of up to l00,000pulses per second. The are will displace the dielectric slurry in its path, moving the abrasive particle against the bore 17, causing it to be reduced smoothlywithout pitting and forming a slick surface. A continuous discharge of the slurry 11 into switch 40 denotes the charging condition of the capacitors 37. The capacitors 37 discharge to the gap. One side of the discharge circuit is modulated by the variable resistance 41 which is connected to the choke coil 42. A capacitor 43, may be connected by the switch 44 the bore 17 provides abrasive particlesto erode theboreas the workpiece reciprocates over the electrode and as the workpiece revolves continuously. v

This process can also be applied to reduce not only interior but exterior surfaces, such as cylindrical or flat shapes, as well as spherical, conical or threedimensional curved surfaces", in such cases, the electrode, instead of being inserted'into a cavity in the workpiece, is positioned instead adjacent to the exterior surface of the workpiece. Where flat surfaces are reduced, the rotation of the pulley 22 is not required,

but only the reciprocation of the collet 19 is required, by the continuous operation of the cam 23. When the workpiece is dielectric material, additional electrodes are provided so that the arc is disposed close to the surface to be reduced.

For reducing flat surfaces, FIG. 4 illustrates a bracket 51 substituted for the collet 19 and the workpiece 52 is bolted or otherwise held in place. The nozzle 16 is directed to apply the abrasive slurry 11 to the flat surface of the workpiece 52. The angle of the electrode 25 is adjusted to approximately 1 with respect to to the workpiece. The pulley 22 is not activated to rotate the workpiece but the cam 23 is driven to reciprocate the flat surface of the workpiece in one plane continuously as the arc activates the slurry flowing over the flat surface of the workpiece 52. A smooth surface is thus created on the flat surface of the workpiece.

In FIG. 5, a dielectric workpiece 53 is attached to the bracket 51. A double, dielectric electrode holder 54 is provided. Two

electrodes

55, 55 are inserted in the electrode holder 54 and each is connected to the arc generator. The two electrodes are adjusted to closely approach thesurface of the workpiece and the abrasive .slurry 11 is fed to the surface of the workpiece 53. The

pulley 22 is not activated, but the cam 23 is driven to reciprocate the flat surface of the dielectric workpiece 53. The are formed between the two

electrodes

55, 55 is sufficiently close as to activate the abrasive slurry at the surface of the dielectric workpiece 53, and to reduce and polish the surface thereof.

What is claimed:

l. A method for reducing a surface of a workpiece comprising:

a. supplying a dielectric, abrasive slurry to a portion of a workpiece to be reduced;

b. generating successive electric arcs in the slurry to move it at the portion of the workpiece to be reduced;

c. reducing the surface of the workpiece by the movement of the abrasive slurry.

2. The method of claim 1 in which the electric arc is formed between an electrode and an electrically conductive workpiece.

3. The method of claim 1 in which the electric arc is formed between two electrodes immediately adjacent to the workpiece.

4. The method of claim 1 in which the slurry is oil and abrasive material. r

5. The method of claim 1 in which the slurry is water and abrasive material.

6. The method of claim 1 in which the electric arcs are formed between the workpiece and electrode disposed in nonparallel relation to the workpiece surface.

7. The method of claim 1 in which the workpiece is rotated with respect to the electrode.

8. The method of claim 1 in which the workpiece is reciprocated with respect to the electrode.

9. The method of claim 1 in which the workpiece is reciprocated and rotated with respect to the electrode.

10. A method for reducing a surface of a workpiece comprising:

a. supplying a dielectric, abrasive slurry to a portion of a workpiece;

b. positioning an electrode in the slurry in spaced relation to the workpiece;

c. generating successive arcs in the abrasive slurry between the electrode and the workpiece.

11. An apparatus for reducing the surface of a workpiece comprising:

a. a means to hold a workpiece;

b. an electrode disposed angularly in spaced relation to the workpiece;

c. an abrasive slurry in the space between the electrode and the workpiece;

d. a means to generate successively electric arcs between the electrode and the workpiece, in the slurry.

12. An apparatus according to claim 1] and a means to reciprocate the workpiece.

13. An apparatus according to claim 11 and a means to rotate the workpiece.

14. An apparatus according to claim ll and a means to adjust the space between the electrode and the workpiece.

15. An apparatus according to claim 11 and a means to reciprocate and rotate the workpiece.

16. An apparatus for reducing the surface of a workpiece comprising:

a. a means to hold a workpiece;

b. a pair of electrodes disposed in close proximity to the surface of the workpiece;

c. an abrasive slurry in the space between the electrodes and the workpiece; (1. means to generate successive electric arcs between piece. I

Claims

1. A method for reDucing a surface of a workpiece comprising: a. supplying a dielectric, abrasive slurry to a portion of a workpiece to be reduced; b. generating successive electric arcs in the slurry to move it at the portion of the workpiece to be reduced; c. reducing the surface of the workpiece by the movement of the abrasive slurry.

4. The method of claim 1 in which the slurry is oil and abrasive material.

5. The method of claim 1 in which the slurry is water and abrasive material.

10. A method for reducing a surface of a workpiece comprising: a. supplying a dielectric, abrasive slurry to a portion of a workpiece; b. positioning an electrode in the slurry in spaced relation to the workpiece; c. generating successive arcs in the abrasive slurry between the electrode and the workpiece.

11. An apparatus for reducing the surface of a workpiece comprising: a. a means to hold a workpiece; b. an electrode disposed angularly in spaced relation to the workpiece; c. an abrasive slurry in the space between the electrode and the workpiece; d. a means to generate successively electric arcs between the electrode and the workpiece, in the slurry.

12. An apparatus according to claim 11 and a means to reciprocate the workpiece.

13. An apparatus according to claim 11 and a means to rotate the workpiece.

14. An apparatus according to claim 11 and a means to adjust the space between the electrode and the workpiece.

16. An apparatus for reducing the surface of a workpiece comprising: a. a means to hold a workpiece; b. a pair of electrodes disposed in close proximity to the surface of the workpiece; c. an abrasive slurry in the space between the electrodes and the workpiece; d. means to generate successive electric arcs between the electrodes, in the slurry, adjacent to the workpiece.