EDM electrode assembly and method of making and using same

An EDM electrode assembly including an electrode with a relative uniform, other-than-round shape, in cross-section along its entire length is supported within tubing by an epoxy bushing formed completely around an end portion of the electrode on one end of the tubing to slidably support the electrode. An EDM cartridge assembly constructed in accordance with the above further includes an outer tubing and a mechanism for driving the electrode through the bushing. A method for making the EDM electrode assembly as well as a method of refeeding the electrode.

TECHNICAL FIELD 
This invention relates to EDM electrode assemblies and method of making and 
using same and, in particular, to EDM electrode assemblies including an 
electrode having an other-than-round shape and method of making and using 
same. 
BACKGROUND ART 
Instrumentation, air pollution abatement equipment, scientific instruments, 
medical devices such as needles and implants, fuel injection nozzles, 
spinnerettes and gas escapement orifices are some of the products that 
require extremely small holes, including those holes with other-than-round 
shapes. Diesel fuel injectors require holes between 0.005 and 0.010 inches 
in diameter. 
The traditional method of small hole drilling involves a drill bit that is 
subject to easy breakage, and a sensitive drill press in the hands of a 
skilled operator. The cost is usually high with broken drills and scrapped 
parts. If the workpiece is a hardened metal, the problems are compounded. 
Electric discharge machining (EDM) has been employed from time to time in 
the drilling of small diameter holes. EDM has worked to a degree even 
though the results are usually far from optimum since most EDM equipment 
is designed to handle work on a much larger scale. Amperages, spark 
frequencies and overcuts that are ideal for machining a die segment, leave 
much to be desired in the task of drilling a fine, accurate hole with no 
appreciable layer of recast and solidified material on the hole surface. 
EDM, however, still offers numerous advantages in the drilling of small 
diameter holes. One such advantage is that the hardness of the workpiece 
to be drilled is irrelevant as long the material is electrically 
conductive and a spark can be forced to jump from an electrode to the 
workpiece. The rate of metal removal is a function of electrical 
conductivity and thermal characteristics of the workpiece. While extremely 
hard materials sometimes have a higher melting temperature, it is the 
melting temperature, not the hardness, that is the governing factor. 
On the other hand, if the workpiece has no electric conductivity, the EDM 
process cannot be used. However, all metals and metallic alloys are 
electrically conductive to some degree and yield to the controlled cascade 
of sparks. 
Another advantage of the EDM process is that when properly controlled, the 
EDM hole drilling process is very accurate and has a high degree of 
stability. Because there is no direct contact between the electrode and 
the workpiece, there are no mechanical forces of the type found in 
conventional drilling. In small hole work, there is frequently not even a 
flow of dielectric fluid into the gap area to set up mechanical forces. 
The energy utilized in the actual metal removal process is divided into a 
very high frequency sparks which are closely controlled with electronic 
systems now available. 
With the EDM process there is no undue heat generation or any significant 
mechanical forces involved. Consequently, there is no part distortion. As 
a result, extremely thin and/or fragile parts can be successfully drilled 
with the EDM process. 
Also, once the EDM job is set up, it can be completely cycled in an 
automatic fashion. As a result, skilled operators are not required. 
The tool cost per hole is also extremely low. To drill holes under 0.015 
inches in diameter, a tungsten alloy wire electrode which comes in spools 
is used. For sizes over 0.015 inches, straight rods are usually used. By 
way of example, typically hundreds of dollars of tungsten alloy wire will 
furnish enough electrode material to drill millions of holes in diesel 
fuel injector nozzles. 
Still another advantage of the EDM process is the ability to vary the hole 
diameter within a limited range by simply changing current parameters 
without changing the electrode itself. By contrast, the diameter of 
mechanically drilled holes is determined by the diameter of the cutting 
tool. In order to resize the holes the size of the tool must be changed or 
a secondary operation must be performed. In EDM there is always an overcut 
comprising the spark gap between the electrode and the workpiece. The gap 
is a direct function of current flow and the frequency with which it is 
applied. In particular, the higher the current flow or the lower the 
frequency of sparking, the greater the gap. On normal EDM work, the gap 
may be anywhere from 0.0001 to 0.0003 inches on a side. Thus, in hole 
drilling work, the hole diameter is always larger than the tool itself. In 
small hole work the overcut is relatively small, but it can be closely 
controlled. 
There are no burrs on the holes produced by the EDM process. Metal is 
eroded away in very minute globules to leave a non-directional type of 
surface finish. In the amperage and frequency ranges utilized in small 
hole EDM drilling, a recast surface is virtually non-existent. 
The EDM process is also particularly susceptible to the use of the multiple 
lead principle to drill a number of holes simultaneously. While there are 
certain limitations that come about from the shape of the workpiece, the 
distance between the centers of holes and so on, the EDM process saves 
time. 
In general, the EDM process affects many areas of cost saving, including 
direct tool cost and net machining time by a reduction of workpiece loss 
due to drill breakage. 
Designers have discovered that better gas mixtures will be developed in 
certain instances where the orifices are made in other-than-round shapes. 
The common household gas range seems to give a better gas/air mixture if 
the gases are passed through a rectangular burner portion. Rectangular 
electrode materials can be utilized in EDM hole drilling units to generate 
"other-than-round" holes in workpieces. The same technique can be used to 
generate a "star" or other unusual hole shape if an electrode with the 
desired shape could be developed and utilized in a simple, yet 
cost-effective manner. 
One method currently being used is to solder or otherwise fixedly attach an 
other-than-round electrode at one end of a round elongated shaft. However, 
this approach has many drawbacks, including the drawback of having to 
frequently change the electrode during the hole-forming process. 
DISCLOSURE OF THE INVENTION 
An object of the present invention is to provide an electrode assembly and 
method of making and using same wherein the assembly includes an elongated 
electrode having a relatively uniform, other-than-round shape is 
cross-section along its entire length and wherein the electrode is 
supported within tubing by a bushing formed completely around the end 
portion of the electrode on one end of the tubing, so that the electrode 
is slidably supported by the bushing. 
Yet another object of the present invention is to provide an EDM electrode 
assembly and method of making and using same wherein the electrode has a 
relatively uniform, other-than-round shape in cross-section along its 
entire length and which is supported within tubing having an inner 
diameter slightly greater than the diameter of the smallest circle 
enveloping all of the points of the cross-sectional shape, and wherein a 
bushing is completely formed around the end portion of the electrode on 
the one end of the tubing so that the electrode is slidably supported by 
the bushing. 
In carrying out the above objects and other objects of the present 
invention, a method of making an EDM electrode assembly including an 
elongated electrode having a relatively uniform, other-than-round shape in 
cross-section along its entire length includes the step of supporting the 
electrode in tubing having an inner diameter slightly greater than the 
diameter of the smallest circle enveloping all the points of the 
cross-sectional shapes so that an end portion of the electrode extends 
beyond one end of the tubing. The method also includes the step of forming 
a bushing completely around the end portion of the electrode on the one 
end of the tubing so that the electrode is slidably supported by the 
bushing. 
Further in carrying out the above objects and other objects of the present 
invention, a method is provided for refeeding an elongated EDM electrode 
having a relatively uniform other-than-round shape in cross-section along 
its entire length through tubing having an inner diameter greater than the 
diameter of a circle enveloping all of the points of the cross-sectional 
shape. The method comprises the step of supporting a rod in the tubing so 
that the rod is aligned with the electrode and in engagement therewith at 
one end thereof. The method also includes the steps of driving the rod 
against the electrode so as to move the electrode along its longitudinal 
length and guiding the electrode at the one end of the tubing during the 
step of driving. 
An EDM electrode assembly constructed in accordance with the present 
invention includes an electrode having a relatively uniform, 
other-than-round shape in cross-section along its entire length. The 
assembly also includes tubing having an inner diameter greater than the 
diameter of the circle enveloping all of the points of the cross-sectional 
shape so that the electrode is supported within the tubing and so that an 
end portion of the electrode extends beyond one end of the tubing. A 
bushing is formed completely around the end portion of the electrode on 
the one end of the tubing to slidably support the electrode. 
An EDM cartridge assembly constructed in accordance with the above includes 
such an electrode assembly and outer tubing which supports the tubing 
therewith. Means are also provided for driving the electrode through the 
bushing. 
The advantages of such assemblies and method of making and using same are 
numerous. For example, the cross-sectional shape of the electrode can 
assume a number of different configurations. Also, the electrode can be 
extruded in a continuous fashion to lower the costs associated with the 
electrode. 
The objects, features and advantages of the present invention are readily 
apparent from the following description of the best mode for carrying out 
the invention taken in connection with the accompanying drawings.

BEST MODE FOR CARRYING OUT THE INVENTION 
Referring now to the drawings, there is illustrated in FIGS. 1 and 2, a 
refeed cartridge assembly, collectively indicated at 10, for refeeding an 
other-than-round electrode. The refeed cartridge assembly 10 includes an 
inner electrode assembly, generally indicated at 12 in FIGS. 4 and 5. The 
electrode assembly 12 includes an extruded, other-than-round electrode, 
examples of which are shown in FIG. 3 such as a star-shaped electrode, 
generally indicated at 14, a Y-shaped electrode 16, a T-shaped electrode 
18 and a triangular electrode 20. Preferably, the electrode 14 is 
supported within a length of hypodermic stainless steel tubing 22 having 
an inner diameter approximately 0.001 inches larger than the minimum 
circle enveloping all the points of the extruded electrode 14. An epoxy 
bushing 24 is formed around an end portion 26 of the electrode 14 and on 
one end of the tubing 22 so as to slidably support the electrode 14 on the 
tubing 22. 
The epoxy bushing 24 is formed by first dipping an end portion 26 of the 
electrode 14 in a release agent such as silicon. Excess release agent is 
removed and the remaining release agent is allowed to dry. Then the epoxy 
is placed around the electrode 14 and the tubing 22 and allowed to dry. 
The release agent allows the electrode 14 to be slidably supported within 
the epoxy bushing 24. 
When an electrode assembly has to be changed after machining a number of 
holes in a workpiece, it is of utmost importance that the replacement 
electrode assembly be placed in exactly the same center and in the same 
angular position as the original electrode assembly. In order to 
facilitate this and for the purposes of illustration, the electrode 
assembly 12 is positioned and supported within outer tubing 28 as shown in 
FIG. 5. The outer tubing 28 is secured to the inner tubing 22 by four set 
screws (not shown) at two spaced-apart locations 30 and 32. 
In order to center the electrode 14 and the tubing 22 within the outer 
tubing 28, centering apparatus, generally indicated at 34 in FIG. 6 is 
utilized. The centering apparatus 34 includes a dovetailed, internally 
apertured mini block 36 which has a built-in hydraulic clamp holder for 
holding the outer tubing 28. The mini block 36 is mounted on a dovetailed 
tooling base 38 which also supports a second mini block 40 which, in turn, 
supports, a centering microscope 42. Each of the mini blocks 36 and 40, 
the tool base 38 and the centering microscope 42 are commercially 
available from the System 3-R Corporation located in Sweden. 
The set screws on the outer tubing 28 are adjusted by watching the 
cross-hairs and concentric circles in the microscope 42 until the 
electrode 14 is centered. The outer tubing 28 is then rotated until the 
reference points on the electrode 14 line up with the cross-hairs. A pin 
44 on a pin ring 46 mounted on the outer tubing 28 is then rotated to a 
pin 48 on the mini block 36 and thereafter the pin ring 46 is fastened to 
the outer tubing 28 by a set screw (not shown) at location 50. The mini 
block 56 and the outer tubing 28 are thereafter removed from the tooling 
base 38 to form part of the refeed cartridge assembly 10 as shown in FIG. 
1. The dovetailed mini block 36 allows the entire cartridge assembly 10 to 
be received and retained on a servo slide mechanism (not shown) having a 
male dovetail. 
The outer tubing 28 is centered within tubing 52 of the cartridge assembly 
10 by set screws 54. In turn, the tubing 54 is connected to an 
internally-apertured U-shaped block 56. The outer tubing 22 extends 
through the tubing 54 into one leg of the U-shaped block 56. A push rod 58 
extends into the outer tubing 22 and in driving engagement with the 
opposite end of the electrode 14. 
The push rod 58 is driven by a DC motor 60 through a gear reducer 62 to 
drive a friction wheel 64 mounted on the drive shaft of the gear reducer 
62. The push rod 58 is driven between the friction wheel 64 and an idler 
wheel 66 rotatably mounted on a block 68 pivotally mounted on the base of 
the U-shaped member 56 at one end thereof. At the opposite end of the 
block 68, the block 68 is resiliently urged towards a shaft 70 extending 
upwardly from the base of the U-shaped member 56 by an O-ring 72 which 
acts as a spring. In this way, only the push rod 58 is directly driven. 
The advantages of the above-described assemblies and method of making and 
utilizing same are numerous. For example, a wide variety of 
other-than-round electrodes may be utilized to form complex holes. 
The invention has been described in an illustrative manner and it is to be 
understood that the terminology which has been used in intended to be in 
the nature of words of description rather than of limitation. 
Many modifications and variations of the present invention are possible in 
light of the above teachings. It is, therefore, to be understood that 
within the scope of the appended claims, the invention may be practiced 
otherwise than specifically described.