Complete EDM Handbook

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5

About the Authors

The father and son team, Carl, Steve, and Phil Sommer, own and operate

Reliable EDM in Houston, Texas. They specialize in all types of EDM(electrical discharge machining) wire EDM, ram EDM (also known as

plunge, and sinker EDM), and small hole EDM. They are the largest wire

EDM job shop west of the Mississippi River.

Carl Sommer, president, has witnessed firsthand the dramatic changes

in the machining field. In 1949, he started working in a machine shop in

Brooklyn, NY. It was not long before Carl began working as an apprentice

tool and die maker where he learned to make dies with hand files and

filing machine. Then he found a job in precision tool and die shop. The

owner of the precision tool and die shop sold it, and in the new company

Carl gained broad and valuable experience in virtually all areas of

the machining fieldprecision tools and dies, fixtures, and short run

production from such companies as IBM, Gyrodyne, Thikol, FairchildStratus, Remington, and Sikorsky Helicopter. He operated all machines,

worked in the inspection department, and made precision dies where

parts were ground to within .0001 (.0025 mm). (That's less than 1/20th the

thickness of a human hair.) Then Carl became a foreman for a tool and die

and stamping company.

Carl decided to become a New York City high school teacher. So for

most of the 1970s, he worked as a New York City high school teacher in the

industrial arts department. During this time he also conducted extensive

Reliable EDMSpecializes in wire EDM, ram EDM, and small hole EDM


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6Complete EDM Handbook

Compliments of www.ReliableEDM.com

research into the problems facing Americas educational institutions. This

research, as well as proposed solutions, culminated in the writing the book,

Schools in Crisis: Training for Success Or Failure?

Carl moved to Houston, Texas in 1978. The pay was so poor for teachers,

that he re-entered the machine tool industryfirst as a tool and diemaker, then as a tool designer for one of Houstons largest tool and die

and stamping shops. After six months Carl advanced to the position of

operations manager, and for 5 1/2 years managed the entire company. At

this shop the stamping dies were milled or ground. When the company

purchased a wire EDM machine, it revolutionized their tool and die

making. Now the most difficult shapes could be machined accurately into

hardened tool steel.

In 1986, Sommer started Reliable EDM with his two sons. One of the major

needs he saw was that individuals needed to be educated concerning thebenefits of wire EDM, so he sent information to companies describing the

process and the capabilities of wire EDM. Within four years, they became

the largest wire EDM job shop in Texas; within nine years, they became the

largest wire EDM job shop west of the Mississippi River.

In the beginning Carl operated the EDM equipment, and with his

machining background built all sorts of fixtures for the EDM shop. With

his company being profitable, Carl began to follow his dreams of writing

One of Reliable's Wire EDM Departments


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7About the Authors

children's books that would teach children the principles on how they

can become successful. He has written 20 children's books that have won

numerous awards. He is also writing three large literacy programs, Reading

Success, a phonics literature-based reading program for adults, Reading

Adventure, a phonics literature-base reading program for children, andNumber Success, a practical math program from addition to trigonometry

(this math program will be on 47 DVDs). For more information go to www.

advancepublishing.com.

Steve Sommer M.E., vice president, received his mechanical engineering

degree from the University of Houston. When Steve graduated from

college, the oil crisis hit Houston and he couldn't find a job as an engineer.

While going to school he worked as a machinist, so with his machinist

background he found a job working as a tool and die maker. While working

as a tool and die maker, he was asked to run the EDM department. His

experience in engineering, machining, tool and die making, and EDMing

continues to be a valuable asset for Reliable EDM. Steve has a thorough

knowledge of the machining trade, computer programming, and the EDM

process. He has worked over 20 years in programming and operating EDM

equipment.

Phil Sommer, vice president of operations, has a degree in business

administration and heads the EDM operations. He also has extensive EDM

experience. Phil has years of experience in running an EDM shop and

dealing with customers.

The family team built their business on following the

Golden Rule of doing to others what one would like

being done to them. Following the Golden Rule and the

exceptional experiences of this father-and-son team are

the major reasons for Reliables remarkable growth and

success. With their machining background, they have

modified EDM machines where they can cut parts 36" (914

mm) tall, and wire EDM a single-hole cavity in tubes up to22" (559 mm) deep. They do all kinds of work for aerospace,

defense, petroleum, plastics, electronics, medical and many

other industries.

Since their company uses all the EDM equipment discussed

in this book, Carl and Steve are uniquely qualified to write

The Complete EDM Handbook. In regard to the first book Carl

and Steve wrote, Wire EDM Handbook, Jack Sebzda, editor in

chief of EDM Today, stated:Wire EDMing to 36" Tall

Illustration: 3 1/4" Keyway EDMed 33"


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Complete EDM HandbookCompliments of www.ReliableEDM.com

FINALLY...A comprehensive, professionally written book, all

about Wire EDM is available to the EDM community!...

The 'Wire EDM Handbook' puts a wealth of practical, to-the-point

information at your fingertips. Written for people at every level of

EDM experience, this professional, hard cover book, belongs inevery EDM shop." (EDM Today has repeatedly advertised and sold

this book for many years."

Wire EDM Handbookwent through four editions and has been used as

a textbook in US colleges and technical schools. When this book was first

published, an EDM salesperson who travelled to Germany told Carl that

there was a book in Germany on wire EDM, but our book "makes money."

This was a high compliment. Our aim in writing The Complete EDM

Handbookis to provide practical advice for all the EDM processes. We haveseen many articles with all sorts of technical information that we in the

shop would never use. We have avoided this in writing this book.

There is information in this book that can literally save companies

thousands of dollars. Since Carl has worked as a tool and die maker,

tool designer, and operations manager of a large tool and die shop, his

information alone in chapters 7 and 8 can save companies tens of thousands

of dollars if implemented. Throughout this book there's much practical

advice for everyone.

For more information, feel free to contact them.

Reliable EDM

6940 Fulton St.

Houston, TX 77022

800-WIRE EDM (800-947-3336)

Tel. 713-692-5454

Fax 713-692-2466

Web site: www.ReliableEdm.com

E-mail Phil or [email protected]

8


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19

Understanding ElectricalDischarge Machining

lectrical Discharge Machining

No longer is EDM a "non-conventional" machining method. It is claimed that

EDM is now the fourth most popular machining method. The first three are milling,

turning, and grinding. One of the major reasons for the turnaround is today's EDM

machines have dramatically increased their cutting speeds.

n todays highly competitive world, it is essential to

understand the electrical discharge machining (EDM)

processes. Every manufacturer needs to learn and understand

the many advantages of EDM. We will be examining thethree basic EDM processes: wire EDM, ram EDM, and small

hole EDM drilling. See Figure 1:1.

Figure 1:1

The Three EDM Processes

1

Wire EDM

Courtesy Mitsubishi

Courtesy Agie

Ram EDM Small Hole EDM Drilling

Courtesy Charmilles


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omplete EDM Handbookomp iments o www.Re ia eEDM.com

Various Electric Discharge Machines

he three electric discharge machining methods, wire, ram, and small hole EDM,

all work on the principle of spark erosion. As the name indicates, material is eroded

from the workpiece by means of electrical discharges that create sparks.

A. Wire EDM

n wire EDM, the spark jumps from the wire electrode to the workpiece and

erodes metal both from the wire electrode and the workpiece. Wire EDM is used

primarily for through hole machining as shown in Figure 1:2.

. Ram EDM

am EDM, also known as conventional EDM, sinker EDM, die sinker, vertical

EDM, and plunge EDM is generally used to produce blind cavities as shown in

Figure 1:3. In ram EDM sparks jump from the electrode to the workpiece. This

causes material to be removed from the workpiece.

Figure 1:3

am EDMRam EDM is used rimaril for blind hole machinin .

Electrode

Work piece

Figure 1:2

Wire EDM

Wire EDM is used primarily for through hole machining.


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21Un erstan ing E ectrica Disc arge Mac ining

C. Small Hole EDM Drilling

Small hole EDM drilling, also known as fast hole EDM drilling, hole popper,

and start hole EDM drilling, uses a hollow electrode to drill holes by means of

lectrical discharge machining by eroding material from the workpiece as shownn Figure 1:4.

Materials That Can Be EDMed

Any material that conducts electricity can be EDMed, either hard or soft. See

igure 1:5 for some of the materials that can be EDMed.

Figure 1:5

ome of the materials that can be EDMed.

Figure 1:4

mall Hole EDM Machining

mall Hole EDM is primarily used for drilling holes.

iece

nconel Aluminum Vasconal 300

ool Steels: 01, A2, D2, S7 Aluminum Bronze PCD Diamond

arbide Copper Nitronic

erro-Tic Brass Beryllium Copper

PM 10V Cold Roll Steel Hastalloy

130 Hot Rolled Steel Stellite

raphite Stainless Steels Titanium


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Keeping Abreast With EDM Technology

n the early '70s a typical wire EDM machine cut two square inches an hour,

today they are rated to cut over 20 times faster and producing sub-micron finishes.

For many applications, from tool and die making, medical tools, dental instruments,

oil field production, and to space applications, wire EDM is an extremely cost-

effective machining operation.

he purpose of this book is to educate engineers, designers, tool and die

makers, mold makers, business owners, and those making machining decisions to

understand and to be able to use the electrical discharge machining methods, and

thus make their companies more profitable.

s a tool and die maker, Carl saw the great advantages of wire EDM for his

trade. Carl's surprise after opening his EDM company was the many production

jobs they received from machine shops that had NC equipment. These machine

shops discovered that it was more cost effective to have work wire EDMed than to

do it on their own NC equipment. Figure 1:6 shows some of the production work

done at Reliable EDM.

Figure 1:6

ire EDM Replacing Conventional and NC Machining


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The Machining Revolution

The early EDM machines, particularly ram EDM, were simple; but with the

advent of the CAD/CAM (computer aided design/computer aided machining),

another revolution came. Computerized programs could be downloaded into a

achine and the operation proceed automatically. The use of these machines

ramatically increased productivity. With the addition of high speed computers,

hese machines achieved faster processing times.

Then fuzzy logic was introduced, both for wire EDM and ram EDM. Unlike

bilevel logic, which states that a statement is either true or false, fuzzy logic allows

a statement to be partially true or false. Machines equipped with fuzzy logic

think and respond quickly to minute variances in machining conditions. They

an then lower or increase power settings according to signals received.

Some EDM machines come equipped with linear drives instead of rotary drives

ith a motor and ball screws. A motor and ball screw must take rotary action and

onvert it to linear motion. Linear motors or flat motors move in a straight motion

so no conversion is required. See Figure 1:7.

ther innovations include automatic tool changers, robots, workpiece and pallet

hangers, high-speed finishing, and artificial intelligence that enables machines to

perform many complex machining sequences.

Courtesy Sodick

Figure 1:7

Rotary and Linear Drives


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24omplete EDM Handbook

omp iments o www.Re ia eEDM.com

Understanding Accuracy

ne of the amazing features of the EDM process is the speed and accuracy that

can be maintained. In a later chapter we will go into further detail about accuracy,

but now we would like to make sure everyone understands accuracy. One of the

biggest difficulties in the machining trade is determining required part accuracies.

Certain jobs require extremely close tolerances; but excessively close tolerances

are often unnecessary and add substantial costs to the machining processes.

Understanding tolerances is an important asset in reducing machining costs.

o better understand the accuracy, some EDM machines can cut to +/- .0001"

(.0025 mm) and closer. The thickness of a human hair is slightly over .002 (.051

mm), these machines can cut to one-tenth the thickness of a human hair.

any manufacturers misunderstand close tolerance measurements. They put on

prints +/- .0005" (.0127 mm) whether the size is 2 inches (51 mm) or 10 inches

(254 mm). In the early days of our EDM experience, we received a wire EDM job

that required +/- .0005" (.0127 mm) for holes about 15 inches (381 mm) apart. Now

close tolerances require numerous skim cutting and are costly. However, when I

went and visited their inspection department, they were measuring the parts with a

veneer caliper!

he coefficient of expansion of steel is 6.3 millionths (.0000063) per inch

(.00016 mm) per degree F. (.56 C). If the temperature of a 10 inch (254 mm) piece

of steel rises only 10 degrees F. (5.6 C.), it will expand .00063 (.016 mm). If a 10

inch part was machined precisely on size with a +/- .0005" (.0127 mm), it would

be out of tolerance just from the ten degrees of heat applied by handling the steel

through heat expansion. See Figure 1:8.

10" (254 mm)

Steel

ncreasing the

emperature 10 F

xpands the steel

plate .00063.

igure 1:8

Understanding Heat Expansion


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Automation and EDM

Here is an example where one can use their imagination to become more

ompetitiveuse automatic production cells. Today robots are available that can

eed various machines, such as a milling machine, wire EDM, and a ram EDM.With such machine production as shown in Figure 1:9, machines can run 24 hours

seven days a week.

Due to the rapid advances of technology, many traditional ways of todays

achining are performed with the EDM process. Manufacturers are realizing

ramatic results in achieving excellent finishes, high accuracies, cost reductions,

and much shorter delivery times.

ourtesy Systems 3R

Figure 1:9

obot Feeding Three MachinesMilling Machine, Ram EDM Machine,

nd Wire EDM Machine


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American Economy and Globalization

We live in a global economy, and America is losing many manufacturing jobs

to factories overseas. A way to keep America from losing jobs is to make our

factories more competitive by being more efficient, and EDM lends itself to be a

very productive machining method.

t Reliable EDM we have built our business on following the Golden Rule

which states: "Do to others what you would want them to do to you." As business

owners we put ourselves in our customers shoes and asked, "What would customers

want us to do?" We believe there are three basic customer desires:

1. They want quality products.

. They want good service.

3. They want good value.

y following these three principles we have become the largest wire EDM

job shop west of the Mississippi River. Because we want to keep our prices low,

we built all sorts of fixtures and try to maintain maximum productivity with our

machines.

We hope those reading this handbook, whether business leaders, employees,

or students, will ask themselves this question, "What can I do to help keep jobs

in America?" One of the things we can all do is to try to make our nation more

productive. We need everyone to think and explore ways on how to make their

companies and machines more efficient so we can keep as many jobs here as

possible.

DM is an excellent method for increasing productivity. Let's examine in the

next chapter the revolutionary machine that has already dramatically increased

productivitywire EDM.


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29

Wire EDM Fundamentals

Revolutionizing Machining

Wire Electrical Discharge Machining (EDM) is one of the greatest innovations

affecting the tooling and machining industry. This process has brought to industry

ramatic improvements in accuracy, quality, productivity, and earnings. Figure 2:1

shows various wire EDM machines.

Courtesy Makino

Courtesy Mitsubishi

ourtesy o c

igure 2:1

ire Electrical Dischar e Machines


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efore wire EDM, costly processes were often used to produce finished parts.

Now with the aid of a computer and wire EDM machines, extremely complicated

shapes can be cut automatically, precisely, and economically, even in materials as

hard as carbide. See Figure 2:2.

Wire EDM Beginnings

n 1969, the Swiss firm Agie produced the worlds first wire EDM machine.

Typically, these first machines in the early 70s were extremely slow, cutting

about 2 square inches an hour (21 mm /min.). Their speeds went up in the early

80s to 6 square inches an hour (64 mm2/min.). Today, machines are equipped

with automatic wire threading and can cut over 20 times faster than the beginning

machines. A remarkable turnaround.

Figure 2:2

Wire Electrical Discharge Machining

Traveling

Wire ElectrodeWorkpiece

otions

Wire

Motions dWire EDM Use

ughPrimarily for Thro

ole Machinin


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Wire EDM Fun amenta s 31

Production Wire EDM

Whether cutting soft aluminum, hot rolled steel, super alloys, or tungsten

arbide, manufacturers are discovering it is less expensive and they receive higher

uality with todays high-speed wire EDM machines for many production parts.

See Figure 2: 3.

Figure 2:3

arious Wire EDM Production Jobs

Wire EDMing Internal Keyways


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Com liments of www.ReliableEDM.com

Capabilities of Wire EDM

Some machines cut to accuracies of up to +/- .0001" (.0025 mm), producing

surface finishes to .037 Ra m and lower. At our company we can cut parts weighing

up to 10,000 pounds. See Figure 2: 4 and 5 for some large and heavy parts.

Wire EDM a Serious Contender With Conventional Machining

oday, wire EDM competes seriously with such conventional machining as

milling, broaching, grinding, and short-run stamping. Conventional wisdom

suggests that wire EDM is only competitive when dealing with expensive and

difficult-to-machine parts. But this is not the case. Wire EDM is often used with

simple shapes and easily machined materials. Our company receives much work

that could be machined by conventional methods. Although many of the customers

have conventional CNC machines, they send their work to us to be EDMed.

Figure 2:4

Wire EDM Machine Capable of Cutting Parts Up To 10,000 Pounds

Test Specimen Cut From a Turbine Measuring 7 Feet in Diameter

Figure 2:5

Large gate valve wire EDMed from a large block of steelruler is 24 inches (610 mm)


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A large wire EDM company reports that production runs up to 30,000 pieces

ake 65% of their cutting time. One particular job of theirs would have required

ine blank tooling and a 10 to 12-week wait, but EDM was able to finish the

ardened, .062" (1.57 mm) thick stainless steel parts burr-free and on time for their

production schedule.

New Demands by Design Engineers

As more design engineers discover the many advantages of wire EDM, they are

ncorporating new designs into their drawings. It therefore becomes important for

ontract shops to understand wire EDM so they can properly quote on these new

esigns requiring EDM.

Increasingly, todays drawings are calling for tighter tolerances and shapes that

an be only efficiently machined with wire EDM. See Figure 2:6.

An added benefit of wire EDM is that exotic alloys can be machined just as

asily as mild steel. When wire EDM manufacturers select the optimum steel to

emonstrate the capability of their machines, their choice is not mild steel, but

ardened D2, a high-chrome, high-carbon tool steel.

Figure 2:6

Various Shapes Cut With Wire EDM


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Whether cutting with nozzles away from the workpiece as in Figures 2:7 and 2:8,

or with nozzles on the workpiece, wire EDM has proven to be one of the greatest

machining revolutions.

Fully Automated Wire EDMs

or total unattended operation, some wire EDM machines are equipped with

automatic wire threading and robotized palletization. These machines are well

equipped to do high production runs.

Figure 2:8

Cavities required to be cut in the air.

6

(255 mm)

Figure 2:7

Cutting with nozzles away from the workpiece


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ne company making standard and made-to-order punch and die sets for turret

punch presses uses ten wire EDM machines fed by a robot. The robot moves

n a track between the two rows of wire EDM machines. After the parts are

DMed, a non-contact video inspection system, interfaced with a computer system

automatically examines the work.eneral Electric uses 36 wire EDM machines to cut steam turbine bucket roots.

reviously, GE used as many as 27 different operations, many of them milling; now

t can cut the entire bucket periphery in one pass. Prior delivery with conventional

ethods required 12 weeks; wire EDM reduced the delivery to 2-4 weeks.

How Wire EDM Works

Wire EDM uses a traveling wire electrode that passes through the work piece.

he wire is monitored precisely by a computer-numerically controlled (CNC)

system. See Figure 2:9.

Like any other machining tool, wire EDM removes material; but wire EDM

removes material with electricity by means of spark erosion. Therefore, material

hat must be EDMed must be electrically conductive.

Rapid DC electrical pulses are generated between the wire electrode and the

orkpiece. Between the wire and the workpiece is a shield of deionized water,

alled the dielectric. Pure water is an insulator, but tap water usually contains

inerals that causes the water to be too conductive for wire EDM. To control

he water conductivity, the water goes through a resin tank to remove much of

ts conductive elementsthis is called deionized water. As the machine cuts, the

onductivity of the water tends to rise, and a pump automatically forces the water

hrough a resin tank when the conductivity of the water is too high.

Figure 2:9Wire EDM

The wire EDM process uses a wire electrode monitored by a CNC system to remove material.

Traveling Wire EDM

Workpiece


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When sufficient voltage is applied, the fluid ionizes. Then a controlled spark

precisely erodes a small section of the workpiece, causing it to melt and vaporize.

These electrical pulses are repeated thousands of times per second. The pressurized

cooling fluid, the dielectric, cools the vaporized metal and forces the resolidified

eroded particles from the gap.he dielectric fluid goes through a filter which removes the suspended solids.

Resin removes dissolved particles; filters remove suspended particles. To maintain

machine and part accuracy, the dielectric fluid flows through a chiller to keep the

liquid at a constant temperature. See Figure 2:10.

DC or AC servo system maintains a gap from .002 to .003" (.051 to .076 mm)between the wire electrode and the workpiece. The servo mechanism prevents the

wire electrode from shorting out against the workpiece and advances the machine

as it cuts the desired shape. Because the wire never touches the workpiece, wire

EDM is a stress-free cutting operation.

he wire electrode is usually a spool of brass, or brass and zinc wire from .001

to .014" (.025 to .357 mm) thick. Sometimes molybdenum or tungsten wire is used.

New wire is constantly fed into the gap; this accounts for the extreme accuracy and

repeatability of wire EDM.

Figure 2:10

How Wire EDM Works

recisely controlled sparks erode the metal using deionized water.

Pressurized water removes the eroded material.

Path of Wire Electrode generated by

CNC Automated Computer System

Gauge of wire ranges from

.001 to .014" (.025 to .357 mm)

Pressurized

Dielectric Fluid

aterial removed is cooled

by the dielectric fluid

Spark erosion causes the

material to be eroded

Wire Electrode never contacts

the workpiece


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The Step by Step EDM Process

See Figures 2:11-14

A. Power Supply Generates Volts and Amps

B. During On Time Controlled Spark Erodes Material

igure 2:11

Deionized water surrounds the wire electrode as the power supply

enerates volts and amps to produce the spark.

igure 2:12

parks precisely melt and vaporize the material.

Wire Electrode

Workpiece

Voltage and Amperage control the

spark between the wire electrode

and workpiece.

EDM

Power

Supply

Deionized dielectric fluid

surrounds wire electrodeand workpiece

Wire Electrode

Workpiece

Dielectric FluidDielectric fluid acts as a resistor

until enough voltage is applied.

Then the fluid ionizes andsparks occur between the wire

electrode and the workpiece.

Sparks precisely melt and

vaporize the material.


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C. Off Time Allows Fluid to Remove Eroded Particles

. Filter Removes Chips While the Cycle is Repeated

Wire Electrode

Dielectric Fluid

Workpiece

Once the sparking process

is complete, the workpiece

material is cooled by the

pressurized dielectric fluid

and the eroded particles are

flushed out.

Wire Electrode

Workpiece

The melted workpiece

material forms into EDM

chips. A filter then removes

the chips and the dielectric

fluid is reused.

igure 2:13

During the off cycle, the pressurized dielectric fluid immediatelycools the material and flushes the eroded particles.

igure 2:14

he eroded particles are removed and separated by a filter system.


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Super Precision Band Saw

To better understand the wire EDM process, visualize the wire EDM machine as

a super precision band saw with accuracies to +/-.0001 " (.0025 mm). See Figure

:15

Escaping

Dielectric

Fluid

Pressurized, filtered, and cooled

dielectric fluid

U

D

G

p

L

igure 2:15

super precision band saw capable of cutting hardened material to +/- .0001 .0025 mm .


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Independent Four Axis

ndependent four axis wire EDM machines allow the machines to cut a top

profile different from the bottom profile. See Figure 2:16. This is particularly useful

for extrusion molds and flow valves.

arts as shown in Figure 2:17 were produced with independent four axis wire

EDM.

Figure 2:16

Independent Four Axis

ifferent shapes can be produced on top and bottom of a workpiece.

View AA

Figure 2:17

Independent Four Axis Parts


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A computer image of the numbers one and two combined into a single piece is

shown in Figure 2:18. (See the second image on the left on the previous page in

igure 2:17 for the EDMed number one and two.)

A picture of the Statue of Liberty combined with a cross is shown in Figure 2:19,

and the computer image in Figure 2:20. (To remove the Statue of Liberty and the

ross, various cuts had to be made in the scrap portion.)

Figure 2:18

rogrammed Number One and Number Two.

igure 2:19

tatue of Liberty and Cross

igure 2:20

Computer Image of the Statue of Liberty and Cross.


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Understanding Independent Four Axis

anufacturers have discovered unique ways of using the capabilities of the

independent four axis: extrusion molds, flow openings, injection molds, and many

other complex shapes.

o better understand independent four axis, a person can hold a string and move

the top and bottom of the string independently. Virtually any conceivable shape can

be created within the confines of the travel of the U and V axes of the wire EDM

machines. Machines are capable of cutting tall parts with independent angles up to

45 degrees. See Figure 2:21.

ourtesy Charmilles

Figure 2:21

Wire EDM Machines are Capable of Cutting 45 Angles.


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Submersible Cutting

In submersible cutting a tank surrounds the work area and the tank is filled with

eionized water before the cutting takes place. In a dry machine, water needs to

low from the nozzles to surround the wire with deionized water.

Submersible cutting is a great aid in starting a cut and when skim cutting because

he wire is always submersed in water as shown in Figure 2:22. Dry machines can

also do skim cutting, but one needs to be careful of always maintaining water

around the wire, otherwise the wire will break. As shown in Figure 2:23, our

ompany cut this 18 (457 mm) show piece submersed.

Figure 2:23

how Piece Cut Submersed18 457 mm

Figure 2:22

A Submersible Wire EDM

Courtesy Mitsubishi


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Staying Competitive

o remain successful, companies need to keep informed of the newest

technologies in order to remain competitive. Understanding the many changes in

the EDM processes is important for those in manufacturing.

ngineering and trade schools should be concerned that their graduating students

are properly equipped to enter the workforce knowing the latest technologies. This

book aims to encourage and educate upcoming engineers, toolmakers, and those in

management to understand and be able to use the EDM processes profitably.

n 1981, someone proved mathematically that wire EDM could not achieve

speeds over 4 sq. in. (43 mm/min.) per hour. Those who experienced wire EDM in

the early 80s may have decided that this process was inefficient and costly. Times

have changed EDM dramatically.

he first wire EDM machines had heights between 2 to 4 inches (51 mm to 102

mm). Through the years the cutting heights of EDM machines have increased. A

customer came to Reliable EDM with a tall part and was told we couldn't cut the

part because of the height limitations of our machines. Carl Sommer happened to

pass by as the customer was told they could not cut the part. Since Carl has years

of machining experience and has worked on building machines, he thought they

could modify a machine to cut the part. Today, they can EDM parts weighing up to

10,000 pounds and workpieces up to 36 inches (915 mm) tall. Illustrated in Figure

2:24 are some tall parts our company has EDMed. The moral of the storylet your

imagination run loose.

We have examined the fundamentals of wire EDM, let us examine some of the

many ways one can profit with this revolutionary machining process.

Figure 2:24

Various Tall Parts EDMed

e have modified a wire EDM machine to cut parts up to 36" (914 mm) tall.


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45

Profiting With Wire EDMUsers of Wire EDM

Parts made with the wire EDM process are used for machining conductive

aterials for medicine, chemical, electronics, oil and gas, die and mold, fabrication,

onstruction, automotive, aeronautics, spacevirtually any place where electrically

onductive materials are utilized.

Benefits Of Wire EDM

A. Production Runs

Because of the new generation of high-speed wire EDM machines, manufacturersncreasingly are discovering that wire EDM produces many parts more economically

han conventional machining. See Figure 3:1 and 2. An additional benefit with wire

DM is that close tolerances can be held without additional cost and without burrs.

Figure 3:1

Production EDMTodays high speed wire EDM machines can produce

many parts more economically and burr-free than with conventional machining.

igure 3:2

Titanium Parts for Oil Exploration

3


30/174



. Various Shapes and Sizes

With this new technology, any contour (Figure

3:3) and varying tapers can be machined precisely.

Extremely thin sections can be made because the

wire electrode never contacts the material being cut.EDM is a non-contact, force-free, metal-removing

process which eliminates cutting stress and resultant

mechanical distortion.

C. Accuracy and Finishes

he wire path is controlled by a CNC computer-generated program with part

accuracies up to +/- .0001 (.0025 mm), and some machines achieve surface

finishes well below .037 Ra m. Dowel holes can be produced with wire EDM to

be either press or slip fit. See Figure 3:4 where precision cams were EDMed.

. Eliminates Extra Machining Processes

he extremely fine finish from the standard wire EDM process often eliminates

the need for grinding or other finishing procedures. When using wire EDM, one

should not hesitate to add small radii to eliminate a secondary operation, such as

deburring of edges (Figure 3:5). The cost is unaffected by adding radii.

Figure 3:3

Infinite Shapes and Sizes

Figure 3:5

Eliminates Extra Machining Process

ll internal

nd external

radii .020

Figure 3:4

recision Cams Cut From Stainless Steel Sheets


31/174

rofiting with Wire EDM 47

E. Burr Free and Perfectly Straight Machining

Stamped materials have rollover edges and tapers. Wire cut materials are totally

burr free, smooth and straight. See Figure 3:6.

. Damaged Parts Can Be Repaired with Inserts

EDM allows a damaged die, mold, or machine part to be repaired with an insert

rather than requiring the part to be remade. An insert can be EDMed and held

ith a screw, or a tapered insert can be produced so that it can be forced to fit. See

xamples in Figures 3:7 and 3:8.

Figure 3:6

ire EDM Parts are Straight and Burr Free

Figure 3:7

Damaged Die Repaired With InsertDovetail can be pressed fit or held with a screw

Rollover

Burnished

Land

Fracture

urr

Finish From

Stamping

Dovetail Insert

inish From

Wire EDM

Straight

Land


32/174



G. Less Need for Skilled Craftspersons

ecause wire EDM often eliminates extreme precision and time consuming

machining processes, it reduces the need for skilled craftspersons. This frees suchprofessionals for more productive and profitable work.

. Material Hardness Not a Factor

Wire EDMs cutting ability is unaffected by workpiece hardness. In fact, it cuts

hardened D2 faster than cold roll steel. The advantage of cutting materials in the

hardened state is that it eliminates the risk of distortion created when the material

needs to be heat treated.

DM introduces minimal heat into the material, and the small amount of heat

that is generated is quickly removed by the dielectric fluid. At our company wehave EDMed hundreds of hardened stamping dies from various tool steels with no

negative results.

. Computers Can Perform Calculations

Since computers program the path for wire EDM, usually only basic math

dimensions are needed. Also when exact chord positions on blending radii are

required, computer programs can automatically calculate the blending points. See

Figure 3:9

igure 3:8

epairing a Damaged Hardened Hole

Damaged Hole Wire EDM the Hole Fit the New InsertPress

seWire Cut In t


33/174

rofiting with Wire EDM 49

J. Digitizing is Possible

It is not always necessary to have exact dimensions of a drawing or of a part. By

eans of digitizing as illustrated in Figure 3:10, a program can be made directly

rom a drawing or from a previous-produced part.

Figure 3:9

Computers are used to program the wire EDM path

igure 3:10

Example of a Digitized Drawing


34/174



. Miniaturization of Parts

Wire EDM can machine thin webs with extreme precision, and close inside and

outside radii with very fine micro finishes (Figure 3:11). Some machines can cut

with wire as thin as .0008(.020 mm) wire.

. Machining With Nozzles Away from Workpiece

arts can be EDMed, as shown in Figure 3:12, even when flush nozzles are not

directly against the workpiece. This is a slower cutting process due to less water

pressure in the cut, but for many jobs it is still economical.

Figure 3:12

Keyway can be EDMed even though flush ports do not contact the part.

Figure 3:11MiniaturizationWire EDM can produce very thin webs and miniature parts.

.007 (.18 mm) Typical

Key Slot EDMed

Courtesy Sodick


35/174

rofiting with Wire EDM

M. Reliable Repeatability

The reliability of wire EDM is one of its great advantages. Because programs

are computer generated and the wire electrode is being fed constantly from a spool

and used only once, the last part is identical to the first one. The cutter wear of

onventional machining does not exist with wire EDM. Because of this, tighter

achining tolerances can be maintained without additional costs.

Parts for Wire EDM

A. Precision Gauges and Templates

omputer generated programs for wire EDM are used rather than costly grinding

procedures to produce precision gauges and templates as in shown in Figure 3:13

and 14. Since gauges and templates are often thin, making two or more at the sameime adds little to the cost of their production.

Figure 3:13

recision Gauges and Templates

Thread Gauges emplates

Figure 3:14

hort-Run Production of Multiple Gauges


36/174



. Keyways vs. Broaching

Wire EDM easily cuts precision keyways as shown in Figure 3:15. It also

produces hexes, splines, and other shapes, without the need to make special

broaches, even from the material in the hardened state.

C. Shaft Slots

ather than make a costly setup to machine a slot in a shaft, a simple setup can

be made on a wire EDM machine. In addition to saving time, EDM produces no

burrs in the threaded area. See Figure 3:16.

. Collets

onventional machining often distorts collets. If the collets are heat treated

after machining, they often distort even more. In contrast, wire EDM can machine

collets in the hardened condition and without any cutting pressure, as shown in

Figure 3:17

Figure 3:15

Precision Keyways

Figure 3:16

Burr-Free Slot in Threaded Area

Figure 3:17

Collets can be cut in the hardened condition without any cutting pressure.

Hole Wire EDMed for Strength


37/174


E. Parting Tubes and Shafts

Because of the small gap produced by wire EDMa .012 (.30 mm) wire produc-

s a .016(.41 mm) gap (thinner wires can also be used)tubes, shafts, and bearing

ages can be parted after machining is completed, as pictured in Figure 3:18.

. Shaft Pockets

Any shaped pocket which goes through a shaft can be machined with wire EDM.

See Figure 3:19.

G. Fabrication of Graphite Electrodes for Ram EDM

raphite electrodes for ram EDM can be machined with wire EDM. One of the

reat advantages for this is that wire EDM produces identical electrodes.

The cost of producing graphite electrodes is largely determined by the

utting speed of the wire. The cutting speed of various grades of graphites are

astly different. For example, the graphite Poco Angstrofine, EDM-AF5, cuts

early twice as fast as most of the other grades, EDM-1, EDM-3, EDM-100,

r EDM 200.

igure 3:18Splitting Tubes

Figure 3:19

Shaft Cutouts

Wire EDM Cut


38/174



. Punches and Dies From One Piece of Tool Steel

With wire EDM, dies no longer have to be made by the costly method of being

sectioned and precision-ground. Now the most elaborate contours can be made

from one solid piece of hardened tool steel as shown in Figure 3:20.

he one-piece tool steel results in a stronger, non-breathing die at a fraction ofthe cost of a sectioned die. Also, compound dies can be wire EDMed from one

piece of tool steel. For detailed instructions on EDMing and fabrication of these

low-cost, high-performance one-piece dies, see chapter 8 of this book.

. Progressive Stamping Dies

Wire EDM has dramatically altered progressive tool and die making as illustrated

in Figure 3:21. Now elaborate die sections can be precisely EDMed at a much

lower cost.

igure 3:20

ne Piece Punch and Die

unch

ie

igure 3:21

Punch and Die Wire EDMed

Courtesy Charmilles Technologies


39/174


J. Short-Run Stampings

Instead of expensive tooling being produced for short runs, precision parts can

be produced with wire EDM. See Figure 3:22. When alterations are needed, they

an be made at practically no cost; while alterations with hard tooling are usually

ostly. Wire EDM can also produce all sorts of special shapes and in varioushicknesses.

. o s

Elaborate extrusion molds, with or without taper can be produced economically.

See Figure 3:23.

L. Special and Production Tool Cutters

Wire EDM can produce special one-of-a-kind tooling with various tapers,

ncluding carbide. See Figure 3:24. When production tool cutters need to be made,

hey should all be the same to eliminate costly setups and checking procedures

hen changing cutters. Since wire EDM repeats accurately, this process produces

dentical production tool cutters.

Figure 3:23

Tapered Extrusion Mold

Figure 3:22

Stacked Material to Produce Intricate Parts for Short-Run Stampings


40/174



. Difficult-to-Machine Shapes

Wire EDM has dramatically reduced costs for many manufactured parts. Instead

of using costly setups and complicated machining procedures to produce parts,

wire EDM is often more cost effective. See Figure 3:25 for a difficult production

machining operation that could be produced more economically with wire EDM.

. Other Cost-Reducing Parts

any other parts can be also economically produced with wire EDM. Following

are some samples. See Figure 3:26-32.

Figure 3:25

Difficult-to-Machine Shapes

.250 .002

.250 .002 TYP

1.250 .002

.195 .002

.125 PINS

.500 .005

.150 .0025/81.000 .002

2.250 .005 MATERIAL 17-4 PH SS

Figure 3:24

pecial Carbide Form Tool


41/174


igure 3:27 Gears & Internal Splines

Figure 3:31 Various Shapes in Barsigure 3:30 Sectionalizing Parts

igure 3:26 Cams

Figure 3:28 Hexes igure 3:29 Special Shapes

Various Wire EDM Applications


42/174



Cutting Shim Stock Absolutely Burr Free

or most sheet metal parts, lasers are more cost efficient. However, when thin

materials need to be cut without many holes, wire EDM can be significantly

cheaper and produce an edge that is totally burr free. For example: 500 pieces

to be machined from .005 shim stock. With wire EDM the shim stock is cut and

sandwiched between two 1/4 inch (6.4 mm) steel plates, the total height of the

shims is 2.5 inches (63.5 mm). See Figure 3:32.

ultiple parts can be cut as shown in Figure 3:33.

Figure 3:32

EDMing Shim Stock Burr Free

igure 3:33

Cuttin Multi le Shims

Flathea crews .


43/174


Single Cavity Cut With Wire EDM Into One Side of a Tube

An oil field company needed two tapered cavities to be cut out of one side of a

ube. A wire EDM machine is like a precision band saw. Under normal conditions,

ne cannot cut single cavities with a wire EDM machine. However, our company

esigned a special fixture that enabled us to cut 22" deep (559 mm) into one side

f a tube. Illustrated in Figure 3:34 and 35, is a show piece that we cut with our

special fixture.

igure 3:35

Reliable EDM's Show Piece: Single Cavity Cut Into One Side of a Tube

Figure 3:34

Special Fixture Cutting a Cavity in One Side of a Tube


44/174



Horizontal Wire EDM

Wire EDM machines are available that instead of cutting vertically, cut

horizontally. One of the machines uses wire as small as .00078" (.02 mm). This

machine is capable of automatically threading wire through a .0019 " (.05 mm)

diameter hole. This type of a machine is used for micro-minature molds, gears,

fiber optics, motors, actuators, nozzles, and medical instruments. One of the big

advantages of horizontal wire EDM is it is better adapted for automation because

the slug can fall straight down and not interfere with cutting the next part. A sensor

on the machine indicates that the core has been removed.

Machining Costs

sually the machining costs are determined by the amount of square inches

of cutting, as illustrated in Figure 3:36. Other factors are type of material,

programming, set up time, and whether the flushing nozzles contact the part. Itshould be noted that thickness of materials can have a dramatic effect on cutting

speeds. When manufacturers quote their cutting speeds, they use their optimal

height, around 2 1/4" (57 mm). Taller pieces cut significantly slower.

his chapter has discussed various profitable uses of EDM. The next chapter will

examine the proper procedures for this process.

Figure 3:36

Determining Machining Costs

hickness x Linear Inches = Square Inches2 x 1/2 + 1/2 + 2 1/2 + 2 1/2 = 12 square inches

2-1/2 2

1/2


45/174

61

To gain the greatest benefits from wire EDM, specific procedures should be used

o maximize EDMs potential for reducing machining costs. In planning work, the

ire EDM machine can be visualized as a super precision band saw which can cut

any hard or soft electrical conductive material.

Starting Methods for Edges and Holes

hree Methods to Pick Up Dimensions.

If the outside edges are important, then a finished edge should be indicated when

setting up the part to be wire EDMed.

A. Pick Up Two Edges as in Figure 4:1.

B. Pick Up a Hole as in Figure 4:2.

Pick Up a Hole

Figure 4:1

Pick Up Two Edges

X0

Y0

X0

Y0

Proper Procedures forWire EDM

4


46/174



C. Pick Up an Edge and Holes or Two Holes as in Figure 4:3

y using an edge and two holes, a part can be EDMed which is much larger than

the capacity of the machine. The part is indicated and a hole that has been either

machined or EDMed is picked up. Also, two EDMed edges can be used to locate

the part after it has been machined.

Edge Preparation

A. Square Edges

. Machined or Ground.

o ensure accuracy, the pick up edges must be square as shown in Figure 4:4.

Edge

oles

XXXX XXXX

Figure 4:3

Pick-Up From Edges and Holes

Figure 4:4

Edges must be square for proper pick up.

rong Right


47/174

roper Procedures for Wire EDM 63

. Unfinished Edges.

In case workpieces cannot be placed flat on the table, workpieces can be made

square to the top surface with sides unfinished by using a special squaring block

as shown in Figure 4:5.

. Scale

Since wire EDM is an electrical process, any material that is non-conductive

ust be removed if it is to be EDMed, or if the area is to be used for picking up.

Scale from heat treating is non-conductive. See Figure 4:6.

The heat-treated parts, particularly holes, must be either cleaned of scale or have

been vacuum heat treated or wrapped before heat treating. Sand or glass blasting

an be used to clean the surfaces where the wire will cut in. However, deep holes

are difficult to clean with sand or glass blasting.

quaring Block

Unfinished edge

Figure 4:5

Special squaring block can be used to make the wire square

to the surface of the material to be cut.

Non-conductive scale

Figure 4:6

o pick up from holes, the holes must be free of scale.


48/174



C. Pick-Ups

t is preferred to pick up surfaces without obstructions. If obstructions occur,

pick-ups can sometimes be made from a step by means of a gauge block or gauge

pin. See Figures 4:7 and 4:8.

Starter Holes

A. Automatic Pick-up

When locating parts with starter holes, the machine will automatically pick up

the center of the hole as shown in Figure 4:9. Such holes should be free from burrs

or scale.

Figure 4:8

bstruction Pick-UpA gauge block is used for pick-up.

Figure 4:7

Non-obstructive Pick-Up

Pick-up Surface

ick-up Surface

auge block

Figure 4:9

Wire EDM machines automatically pick up the center of a hole.

Automatic Pick-up


49/174


. nsquare o es

If a hole is unsquare, as illustrated in Figure 4:10, the wire will pick up the high

points and not the center of the hole.

C. Relieved Holes

A relieved hole, as pictured in Figure 4:11 , is the most accurate method to pick

p from a hole. Approximately 1/8 (3 mm) to 1/4 (6 mm) of land should be

eft.

D. Smooth Holes

A drilled hole may leave ragged edges. The wire will pick up the high points of the

ragged edges. To ensure accuracy, a reamed or bored hole is best. See Figure 4:12.

Location not in center

Pick-up points

Figure 4:10

nsquare hole will produce an inaccurate pick-up.

Land - leave 1/8 - 1/4

Figure 4:11

he greatest accuracy is obtained with a relieved hole.

igure 4:12

mooth holes locate pick-ups most accurately.

mooth hole


50/174



. Placement and Location of Starter Holes

1. If the part pick-up is in another location, the starter hole requires no precise

location.

. The starter hole should be placed at a straight surface whenever possible, as

shown in Figure 4:13. When parts are not skim cut in order to save machining timeand costs, usually a slightly raised area appears where the part ends. In such cases

the tip can be removed with a file or stone.

3. On narrow slots, the starter hole should be placed in a corner, as illustrated in

Figure 4:14, so that only one slug will be produced when wire EDMed.

igure 4:14

Proper Placement of Starter Hole for Narrow Slots

Place starter holes along straight

surface for easy removal of tip.

eave a 1/8 - 1/4wall thickness

void starter holes in radii or corners

Figure 4:13

Proper Placement of Starter Holes

will create two slugs. .


51/174


Layout

If multiple wire EDM operations are made in one piece, the best method to put

n dimensions is from a reference point of X = 0, Y = 0. See Figure 4:15 for the

deal layout.

igure 4:15

Best Layout Dimensions for Wire EDM

.825

X = 0

Y = 0 .000 2.8751.000 1.500

2.450

1.950

1.700


52/174

69

Accuracy and Tolerances

Wire EDM is extremely accurate. Many machines move in increments of 40

illionths of an inch (.00004") (.001 mm), some in 10 millionths of an inch (.00001")

(.00025 mm), and others even in 4 millionths of an inch (.000004) (.0001 mm).

Machines can achieve accuracies of +/-.0001 (.0025 mm); however, skim cuts

eed to be made to obtain such tolerances. See Figure 5:1.

Finishes

Extremely fine finishes of below 15 RMS can be produced with wire EDM.

(Some machines can produce even a mirror finish.) Wire EDM produces an

xcellent finish even in the so-called rough cut. Customers are often amazed

hen shown the fine finish of a single-pass cut.

This fine finish is present even after very large parts are cut, as in Figure 5:2.

n other cutting operations, such as lasers and abrasive water jet, the larger the

part, the rougher the finish. Wire EDM produces a smooth finish because the wire

lectrode goes through the entire part, and spark erosion occurs along the entire

ire electrode.

Courtesy Agie

Figure 5:1

recision Wire EDMing

Understanding the WireEDM Process

5


53/174



Wire Path

A. Wire Kerfhe wire never contacts the workpiece. If the wire would contact the workpiece,

there would be a short circuit and no cutting would occur. The wire electrode cuts

by means of spark erosion, thereby leaving a path slightly larger than the wire. A

commonly used wire, .012 (.30 mm), usually creates a .016 (.41 mm) kerf as

shown in Figure 5:3. Thinner wires have smaller kerfs.

igure 5:2

Showpiece: 16 Inches (406 mm) TallCut at Reliable EDM

They can cut up to 36" 914 mm tall

Figure 5:3ire Kerf

.012 (.30 mm) Diameter Wire

.016" (.41 mm)

kerf


54/174

Understanding the Wire EDM Process

. Corners and Radii

When the wire turns a corner it can produce a sharp edge on the outside corner,

but it will always leave a small radius on the inside corner as demonstrated in

igure 5:4. The size of this radius is determined by the wire diameter plus the spark

ap.To produce very sharp outside corners, skim cuts are made. Having small corner

radii on the outside corners can prevent the need for skim cuts; this also reduces

ire EDM costs. In stamping dies, sharp corners usually wear first, so a small

utside radius is preferable.

The minimum inside radius for .012(.30 mm) wire is .0063(.016 mm), and

he minimum radius for .010wire (.25 mm) is .0053(.13 mm). These small radii

are achieved by skimming. Smaller radii are possible with thinner wire; however,

ost work is done with thicker wires because thinner wire cuts slower.

Skim Cutting

For most jobs, the initial cut is sufficient for both finish and accuracy. However,

or precision parts, skim cuts achieve greater accuracy and a finer finish. There are

hree main reasons for skim cuts:

Barreling effect and wire trail-off Metal movement Finishes and accuracy

Figure 5:4

nside and Outside Corners

Radius .0063

.012 Wire

orner can be sharp


55/174



A. Barreling Effect and Wire Trail-Off

here is a .002 to .003 (.050-.076 mm) gap between the wire and the workpiece.

(Gap is determined by the intensity of the spark energy.) In this gap, a controlled

localized eruption takes place. The force of the spark and the gases trying to escape

causes a slight barreling. On thick workpieces, this barreling causes the center to beslightly hollow. See Figure 5:5.

When cutting sharp corners, the wire dwells longer by the inside radius,

causing a slight overcut; on the outside radius, it speeds, leaving a slight undercut

as illustrated in Figure 5:6. That is why most new machines have a slow downprogram for corner cutting. To achieve maximum corner profiles; however, skim

cutting is recommended.

trail-off is produced when the machine cuts a corner. A slight amount of

material is left behind for a short distance before the wire returns to its programmed

path. For most jobs this slight undercut is negligible.

Figure 5:5

First Cut Corner Conditions

Figure 5:6

kim Cutting is Used For Very Close Tolerances.

.016"

Direction of Travel

ligh

becau

well

Slight undercut

because wire goes

faster around corner

irection of Travel

Act

light hollow on first cut


56/174

Understanding the Wire EDM Process 73

The sharper the corner, the greater the overcut and undercut. The accuracy of

he part determines the need for skim cutting. To avoid most of this barreling effect

and wire trail-off, some wire EDM machines automatically slow down in corner

utting. Nevertheless, high precision parts still require skim cuts.

. eta ovement

Even though metal has been stress relieved, it may move after the part has

been cut with wire EDM because the stresses within the metal were not totally

removed in stress relieving. If metal has moved due to inherent stresses, and

he part requires to be precise, then skim cuts are needed to bring the part into

olerance. The accuracies called for by the print determine the number of skim

uts.

C. Finishes and Accuracy

First cuts produce a fine finish; however, sometimes a finer finish and greater

accuracies are required. To accomplish this, skim cuts are used. See Figure 5:7 for

a general view of the various finishes that can be produced with wire EDM. (Some

achines produce different results.)

.0008-.0014 Accuracy

(depending on thickness

of material)

.0004 Accuracy

.0002 Accuracy

A B D E0

45

0

15

MS

Finish

High Speed

Cut

1st

Skim

nd

kim

rd

kim

th

Skim

Figure 5:7

Approximate Accuracies and Finishes

Cut AFor most jobs, this finish and accuracy are more than adequate.

Cuts B-EDepending on accuracy and finish

required, various skim cuts are performed.


57/174



Skim cutting produces fine finishes because less energy is applied to the wire

which creates smaller sparks and thus smaller cavities. These small sparks produce

extremely fine finishes, and on some machines mirror finishes.

Carbideungsten carbide, third in hardness to diamond and boron carbide, is an

extremely difficult material to machine. Except for diamond cutting tools and

diamond impregnated grinding wheels, EDM presents the only practical method to

machine this hardened material.

o bind tungsten carbide when it is sintered, cobalt is added. The amount of

cobalt, from 6 to 15 percent, determines the hardness and toughness of the carbide.

The electrical conductivity of cobalt exceeds that of tungsten, so EDM erodes the

cobalt binder in tungsten carbide. The carbide granules fall out of the compound

during cutting, so the amount of cobalt binder determines the wire EDM speed,

and the energy applied during the cutting determines the depth of binder that is

removed.

When cutting carbide on certain wire EDM machines, the initial first cut can

cause surface micro-cracks. To eliminate them, skim cuts are used. However, at our

company, Reliable EDM, we have repeatedly cut carbide parts with a single cut.

When precision carbide parts are needed, then skim cuts are used.

Some older wire EDM machines used capacitors. Since these machines applied

more energy into the cut, there was a greater danger for surface micro-cracking.

Then DC power supply machines without capacitors were introduced, and this

helped in producing less surface damage when cutting carbide.

oday, many machines come equipped with AC power supplies. These machines

are especially beneficial when cutting carbide in that they produce smaller heat-

affected zones and cause less cobalt depletion than DC power-supplied machines.

o eliminate any danger from micro-cracking and to produce the best surface

edge for stamping, it is a good practice to use sufficient skim cuts when EDMing

high-precision blanking carbide dies. Studies show that careful skimming greatly

improves carbide surface quality. Durability tests prove that an initial fast cut and

fast skimming cuts produce very accurate high-performance dies.

Polycrystalline Diamond

he introduction of polycrystalline diamond (PCD) on a tungsten carbide

substrate has greatly increased cutting efficiency. PCD is a man-made diamond

crystal that is sintered with cobalt at very high temperatures and under great

pressure. The tungsten substrate provides support for the thin diamond layer.

he cobalt in PCD does not act as a binder, but rather as a catalyst for the


58/174


iamond crystals. In addition, the electrical conductivity of the cobalt allows

CD to be EDMed. When PCD is EDMed, only the cobalt between the diamond's

rystals is being EDMed.

EDMing PCD, like EDMing carbide, is much slower than cutting steel. Cutting

speed for PCD depends upon the amount of cobalt that has been sintered with theiamond crystals and the particle size of PCD. Large particles of PCD require very

igh open voltage for it to be cut. Also, some power supplies cut PCD better than

thers.

Ceramics

eramics are poor conductors of electricity. However, certain ceramics are

ormulated to be cut with wire EDM.

Flushing

Flushing is an important factor in cutting efficiently with wire EDM. Flushing

pressure is produced from both the top and bottom flushing nozzles. See Figure

5:8. The pressurized deionized fluid aids in spark production and in eroded metal-

particle removal.

Figure 5:8

deal Flushin Conditions

ressurized Deionized Fluid

ressurized Deionized Fluid

/16minimum

Flush support


59/174



Sometimes the flushing nozzle may extend beyond the edge of a workpiece, as

shown in Figure 5:9. When this occurs, flushing pressure is lost, and this can cause

wire breakage and part inaccuracy. To avoid wire breakage in such cases, a lower

spark energy is used which slows the machining process. To avoid losing flushing

pressure, it is advisable, if possible, to leave at least 3/16(5 mm) of material to

support the flushing nozzles.

Cutting Speed

Speed is rated by the square inches of material that are cut in one hour.

Manufacturers rate their equipment under ideal conditions, usually 2 1/4 inch (57

mm) thick D2 hardened tool steel under perfect flushing conditions. However,

differences in thicknesses, materials, and required accuracies can greatly alter the

speeds of EDM machines.

utting speed varies according to the conductivity and the melting properties

of materials. For example, aluminum, a good conductor with a low melting

temperature, cuts much faster than steel.

n the other hand, carbide cuts much slower than steel. It is the binder, usually

cobalt, that is melted away. When the cobalt is eroded, it causes the carbides to fall

out. Various carbides machine at different speeds because of carbide grain size and

the binder amount and type.

Impurities

enerally, impurities cause little difficulty; however, occasionally materials are

received with non-conductive impurities. The wire electrode will either stall or pass

around small non-conductive impurities, thereby causing possible streaks from

raised or indented surfaces.

When welded parts must be EDMed, one should use caution to make certain

there is no slag within the weld. Tig welding is preferred for wire EDM.

Figure 5:9

Poor Flushing Conditions

ost Flushing Pressure


60/174


Recast and Heat-Affected Zones

The EDM process uses heat from electrical sparks to cut the material. The sparks

reate a heat-affected zone that contains a thin layer of recast, also called white

ayer. The depth of the heat-affected zone and recast depends upon the power, type

f power supply, and the number of skim cuts.

The recast contains a layer of unexpelled molten material. When skim cuts

are used, much less energy is applied to the surface. This greatly reduces and

practically eliminates the recast layer.

n older wire EDM machines, the heat-affected zones and recast were much

ore of a problem. Also, the recast and heat-affected zones of ram EDM are much

reater when roughing because more energy can be used than with wire EDM.

Many of todays wire EDM machines have reduced this problem of recast and

eat-affected zones. Our company, Reliable EDM, is a wire EDM job shop that has

one work for well over 500 companies, including aerospace companies. We have

ire EDMed thousands of jobs and cut all sorts of materials, including carbide

and high-alloy steels. We have had practically no negative results from recast and

eat-affected zones. Most work is done with just one cut. For precision parts, skim

uts are used.

Newer machines now come equipped with anti-electrolysis power supplies, also

alled AC power supplies. These power supplies greatly reduce the recast and heat-

affected zones. On some machines, the heat-affected zone for the first cut is .0015

(038 mm), on the first skim cut it is .0003(.0076 mm), and on the second skim

ut it is .0001(.0025 mm).

For years, the recast and heat-affected zones have been a concern for the

aerospace and aircraft industry. With the improvement of power supplies, these

ndustries increasingly accept work done with wire EDM.

AC Non-Electrolysis Power Supplies

Instead of cutting with DC (direct current), some machines cut with AC

(alternating current). Cutting with AC allows more heat to be absorbed by the wire

nstead of the workpiece.

Since AC constantly reverses the polarity of the electrical current, it reduces the

eat-affected zone and eliminates electrolysis. Electrolysis is the stray electrical

urrent that occurs when cutting with wire EDM. For most purposes, electrolysis

oes not have any significant effect on the material. However, the elimination of

lectrolysis is particularly beneficial when cutting precision carbide dies in that it

reduces cobalt depletion.

When titanium is cut with a DC power supply, there is a blue color along where

he material was cut. This blue line is not caused by heat, as some suspect, but by


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electrolysis. This effect is not generally detrimental to the material. However, AC

power supplies eliminate this line.

ike AC power supply, the AE (anti-electrolysis) or EF (electrolysis-free) power

supplies improve the surface finish of parts by reducing rust and oxidizing effects

of wire EDM. Also, less cobalt binder depletion occurs when cutting carbide,and it eliminates the production of blue lines when cutting titanium. AC and

non-electrolysis power supplies definitely have advantages. See Figure 5:10 for

comparison between anti-electrolysis and conventional machining.

Isolated Pitting

When doing mold work, the surface finish of the molds is extremely important.

On certain materials, such as H-13 and S-7, pitting sometimes occurred when the

steel was wire EDMed. However, pitting never occurred when cutting D2 steel. It

was discovered that the chrome content of D2, which is 12%, was much higher than

H-13only 5% chrome, and S-7only 3.25%. However, H-13 and S-7 are very

popular mold steels.

he chrome content answered some of the problems, but not all. Sometimes

when cutting H-13 and S-7 pitting did not occur. The question arose, "Why does

pitting only occur occasionally."

fter further testing it was discovered that magnetism was the reason for the

pitting. On some occasions, even after the steel was thoroughly demagnetized,

they found some pitting. Then it was discovered even the rails on the wire EDM

machine, which could have residual magnetism, had an effect. One mold company

found a solution by purchasing an instrument that measured magnetic induction

(Gaussmeter). The company came to the conclusion that residual magnetism was

the basic cause for pitting.

Figure 5:10

Anti-Electrolysis and Conventional Machining Surfaces Compared

ubishiCourtesy Mits


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Heat-Treated Steels

Wire EDM will machine hard or soft steel. Materials requiring hardening

are commonly heat treated before being cut with wire. By heat treating

steel beforehand, it eliminates the distortions that can be created from heat-

reating.

The decision to heat treat steel before or after is often determined by the

equired accuracy needed, or if machining must be done after wire EDMing.

Cutting Large Sections

Steels from mills have inherent stresses. Even hardened steel that has been

empered often has stresses remaining. For cutting small sections, the effect is

egligible. However, for large sections when there is a danger of metal movement,

t is advisable to remove some of the metal. By removing metal, it helps to reducehe possibility of metal movement. Workpiece accuracy is the determining factor if

etal needs to be removed. See Figure 5:11.

Figure 5:11

emoving Material to Reduce Stresses on Large Parts

Leave at least 3/16 of material for EDMing.

ut out inside section with band saw.


63/174



etal movement can also be reduced by cutting relieving slots with a band

saw to connecting holes, as in Figure 5:12. Steel should be stress relieved before

heat-treating to remove the stresses caused by milling, drilling, and grinding. After

heat-treating, the tool steel should be double or triple drawn, including the non-

deforming air hardening tool steels. Another method to remove stresses is to usecryogenics (deep freeze). The tool steel is hardened and tempered; then it is put into

deep freeze and retempered.

Cutting Sections From a Block

A. Leaving a Frame

When a section must be cut from a block of steel, a frame should be left around

the workpiece to ensure accuracy and to reduce cost. At least 1/4 to 1/2" (6.5 to 13

mm) should be left around the part so that flush nozzles can efficiently remove the

eroded particles and also support the part for clamping. See Figure 5:13.

Figure 5:12

Using Saw Slots to Reduce Stresses on Large Parts

Drilled

Holes

Figure 5:13upport Part With Frame

Leave at least 1/4-1/2of material

to support frame and flush.

Starter

Hole

Leave at least 3/16of material for EDMing.

aw slots


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B. Strength of Frame

Sufficient extra material needs to be left around the part. When the part is held

in a fixture, the extra material will prevent the part from moving as it is being

EDMed. Figure 5:14 demonstrates a weak support frame. While the part is being

EDMed, the frame becomes weak, which can cause the part to move.

C. Material for Clamping

For many parts fixtures are used as in the above illustration. However, for some

parts provision should be made for clamping. See Figure 5:15.


The better understanding one gains of the wire EDM process, the more benefits

ne can obtain from this process. The next section covers how to reduce wire

costs.

igure 5:14

Improper Support Frame

rame is too weak. As

he part is EDMed the

rame collapses.

Figure 5:15

xtra material provided for clamping

Leave 1-1/4

or clamping


65/174

3

Wire EDM costs can be greatly reduced if the material has been properly

prepared and the EDM process is understood. Unfortunately, the opposite is also

rue. Wrong preparation can be costly.

Create One Slug

To reduce costs, the general aim should be to create one slug. Wire EDM is an

automatic process; if more slugs are made, it requires more down time and operator

services. Also, when surfaces close to an edge are cut, inadequate flushing occurs

hich reduces cutting speed.

When entering a workpiece on a slight angle, feathered-edge machining occurs.

his feather-edge machining may cause slight surface irregularities. Skim cutting

an be used to remove such irregularities; however, unnecessary skim cuts increase

ost. Cutting one slug is much more cost effective. See Figures 6:1 - 6:4.

Figure 6:1

rong ProcedureCreates six slugs and slows the process with feather-edge machining

akes six slugs.

Feathered-Edge Machining

Reducing Wire EDMCosts

6


66/174

84omp ete EDM Han oo

Comp iments o www.Re ia eEDM.com

Figure 6:2

ight ProcedureCreates one slug which produces more efficient machining

Leave at least 3/16 (9.84 mm)

Small hole in center

creates one slug.

igure 6:3

Wrong ProcedureCreates Five SlugsFive starting cuts must be made,

nd five times the machine must be stopped to remove each slug.

Figure 6:4

ight ProcedureCreates One SlugLeaving extra material

n the outside allows for one slug to be cut.


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Reducing Wire EDM Costs 5

Keeping Flush Nozzles on the Workpiece

The most efficient method for wire EDMing is placing both top and bottom

lush nozzles on the workpiece as shown in Figure 6:5. This placement allows for

aximum flushing pressure to remove the eroded chips.

If possible, nozzles that are not on the workpiece should be avoided because it is

ess efficient because of less water pressure in the cut. See Figure 6:6.

For many applications, however, there is no alternative but to have nozzles off

he workpiece. At our company, Reliable EDM, we cut many jobs with nozzles off

he workpiece, including tall parts. See Figure 6:7.

Figure 6:5

Most efficient cutting occurs when both flush nozzles rest on the part.

Figure 6:6

Cutting with nozzles not on the workpiece is possible, but it is less efficient.


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Machining After Wire EDM

o avoid cutting with nozzles off the workpiece, it is sometimes more economical

to do machining after, rather than before the EDM process. This is particularly true

with shallow recesses as in Figure 6:8.

Recess

ew

Figure 6:7

An 11-1/2 Inch (292 mm) test specimen cut out of a large gear with nozzles off the workpiece.

Figure 6:8

Machine the Workpiece After Wire EDMing

Since the recess is shallow it is more efficient to do the EDMin when the art is solid.


69/174


ften parts are stacked to reduce costs. When parts have intricate dimensions,

stacking may be difficult if parts have been previously machined as shown in

igure 6:9.

If parts can be stacked, it is preferred that holes be put in after the part has been

DMed. Putting holes in first can cause alignment difficulties when the parts are

set up in a fixture as in Figure 6:10.

Cutting Multiple Plates and Sheet Metal Parts

Stacked sheet metal can be held with fixtures without the need for welding.

owever, when multiple parts from one stack and starter holes are required, the

stack can be bolted with flat head screws or welded on its sides. The stack should

be flat, and the EDM job shop should be consulted for the ideal stack thickness.

igure 6:9

Holes should be put in after EDMing.

Ma ing one piece presents no problem; however, parts like these are stacked. If holes are

premachined, it is difficult to line up the holes when cutting large stacks.

.

Figure 6:10

ut tapped hole in after EDMing.Parts like these are often stacked in a V block. Higher machining costs occur

because tapped holes cause alignment difficulties.

5/8


70/174



Accuracy, efficiency, and machine capabilities determine the height for stacked

parts.

Wire EDM will cut through light rust; however, heavy rust and scale must be

removed. Many times plates are warped. The plates should be clamped tightly

together before welding. At least 1/2 (13 mm) should be left on the sides for

welding and clamping the part. See Figure 6:11 for proper stacking.

f sheets or plates are badly warped, each stack should be divided in half and the

belly should hit the center. The ends are then clamped together and welded. The

aim should be to produce a flat surface. The weld should be removed from the top

and bottom of the stack so flush ports do not hit the weld.

When putting stacks together, all sheets must be cleanmarker paint, (not magic

marker), scale, tape, or paper between the sheets must be removed. Wire EDM cuts

by spark erosion; it cannot cut through non-conductive materials.

Production Lots

Wire EDM is an excellent machining method for production work. Fixtures

are often used to hold the multiple parts. It is important that production lots are

machined the same in the area where they will be located. Parts also need to be

machined square. See Figure 6:12.

Head Bolts

1/2 (13 mm)

from edge

Figure 6:11

tacks Welded or Bolted

At least 1/2 (13 mm) should be left for clamping and a frame to support part while cutting.Caution: If parts are welded or bolted, both sides of plates must be clean and

free from heavy scale, tape, paper, or any other non-conductive materials.


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Stipulating Wire Sizes

Some machines can cut with .0008(.020 mm) wire. One wire EDM job was

one on a .015(.38 mm) diameter air turbine rotor. It had 13 slots cut with .00039

(.01 mm) wire. This was done on a specialized wire EDM machine.

The difficulty with cutting with thin wires is that it machines much slower

because less energy can be applied to the wire. Also, thin wires break much more

asily than standard wire sizes. Some applications require thin wires; however,

henever possible stay with the standard wire size of .010(.25 mm) or .012(.30

m) wires. Stipulating thin wire can add significant costs to the wire EDM process

because of slower cutting feeds and difficulties associated with such wires.

Figure 6:12

Production EDMingWhen machining parts, consideration should be made for stacking.

Outside diameter should

be the same and square

to assure accuracy


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Pre-Machining Non-Complicated Shapes

t is not always necessary to EDM the entire part. Sometimes pre-machining can

reduce costs as shown in Figure 6:13.

Wire EDM is an extremely efficient method to machine parts. However, costs

can be further reduced by understanding this unique process of cutting metal. In

the next chapter we will be discussing the advantages of wire EDM in tool and die

making. Understanding this process can result in substantial savings in producing

stamping dies.

Figure 6:13

Pre-Machine Parts to Reduce Costs.

Weld

Pre-machined surface


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Tool and Die Making

Wire EDM has revolutionized tool and die making. To understand the extent

f the wire EDM revolution for stamping dies (Figure 7:1), let Carl share some

istory.

Old-Fashioned Tool and Die Making

In 1950, I started to work in a machine shop; one year later I became an

apprentice tool and die maker in a large handbag frame plant in Brooklyn. The

plant produced a large variety of handbag frames which required many kinds of

ixtures and dies.

From 01 tool steel we milled, ground, or filed the form punch. The punch washen hardened in a gas-fired oven that had no temperature gauge. In those days, one

earned early the necessary cherry red color to indicate that the punch was ready to

be quenched in oil. After quenching, we used a gas torch to temper the punch to a

ight straw color.

Using the hardened punch as a template, we traced the pattern on a piece of tool

Documents

Complete EDM Handbook