The domestic die/mold industry is today going through considerable change—a good
deal of which is being driven by an urgency to become more competitive coupled
with advances in technology. Here's how one shop combines skill and technology
to be more than just competitive, but to excel and grow.
As one of three manufacturing companies under Laitram LLC, Intralox Inc.
(Harahan, Louisiana) manufactures modular plastic conveyor belts. With more than
400 combinations of belt styles, materials and colors to offer, the company
keeps its in-house mold shop running at full capacity.
Today, with 29 mold makers and repair technicians employing nine surface
grinders, five milling machines, three ram and two wire EDM machines, the
Intralox mold shop may well be one of the most competitive shops in the region.
Aiding the company in this competition is the Jung J630-D with a PA/31 contour
dresser with four diamond stations from United Grinding
Technologies (Miamisburg, Ohio).
According to Jules Ceccanti, mold shop manager, the shop started out 10 years
ago at Laitram as a mold repair facility. Then, as the repair activity
continued, the decision was made to begin building mold cavities. As that
capability grew, the company invested in more new technology, and today the mold
shop is the predominant supplier of plastic injection molding tooling to the
company.
"People who come here and see how we're set up and see the level of our
technology, tell us that this mold shop is one of the best in the South," says
Mr. Ceccanti.
The reasons that Intralox has its own mold shop are self-evident—the
competitive advantage of fast time-to-market, the confidence that comes from
complete process control and consistent product quality, and the ability to
address the sensitive issue of the retaining of proprietary mold information.
"If Intralox wanted to source its mold work outside," Mr. Ceccanti says, "it
would be looking at 18- to 20-week leadtimes. We, however, can have a mold
finished and producing good parts in 6 weeks, when we have to."
The shop does outsource some mold work. spreading it around. Some jobs,
however, have proven too tough for others to tackle. "We used to bid out a
couple of parts that we do very efficiently now on the Jung," Mr. Ceccanti says.
"These parts are very complicated, highly detailed, time-consuming and very
close-tolerance. Some shops just refused to quote; others bid high because they
were either unsure if they could even make the part or unsure whether they could
make a profit on the job."
There were two of these parts, Mr. Ceccanti says, that he got bids of $1,750
per part. With the Jung, his team makes the parts for $400 each.
Shane Jackson, lead mold maker, addresses some of the reasons the J630-D was
acquired. "Our previous CNC machine could do just about everything we wanted,
but there were some limitations" he says. The diamond dressers were stationary,
which meant the machine had to travel X, Y and Z to the dress wheel, which
tended to create flat spots, spots where parts of the diamond surface are worn
more than others. When we'd start getting spotty diamond wear, the machine
operator would try to compensate for it, but the compensation just wasn't
accurate enough."
The CNC dresser on the Jung rotates about an axis and permits much more
controlled diamond wear. Further, if a certain section of the diamond begins to
wear, Mr. Jackson says, you can change the angle where the diamond and the wheel
intersect, thus avoiding the worn section and using more of the diamond. The
rotational four-diamond dresser avoids diamond wear, and the Jung permits
continuous dressing so that dressing and grinding can occur simultaneously.
Mr. Jackson says that with the previous method, he'd have to draw all the
wheel geometry, post it through a software program, and then download it to the
machine. With the Jung, however, he simply takes a DXF file from the designer,
plugs it into the J630-D and runs the wheel profile right from the file.
A resident wheel library facilitates quick setup. Mr. Jackson explains that
the Jung actually "remembers" wheel shapes. "You take the wheel off and store it
away, but the wheel information stays in the machine's library. Then, when you
put the wheel back on, you type in a library number, and the Jung knows what the
wheel shape was the last time it was used. This is a great feature, permitting
the flexibility to interrupt a job, run a new job or several jobs and then go
back to the original job with no complicated reprogramming or setup issues—even
if a month has passed between jobs."
Mr. Jackson says the Jung is used for the shops most critical work, work in
tough materials with very tight tolerances and requiring superior surface
finishes. One example is special core pin slots, which are roughly 0.2000 inch
deep by 0.4000 inch wide by 12 inches long in a cavity block that's 12 inches by
2 inches and 2 inches thick. Typical material is 420 stainless or Elmax, a
powder metallurgical high vanadium version of 420 that's comparable to D2 and is
one of the most difficult materials to grind. 420 is generally 50-52 Rc, and
Elmax is 58-62 Rc.
Once a cavity block has been squared up and sized, it will come to the Jung,
where Mr. Jackson will load the wheel geometry, radii and angles, wheel
manufacturer, wheel type, grit size, and so on into the wheel library. He's then
ready to dress the form.
"After I've dressed the form," Mr. Jackson says, "I'll qualify it by grinding
the form in graphite. Then, I'll pull the graphite and inspect it using
conventional means—comparators, indicators or a Zeiss CMM—to inspect and check
the contour or axis of the radius. Generally, on forms we hold ±0.0002 inch. If
the graphite checks out, I know the wheel geometry is fine. Then I'll touch on
either side of the block, find the center, calculate my locations—typically I'll
program to location and depth—and then run the part. And the part is right on
size, without running any test work."
"Typically, in mold making, you cut some and then you measure; then you cut
some more and measure some more," he says. "As you get closer and closer to your
final dimensions, you're measuring more and cutting less. With the Jung, once
the wheel geometry is correct, you measure once and cut straight to
dimension."
The result is a significant savings in time, as well as an increase in
productivity and flexibility. Mr. Jackson cites a couple of examples. Before the
Jung, it would take a full day to run four to five typical 8 inch by 10 inch
cavities with four core slots. With the Jung, he can set up the same job and run
production—all before noon.
"Start to finish, it would take us two full 10-hour days to run six cavities
before the Jung. Now six cavities are done in a day," Mr. Jackson says. "That's
a time savings of 50 percent. It's not that the Jung grinds any faster; it's in
setup time and measuring time where we see the real competitive benefits."
One of the crucial issues in die/mold work is having complete confidence in
your tools—especially the grinder. "You have to build up a level of trust in the
machine," Mr. Jackson says. "Manual machines, for example, are notorious for
creeping, for getting a lot of wheel wear and not knowing exactly where the wear
is."
However, he says he doesn't worry about the J630-D and its rotating four
diamond dresser. The PA/31 rotates through each of the four diamonds—a rough
diamond, a semi-rough diamond, a finish diamond and an idle diamond. The idle
diamond takes a zero pass all the way through the form, ensuring that if any
flat spots remained after the three previous passes, the idle diamond will pick
them up.
Mr. Jackson says that to compete today, manufacturers have to use machines
that provide high productivity and flawless accuracy. Successful mold shops,
have to be able to convert their operations to high-end, high-productivity,
high-accuracy technology.
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