This is a quick update on 3D
printing technology used to produce production components. As stated, it does not lend itself to volume production
needs but for now it is great for small production runs and I am sure it beats hogging
out a block of metal.
I also suspect the process itself
has great upside for innovation and steady improvement.
In time we can hope to have the
capacity to produce almost anything this way.
Machined surfaces and the like may not be part of the mix but that has
always been an engineering challenge even with castings. That is what sleeves were invented for.
A thousand robots producing the
equivalent of castings seems likely though.
Layer by Layer
With 3-D printing, manufacturers can make existing products more
efficiently—and create ones that weren't possible before.
JANUARY/FEBRUARY 2012
BY DAVID H. FREEDMAN
Buildup: GE made the aircraft engine component on the left by using a
laser to melt metal in precise places, beginning with the single layer seen on
the right. Credit: Bob O’Connor
The parts in jet engines have to withstand staggering forces and
temperatures, and they have to be as light as possible to save on fuel. That
means it's complex and costly to make them: technicians at General Electric
weld together as many as 20 separate pieces of metal to achieve a shape that
efficiently mixes fuel and air in a fuel injector. But for a new engine coming
out next year, GE thinks it has a better way to make fuel injectors: by
printing them.
To do it, a laser traces out the shape of the injector's cross-section
on a bed of cobalt-chrome powder, fusing the powder into solid form to build up
the injector one ultrathin layer at a time. This promises to be less expensive
than traditional manufacturing methods, and it should lead to a lighter
part—which is to say a better one. The first parts will go into jet engines,
says Prabhjot Singh, who runs a lab at GE that focuses on improving and
applying this and similar 3-D printing processes. But, he adds, "there's
not a day we don't hear from one of the other divisions at GE interested in
using this technology."
These innovations are at the forefront of a radical change in
manufacturing technology that is especially appealing in advanced applications
like aerospace and cars. The 3-D printing techniques won't just make it more
efficient to produce existing parts. They will also make it possible to produce
things that weren't even conceivable before—like parts with complex,
scooped-out shapes that minimize weight without sacrificing strength. Unlike
machining processes, which can leave up to 90 percent of the material on the
floor, 3-D printing leaves virtually no waste—a huge consideration with
expensive metals such as titanium. The technology could also reduce the need to
store parts in inventory, because it's just as easy to print another part—or an
improved version of it—10 years after the first one was made. An automobile
manufacturer receiving reports of a failure in a seat belt mechanism could have
a reconfigured version on its way to dealers within days.
Additive manufacturing, as 3-D printing is also known, emerged in the
mid-1980s after Charles Hull invented what he called stereolithography, in
which the top layer of a pool of resin is hardened by an ultraviolet laser.
Various methods of 3-D printing have become popular with engineers who want to
create prototypes of new designs or make a few highly customized parts: they
can make a 3-D blueprint of a part in a computer-assisted design program and
then get a printer to spit it out hours later. This process avoids the up-front
costs, long lead times, and design constraints of conventional high-volume
manufacturing techniques like injection molding, casting, and stamping. But the
technology has been adapted to only a limited set of materials, and there have
been questions about quality control. Building parts this way has also been slow—it
can take a day or more to do what traditional manufacturing can accomplish in
minutes or hours.
For these reasons, 3-D printing hasn't been used for very large runs of
production parts.
But now the technology is advancing far enough for production runs in
niche markets such as medical devices. And it's poised to break into several
larger applications over the next several years. "We've come to the point
when enough critical advances are happening to make the technology truly useful
in manufacturing end-use parts," says Tim Gornet, who runs the Rapid Prototyping
Center at the University of Louisville
Pressing print: This photo shows an array of metal jet-engine
components printed at GE. Credit: Bob O’Connor
MAKING INROADS
Several techniques can be used to "print" a solid object
layer by layer. In sintering, a thin layer of powdered metal or thermoplastic
is exposed to a laser or electron beam that fuses the material into a solid in
designated areas; then a new coating of powder is laid on top and the process
repeated. Parts can also be built up with heated plastic or metal extruded or
squirted through a nozzle that moves to create the shape of one layer, after
which another layer is deposited directly on top, and so forth. In another 3-D
printing method, glue is used to bind powders.
Aerospace companies are at the forefront of adopting the technology,
because airplanes often need parts with complex geometries to meet tricky
airflow and cooling requirements in jammed compartments. About 20,000 parts
made by laser sintering are already flying in military and commercial aircraft
made by Boeing, including 32 different components for its 787 Dreamliner planes,
according to Terry Wohlers, a manufacturing consultant who specializes in
additive processes. These aren't items that have to be mass-produced; Boeing
might make a few hundred of them all year. They're also not critical to flight;
among them are elaborately shaped air ducts needed for cooling, which
previously had to be manufactured in multiple pieces. "Now we can optimize
the design of these parts for weight, and we save material and labor,"
says Mike Vander Wel, director of Boeing's manufacturing technology strategy
group. "In theory, this is the ultimate manufacturing method for us."
Though the speed limitations of 3-D printing might keep it from ever producing
the majority of Boeing's parts, Vander Wel says, the approach is likely to be
used in a growing proportion of them.
Boeing's main rival, the European Aeronautic Defense and Space Company
(EADS), is using the technology to make titanium parts in satellites and hopes
to use it for parts it makes in higher volume for Airbus planes. "We don't
yet know what the extent of our use of additive-layer manufacturing there will
be yet, but we don't see any show stoppers," says Jon Meyer, who heads
research on 3-D printing at EADS's Innovation Works division in England
Smaller scale: Seen
here is a microprinter that GE uses to test new ways of building things out of
ceramic materials. Researchers are using the machine to print the transducers
used as probes in ultrasound machines; they believe it might save time and
money while improving design. Credit: Bob O’Connor
GE's jet engine division may be closer than anyone else to bringing
3-D-printed parts into large-scale commercial production. In addition to the
fuel injector, GE is also laser-sintering titanium into complex shapes for
four-foot-long strips bonded onto the leading edge of fan blades. These strips
deflect debris and create more efficient airflow. Until now, each one has
required tens of hours of forging and machining, during which 50 percent of the
titanium was lost. By switching to 3-D printing, the company will save about
$25,000 in labor and material in each engine, estimates Todd Rockstroh, the GE
consulting engineer who heads the effort. The blade edge and the fuel injector
will start appearing in engines as early as 2013, and they will be integrated
into full-scale production runs in the thousands by about 2016.
Meanwhile, says Rockstroh, the company hopes to gain design flexibility
by using 3-D printing for more parts. When it recently discovered that a stem
in the fuel injector was subjected to excessive levels of heat stress, a
redesigned version came out of the printer within a week. "Before, we
would have had to redesign 20 different parts, with all the associated
tooling," says Rockstroh. "It might not have even been
possible." And using 3-D printing to corrugate the insides of some parts
can reduce their weight by up to 70 percent, which can save an airline millions
of gallons of fuel every year. That prospect has GE looking for ways to print
everything from gearbox housings to control mechanisms. "We're going on a
major weight-reduction scavenger hunt next year," Rockstroh says.
Automobiles could similarly benefit from lighter parts, and the University of Louisville
Polished: A
transducer made in GE’s microprinter (top) and the same transducer after being
refined and finished in other machines (bottom). Credit: Bob O’Connor
CHALLENGES TO
OVERCOME
If it weren't for the limitations of the technology, 3-D printing would
already be much more broadly used. "Speeds are atrociously slow right
now," says GE's Singh. Todd Grimm, who heads an additive-manufacturing
consultancy in Edgewood , Kentucky
Another problem: for now, only a handful of plastic and metal compounds
can be used in 3-D printing. In laser sintering, for example, the material must
be able to form a powder that will melt neatly when it is hit with a laser, and
then solidify quickly. The compounds that meet the necessary criteria can cost
50 to 100 times as much by weight as the raw materials used in conventional
manufacturing processes, partly because they're in such low demand that they're
available only from small specialty suppliers.
As demand increases with new applications, however, supplier
competition should pull prices down dramatically. And the list of available
materials is slowly expanding. GE is trying to use ceramics, which would open
up new possibilities in engines and medical devices, among other areas.
Simple experience, too, will do much to improve the technology. So far,
manufacturers don't have enough data to predict exactly how a part will turn
out and how it will hold up, or how production variables—including temperature,
choice of material, part shape, and cooling time—affect the results. That can
be frustrating, says Singh: "3-D printing often ends up being a black art.
A part is made out of thousands of layers, and each layer is a potential
failure mode. We still don't understand why a part comes out slightly
differently on one machine than it does on another, or even on the same machine
on a different day." For example, the layering process tends to build up
interlayer stresses in unpredictable ways, so that some parts end up distorted.
Porosity can vary within parts as well, leading to concerns about fatigue or
brittleness. That could be a big problem in aircraft engines or wing struts.
"We know how to make the metals strong enough," says Boeing's Vander
Wel. "But we worry about the unpredictability. Can we repeat a result to
get 100 parts that are exactly the same? We're not sure yet."
Even with these challenges, time is on the side of 3-D printing, says
Vander Wel, and not just because the processes are improving. Engineers are
understandably reluctant to embrace a new technology for critical parts when
their deadlines and reputations, not to mention the lives of people in
airplanes, are at stake. "But younger designers are adapting more
quickly," he says. "They're not so quick to say, 'It can't be built
this way.'"
David H.
Freedman, a science journalist based in Boston, wrote about optogenetics in
the November/December 2010 issue of TR. His latest book is Wrong: Why Experts Keep Failing Us.
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