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3
Rapid Prototyping Techniques
Most
commercially available Rapid
Prototyping machines use one of
six techniques. At present, trade restrictions severely
limit the import/export of rapid prototyping machines,
so this guide only covers systems available in the U.S.
3.1
Stereolithography
Patented
in 1986, stereolithography started the rapid prototyping
revolution. The Stereolithography process is the most
widely used of all Rapid Prototyping processes in the
year 2004.
The technique builds three-dimensional models from liquid
photosensitive polymers that solidify when exposed to
ultraviolet light. As shown in the figure below, the
model is built upon a platform situated just below the
surface in a vat of liquid epoxy or acrylate resin.
A low-power highly focused UV laser traces out the first
layer, solidifying the model’s cross section while
leaving excess areas liquid.
Figure
1: Schematic diagram of stereolithography.
Next, an elevator incrementally lowers the platform
into the liquid polymer. A sweeper re-coats the solidified
layer with liquid, and the laser traces the second layer
atop the first. This process is repeated until the prototype
is complete. Afterwards, the solid part is removed from
the vat and rinsed clean of excess liquid. Supports
are broken off and the model is then placed in an ultraviolet
oven for complete curing.
Stereolithography
Apparatus (SLA) machines have been made since 1988 by
3D Systems of Valencia, CA. To this day, 3D Systems
is the industry leader, selling more RP machines than
any other company. Because it was the first technique,
stereolithography is regarded as a benchmark by which
other technologies are judged. Early stereolithography
prototypes were fairly brittle and prone to curing-induced
warpage and distortion, but recent modifications have
largely corrected these problems.
3.2
Laminated Object Manufacturing
In
this technique, developed by Helisys of Torrance, CA,
layers of adhesive-coated sheet material are bonded
together to form a prototype. The original material
consists of paper laminated with heat-activated glue
and rolled up on spools. As shown in the figure below,
a feeder/collector mechanism advances the sheet over
the build platform, where a base has been constructed
from paper and double-sided foam tape. Next, a heated
roller applies pressure to bond the paper to the base.
A focused laser cuts the outline of the first layer
into the paper and then cross-hatches the excess area
(the negative space in the prototype). Cross-hatching
breaks up the extra material, making it easier to remove
during post-processing. During the build, the excess
material provides excellent support for overhangs and
thin-walled sections. After the first layer is cut,
the platform lowers out of the way and fresh material
is advanced. The platform rises to slightly below the
previous height, the roller bonds the second layer to
the first, and the laser cuts the second layer. This
process is repeated as needed to build the part, which
will have a wood-like texture. Because the models are
made of paper, they must be sealed and finished with
paint or varnish to prevent moisture damage.
Figure
2: Schematic diagram of laminated object manufacturing.
Helisys developed several new sheet materials, including
plastic, water-repellent paper, and ceramic and metal
powder tapes. The powder tapes produce a "green"
part that must be sintered for maximum strength. As
of 2001, Helisys is no longer in business.
3.3
Selective Laser Sintering
Developed
by Carl Deckard for his master’s thesis at the
University of Texas, selective laser sintering was patented
in 1989. The technique, shown in Figure 3, uses a laser
beam to selectively fuse powdered materials, such as
nylon, elastomer, and metal, into a solid object. Parts
are built upon a platform which sits just below the
surface in a bin of the heat-fusable powder. A laser
traces the pattern of the first layer, sintering it
together. The platform is lowered by the height of the
next layer and powder is reapplied. This process continues
until the part is complete. Excess powder in each layer
helps to support the part during the build. SLS machines
are produced by DTM of Austin, TX.
Figure
3: Schematic diagram of selective laser sintering.
3.4
Fused Deposition Modeling
In
this technique, filaments of heated thermoplastic are
extruded from a tip that moves in the x-y plane. Like
a baker decorating a cake, the controlled extrusion
head deposits very thin beads of material onto the build
platform to form the first layer. The platform is maintained
at a lower temperature, so that the thermoplastic quickly
hardens. After the platform lowers, the extrusion head
deposits a second layer upon the first. Supports are
built along the way, fastened to the part either with
a second, weaker material or with a perforated junction.
Stratasys,
of Eden Prairie, MN makes a variety of FDM machines
ranging from fast concept modelers to slower, high-precision
machines. Materials include ABS (standard and medical
grade), elastomer (96 durometer), polycarbonate, polyphenolsulfone,
and investment casting wax.
Figure
4: Schematic diagram of fused deposition modeling.
3.4 Solid Ground Curing
Developed
by Cubital, solid ground curing (SGC) is somewhat similar
to stereolithography (SLA) in that both use ultraviolet
light to selectively harden photosensitive polymers.
Unlike SLA, SGC cures an entire layer at a time. Figure
5 depicts solid ground curing, which is also known as
the solider process. First, photosensitive resin is
sprayed on the build platform. Next, the machine develops
a photomask (like a stencil) of the layer to be built.
This photomask is printed on a glass plate above the
build platform using an electrostatic process similar
to that found in photocopiers. The mask is then exposed
to UV light, which only passes through the transparent
portions of the mask to selectively harden the shape
of the current layer.
Figure
5: Schematic diagram of solid ground curing.
After the layer is cured, the machine vacuums up the
excess liquid resin and sprays wax in its place to support
the model during the build. The top surface is milled
flat, and then the process repeats to build the next
layer. When the part is complete, it must be de-waxed
by immersing it in a solvent bath. SGC machines are
distributed in the U.S. by Cubital America Inc. of Troy,
MI. The machines are quite big and can produce large
models.
3.6
3-D Ink-Jet Printing
Ink-Jet
Printing refers to an entire class of machines that
employ ink-jet technology. The first was 3D Printing
(3DP), developed at MIT and licensed to Soligen Corporation,
Extrude Hone, and others. The ZCorp 3D printer, produced
by Z Corporation of Burlington, MA (www.zcorp.com) is
an example of this technology. As shown in Figure 6a,
parts are built upon a platform situated in a bin full
of powder material. An ink-jet printing head selectively
deposits or "prints" a binder fluid to fuse
the powder together in the desired areas. Unbound powder
remains to support the part. The platform is lowered,
more powder added and leveled, and the process repeated.
When finished, the green part is then removed from the
unbound powder, and excess unbound powder is blown off.
Finished parts can be infiltrated with wax, CA glue,
or other sealants to improve durability and surface
finish. Typical layer thicknesses are on the order of
0.1 mm. This process is very fast, and produces parts
with a slightly grainy surface. ZCorp uses two different
materials, a starch based powder (not as strong, but
can be burned out, for investment casting applications)
and a ceramic powder. Machines with 4 color printing
capability are available.
3D
Systems' (www.3dsystems.com) version of the ink-jet
based system is called the Thermo-Jet or Multi-Jet Printer.
It uses a linear array of print heads to rapidly produce
thermoplastic models (Figure 6d). If the part is narrow
enough, the print head can deposit an entire layer in
one pass. Otherwise, the head makes several passes.
Sanders
Prototype of Wilton, NH (www.solid-scape.com) uses a
different ink-jet technique in its Model Maker line
of concept modelers. The machines use two ink-jets (see
Figure 6c). One dispenses low-melt thermoplastic to
make the model, while the other prints wax to form supports.
After each layer, a cutting tool mills the top surface
to uniform height. This yields extremely good accuracy,
allowing the machines to be used in the jewelry industry.
Ballistic
particle manufacturing, depicted in Figure 6b, was developed
by BPM Inc., which has since gone out of business.
Figure
6: Schematic diagrams of ink-jet techniques.
Notes
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