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Troubleshooting Styrene Acrylonitrile
Styrene acrylonitrile (SAN) resins are transparent with excellent
clarity, good surface gloss, dimensional stability, heat resistance,
environmental stress-crack resistance, hardness, load-bearing capabilities,
processing ease and good economics. Most common formulations have
about 75% styrene monomer; are available in a range of grades, including
glass-reinforced and high-heat distortion; common additives include
plasticizers, mold-release agent, colorants, and UV stabilizers. Applications
include safety glazing, cassette housings, consumer goods (dishwasher-safe
mugs, tumblers, dinnerware, utensils; pen and pencil barrels, hobby-kit
parts), appliances (refrigerator food trays, blender bowls, vacuum-cleaner
parts), medical (syringes, IV connectors), automotive (lenses and
instrument panels), packaging (cosmetics, bottles, nozzles), and industrial
(battery cases and caps, instrument and meter lenses). Although the
resins are commonly injection molded, they can also be extruded, compression
molded and injection blow molded. As is generally the case, proper
molding conditions are affected by the process chosen, the equipment
used and the part to be produced and it is recommended that processors
discuss particular needs with their resin supplier. SAN is hygroscopic
and can absorb as much as 0.6% moisture encouraging splay, streaks
and other surface defects. Therefore, the pellets should be dried
prior to processing for two or more hours. Dried pellets can reabsorb
moisture from humid air, so unless they are used within two to four
hours, they should be protected from again picking up moisture. The
resin can also experience a color shift towards yellow during its
lifetime, and so the use of regrind should be monitored carefully.
Design guidelines
The fundamental design principles used with other engineering thermoplastics
are equally valid with SAN. · Wall thickness transitions: A nominal
wall thickness of 0.125 inch is commonly used. Functional wall thickness
as thin as 0.020 inch may be designed. Material flow should be from
thick to thick sections to avoid high stresses. Gating should be in
the thickest area to allow a smooth transition to thinner sections.
Gating in thinner sections can cause sinks and warping in thicker
sections, and can result in excessive molded-in stresses in thin areas.
· Fillets and radii: Generous radii reduce molded-in stresses and
allow loads to be is distributed over a wider area. All corners should
have an optimum inside radius of 50% and an outside radius of 150%
of the wall thickness. · Ribs: Properly designed and located ribs
allow an overall reduction in wall thickness and part, weight, and
increase the load-bearing ribs are preferable to thick ones, which
can result in bubbles, sink marks, and stress-concentration points.
The polymer's flow length and wall thickness are the important factors
in determining rib thickness. General guidelines are: radii - minimum
0.25 X wall thickness: rib height - maximum 3 X nominal wall thickness;
rib thickness - maximum 0.75 X nominal wall thickness. · Undercuts:
Snap-off undercuts can cause high stresses and generally are not recommended
Cam-action undercuts perform satisfactorily. Concerning model design,
the following should be addressed: · Tolerances: The predictable low
shrinkage of SAN allows for excellent dimensional control when designing
molds. Actual tolerances depend on the part design. · Gating: Gate
design, size and location are determined by the type of mold, the
size and shape of the part, and the resin. With SAN, the gate diameter
at the part wall should beat least equivalent to the wall thickness,
and located where the wall thicknesses are greater. To minimize gate
blush and jetting, gates should be positioned so the melt goes against
the core, core pin, or cavity wall. · Venting: Gas entrapment, which
may cause brown spots, is prevented by adequate mold venting, which
also allows faster filling. Vents should not exceed 0.0020 inch in
depth. If possible vents should be located around the entire perimeter
of the mold, and wherever the polymer flow pattern could result in
air entrapment. · SAN parts can be welded to each other with several
effective solvents. If a fast-drying solvent adhesive is desired,
menthylene chloride is commonly used. Effective medium-drying solvent
adhesives are methyl ethyl ketone, and a mixture of 30% methyl methacrylate
monomer and 70% butyl acetate
Courtesy: Mr. P.M. Jariwala, Kolsite Industries
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