Plastic Injection Molding
Injection Molding produces plastic parts by forcing molten material into a
mold where it cools and hardens. The molded shape produced is a reverse image of the mold tool. Injection molding
is low cost for
simple and complex parts. Tooling adds to the initial cost but is quickly amortized.
With injection molding, granular plastic is fed by gravity from a hopper
into a heated barrel. As the granules are slowly moved forward by a screw-type plunger,
the plastic is forced into a heating chamber, where it is melted. As the plunger advances,
the melted plastic is forced through a nozzle that rests against the mold, allowing it to
enter the mold cavity. The mold remains cold so the
plastic solidifies almost as soon as the mold is filled.
Injection molding is an extremely versatile process for producing a wide
range of simple or complex plastic parts - economically and with a good finish. Injection
molding's efficiency varies by the number of parts you plan to produce. For small
quantities it is usually less expensive to simply machine the desired parts.
Possible shapes
A wide variety of simple or complex 2D or 3D shapes.
Plastic Injection Molding Design Guidelines
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Keep walls thin - typically between 1/32" and 1/10". This allows for proper
cooling and reduces cost by minimizing use of material. Thin walls also reduce problems
with material shrinkage. Although some unevenness will occur due to shrinkage, walls as
thick as 1/5" can be used. Keep wall thickness at least wall length / 50.
Keep 90 deg walls under 0.25" high. Keep thickness of
ejection pin surface wall at least .07".
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To strengthen parts, instead of using thicker walls, use additional structures such as
ribs. When using a rib, make the rib about half the
main wall thickness. Use fillets at the base of ribs.
Avoid shapes that are impossible to remove from the mold.
Lighter colors hide flow patterns better than dark colors. Choose the right material from
the table on the right. Drawing dimensions should be of the final part - material
shrinkage will automatically be considered in the design of the mold. Use raised text
instead of recessed text when possible. Where walls meet at a 90 angle, round inside and
outside to at least .05" radius - sharper
outside corners can create molding problems and sharper inside corners will increase
tooling cost. Keep holes at least
.015" from edges. It should not be possible to fully hide a 0.3" diameter ball
anywhere inside the material.
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Example parts
Injection molded parts are widely used in:
aerospace, automotive, engineering prototypes, hydraulics and pneumatics, packaging,
architecture, appliances, fiber optics, medical and dental, power tools, agriculture,
electronics, geophysics, measuring instruments, telecommunication, caps, enclosures, valves, toys, levers, cams, etc.
Advantages of Plastic Injection Molding
Low cost and good repeatability. Extremely cost efficient in
larger quantities.
Specifications for Plastic Injection Molding
 Material - ABS,
acrylic, polycarbonate, high density polyethylene, acetyl, polyamide,
low density polyethylene, polypropylene, filled and blended plastics.
Alternative machines
- Mill 3-Axis (for short runs).
Tooling - custom
mold for your design.
Reducing costs - minimize size and material volume, avoid sharp corners on
all features - for example a round post is better than a square post.
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Notes
 You can arrange multiple pieces in one mold by connecting them with small bars
~0.1", however the sub-components must not have widely varying volumes. When the
design does not allow for additional structures to improve strength, consider using a
stronger material, such as glass fiber filled plastic. Consider specifying a fire
retardant material when necessary. Contoured parts warp less than flat parts.
If desired specify the following:
Where to place the gate - the location where plastic is injected - a
small rough spot will appear at this location.
Where to place the parting line - the location where the two mold halves
meet - a thin line will appear at this location.
What surface finish to use - polished, matte, textured.
A small slightly rough spot appears at the Gate. A thin line appears at
the Parting Line. A circular mark appears at the ejector pin locations.
Living Hinges - A Living Hinge is a thin
connection provided between two sections of a molded part so that it can be used as a
hinge, e.g. a box, with a lid, molded as one piece. You can use living hinges in your
injection molded parts.
Multiple parts in one design - In some
cases you can design several different parts in one tool to avoid the cost of making
separate molds for each part. Generally the limit is about four if the parts are fairly
different and up to 24 if the parts are nearly identical. To have multiple parts in one
tool, join the parts together with a narrow connecting channel. If desired, you can
"Remove connecting links". Combining parts in one mold does not always decrease
the cost - check pricing both ways.
Box seams - Since a seam between two
halves of a box is difficult to fully hide, most designers make the seam pronounced - more
visible - to make it look like it is decorative. Look at some molded products to see some
styles.
Insert Molding - A screw driver with a
plastic handle is an example of insert molding. Injection molding is performed around a
metal (or another plastic) part. Additional examples include threaded metal inserts and
electrical plugs.
Material Selection
Material |
Colors |
Stiffness |
Dimensional tolerance |
Intricate design |
Dark colors |
Max wall thickness, mm |
ABS |
Many |
High |
Good |
Good |
Fair |
5 |
Nylon |
Many |
High |
Good |
Fair |
Fair |
4 |
Delrin |
Usually white |
Med |
Good |
Good |
Good |
4 |
Polyethylene |
Many |
Low |
Poor |
Good |
Good |
4 |
Polypropylene |
Many |
Low |
Fair |
Good |
Good |
2 |
Polystyrene |
Many
(translucent, opaque,
transparent, tinted) |
Low |
Good |
Good |
Good |
5 |
Polycarbonate |
Many
(translucent, opaque, transparent, tinted) |
Med |
Good |
Good |
Fair |
4 |
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