 An
extrusion blow-molding machine consists of an extruder that melts the
plastic and forms it into a molten tube (called a parison or preform)
through a conventional-type die and a split-body mold. The die closes
around the parison, sealing both ends, and a blow pin is inserted into
the parison to inflate it, causing it to expand and conform the shape of
the mold cavity. Again, the mold is cooled and once the part has
solidified, the mold opens and the part is removed. Extrusion
blow-molding is a continuous process that is used to mostly to
manufacture small, thin-walled parts but can produce parts as large as
44-gal drums.
An injection blow-molding machine consists of a number of stations
with various devices at each station. In one such machine in the first
station, the mold is closed and, with the aid of a mandrel, a hollow
injection-molded preform is created. (A mandrel is a piece of steel that
allows a hollow to be formed in extrusion or injection molding by
filling the part of the cavity that would otherwise be filled by the
melt. It is sometimes called a tongue.)
The mold then opens and the hot and soft preform is indexed to the
blow station on the machine, where the final shape mold closes. Air is
introduced through the mandrel to inflate the part to conform to the
internal cavity of the mold. Once cooled, the mold opens, and the part
is indexed to the ejection part of the machine where the finished part
is removed from the mandrel.
In
plunger type machines all the heat for melting the plastic is supplied
by external heaters. In screw type machines the shear heating of the
resin between the screw flights provides a large contribution to heating
and barrel heaters are used to produce complete melting and for
controlling the final temperature of the melt, as in most injection
molding machines. The spreader or torpedo is used to produce uniform
flow around machine component peripheries and to produce desired
flow-induced molecular structure.
Blow Molding Molds
In addition to the mold cavity which determines part
geometric characteristics, blow molding molds have many features that
influence process operation, efficiency and effectiveness in terms of
part quality. Coolant flow channels are provided to accelerate part
cooling and so reduce cycle time. In blow molding the general intent is
to cool the part to a suitable ejection temperature as quickly as
possible. In the production of preforms in injection blow molding the
coolant may be heated to a temperature lower than the melt temperature
but high enough so that the preform can be directly transfered to the
blowing station with no, or little, temperature conditioning.
There are raised regions on the die face to pinch off and seal the
parison before blowing. Recessed regions are provided for flash to flow
into, and so minimize the potential for mold separation due to flashing.
Mold inserts are separate components fitted to the mold to produce
specific features, e.g., a thread insert used to produce threads on the
neck of a container. Vents are small channels, perhaps with a porous
plug at the mold wall end, to allow air to escape from between the part
wall and mold surface.
Since blow molding pressures are relatively low compared to other
molding operations, mold material strength is not as important and a
large proportion of molds are made from high strength aluminum alloys.
However, mold wear may become a problem. Plated steel and
beryllium-copper are alternative materials for molds or these more
wear-resistant materials can be used for various components of aluminum
molds, e.g., inserts and pinchoffs.
Product Characteristics and Process Design
In some situations product end-use and required part
performance determine almost all product design requirement. This is
usually the case in high-performance parts and products. In contrast,
for many large lot, high production rate operations the effects of part
design on process performance must be included in part design. In a very
general sense, this means that part production cost is more important in
some situations than in others. And, in cases in which production
process costs are important part design should include explicit
consideration of part design features that influence process operation
and efficiency.
For example, in blow molding of large quantities of inexpensive parts
process cycle time must be as short as feasible. The largest part of
cycle time may be the cooling and solidification phase of the part
production cycle. Minimizing cooling time implies not only effective
process design and efficient process operation - e.g., material
transport and cooling - but also the inclusion of cooling time
considerations in part design. Such cycle time considerations lead to
injection molded parts designed with thin sections and minimum wall
thickness in blow molded products.
In plastic parts with mechanical performance requirements such as
strength or deflection specifications, part designs are often
complicated. The requirement for short cycle time leads to parts with
thin sections. Mechanical behavior requirements lead to complicated
shapes so that thin section parts perform adequately, e.g., ribs, webs,
double curvature, etc.
Blow molded part shapes have to be simple since the the parts are
hollow and pneumatic pressure is used to inflate the parison. Overall
part shape and outside surface features are set by the mold and these
may be complex. However, part inner surface features are limited.
Available part design variables are overall shape, local part geometry,
wall thickness and material properties. |
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