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Injection moulding
Injection molding (British English: moulding) is a manufacturing process
for producing parts from both thermoplastic and thermosetting plastic
materials. Material is fed into a heated barrel, mixed, and forced into
a mold cavity where it cools and hardens to the configuration of the mold
cavity (manufacturing processes reference guide, p240). http://www.thefreedictionary.com/injection+molding]
After a product is designed, usually by an industrial designer or an engineer,
molds are made by a moldmaker (or toolmaker) from metal, usually either
steel or aluminium, and precision-machined to form the features of the
desired part. Injection molding is widely used for manufacturing a variety
of parts, from the smallest component to entire body panels of cars. Injection
molding is the most common method of production, with some commonly made
items including bottle caps and outdoor furniture. Injection molding typically
is capable of tolerances equivalent to an IT Grade of about 9–14.
While typical tolerance for thermoplastic and thermoset is ±.008
in., tolerance of ±.002 in. is feasible.[1]
Standard two plates tooling – core and cavity are inserts in a
mold base – "Family mold" of 5 different partsThe most
commonly used thermoplastic materials are polystyrene (low cost, lacking
the strength and longevity of other materials), ABS or acrylonitrile butadiene
styrene (a ter-polymer or mixture of compounds used for everything from
Lego parts to electronics housings), polyamide (chemically resistant,
heat resistant, tough and flexible – used for combs), polypropylene
(tough and flexible – used for containers), polyethylene, and polyvinyl
chloride or PVC (more common in extrusions as used for pipes, window frames,
or as the insulation on wiring where it is rendered flexible by the inclusion
of a high proportion of plasticiser). Plastics reinforced with short fibres
can also be injection molded.
Equipment
Paper clip mold opened in molding machine; the nozzle is visible at rightMain
article: Injection molding machine
Injection molding machines consist of a material hopper, an injection
ram or screw-type plunger, and a heating unit(manufacturing processes
reference guide, p240). They are also known as presses, they hold the
molds in which the components are shaped. Presses are rated by tonnage,
which expresses the amount of clamping force that the machine can exert.
This force keeps the mold closed during the injection process. Tonnage
can vary from less than 5 tons to 6000 tons, with the higher figures used
in comparatively few manufacturing operations. The required force is determined
by the material used and the size of the part, larger parts require higher
clamping force.
Mould
Mould or die are the common terms used to describe the tooling used to
produce plastic parts in molding.
Traditionally, moulds have been expensive to manufacture. They were usually only used in mass production where thousands of parts were being produced. Moulds are typically constructed from hardened steel, pre-hardened steel, aluminium, and/or beryllium-copper alloy. The choice of material to build a mold from is primarily one of economics, steel moulds generally cost more to construct, but their longer lifespan will offset the higher initial cost over a higher number of parts made before wearing out. Pre-hardened steel molds are less wear resistant and are used for lower volume requirements or larger components. The steel hardness is typically 38-45 on the Rockwell-C scale. Hardened steel molds are heat treated after machining. These are by far the superior in terms of wear resistance and lifespan. Typical hardness ranges between 50 and 60 Rockwell-C (HRC). Aluminium molds can cost substantially less, and when designed and machined with modern computerized equipment, can be economical for molding tens or even hundreds of thousands of parts. Beryllium copper is used in areas of the mold which require fast heat removal or areas that see the most shear heat generated. The molds can be manufactured by either CNC machining or by using Electrical Discharge Machining processes
Injection moulding die with side pulls "A" side of die for
25% glass-filled acetal with 2 side pulls.
Close up of removable insert in "A" side.
"B" side of die with side pull actuators.
Insert removed from die.
Mould Design
Molds separate into two sides at a parting line, the A side, and the B
side, to permit the part to be extracted. Plastic resin enters the mold
through a sprue in the A plate, branches out between the two sides through
channels called runners, and enters each part cavity through one or more
specialized gates. Inside each cavity, the resin flows around protrusions
(called cores) and conforms to the cavity geometry to form the desired
part. This is similar to someone squeezing clay between their hands so
that when it is removed, it matches the shape of the hollow of their cupped
hands.
The amount of resin required to fill the sprue, runner and cavities of a mold is a shot. When a core shuts off against an opposing mold cavity or core, a hole results in the part. Air in the cavities when the mold closes escapes through very slight gaps between the plates and pins, into shallow plenums called vents. To permit removal of the part, its features must not overhang one another in the direction that the mold opens, unless parts of the mold are designed to move from between such overhangs when the mold opens (utilizing components called Lifters).
Sides of the part that appear parallel with the direction of draw (the direction in which the core and cavity separate from each other) are typically angled slightly with (draft) to ease release of the part from the mold, and examination of most plastic household objects will reveal this. Parts with bucket-like features tend to shrink onto the cores that form them while cooling, and cling to those cores when the cavity is pulled away. The mold is usually designed so that the molded part reliably remains on the ejector (B) side of the mold when it opens, and draws the runner and the sprue out of the (A) side along with the parts. The part then falls freely when ejected from the (B) side. Tunnel gates tunnel sharply below the parting surface of the B side at the tip of each runner so that the gate is sheared off of the part when both are ejected.
Ejector pins are the most popular method for removing the part from the B side core(s), but air ejection, and stripper plates can also be used depending on the application. Most ejection plates are found on the moving half of the tool, but they can be placed on the fixed half if spring loaded. For thermoplastics, coolant, usually water with corrosion inhibitors, circulates through passageways bored through the main plates on both sides of the mold to enable temperature control and rapid part solidification.
To ease maintenance and venting, cavities and cores are divided into pieces, called inserts, and sub-assemblies, also called inserts, blocks, or chase blocks. By substituting interchangeable inserts, one mold may make several variations of the same part.
More complex parts are formed using more complex molds. These may have sections called slides, that move into a cavity perpendicular to the draw direction, to form overhanging part features. Slides are then withdrawn to allow the part to be released when the mold opens. Slides are typically guided and retained between rails called gibs, and are moved when the mold opens and closes by angled rods called horn pins and locked in place by locking blocks, both of which move cross the mold from the opposite side.
Some muolds allow previously molded parts to be reinserted to allow a new plastic layer to form around the first part. This is often referred to as overmolding. This system can allow for production of one-piece tires and wheels.
2-shot or multi-shot molds are designed to "overmold" within a single molding cycle and must be processed on specialized injection molding machines with two or more injection units. This can be achieved by having pairs of identical cores and pairs of different cavities within the mold. After injection of the first material, the component is rotated on the core from the one cavity to another. The second cavity differs from the first in that the detail for the second material is included. The second material is then injected into the additional cavity detail before the completed part is ejected from the mold. Common applications include "soft-grip" toothbrushes and freelander grab handles.
The core and cavity, along with injection and cooling hoses form the mould tool. While large tools are very heavy weighing hundreds and sometimes thousands of pounds, with the aid of a forklift or overhead crane, they can be hoisted into moulding machines for production and removed when moulding is complete or the tool needs repairing.
A mould can produce several copies of the same parts in a single "shot". The number of "impressions" in the mold of that part is often incorrectly referred to as cavitation. A tool with one impression will often be called a single cavity (impression) tool. A mould with 2 or more cavities of the same parts will likely be referred to as multiple cavity tooling. Some extremely high production volume moulds (like those for bottle caps) can have over 128 cavities.
In some cases multiple cavity tooling will mold a series of different parts in the same tool. Some toolmakers call these moulds family moulds as all the parts are not the same but often part of a family of parts (to be used in the same product for example).
Effects on the material properties
The mechanical properties of a part are usually little effected. Some
parts can have internal stresses in them. This is one of the reasons why
it's good to have uniform wall thickness when molding. One of the physical
property changes is shrinkage. A permanent chemical property change is
the material thermoset, which can't be remelted to be injected again.
Geometrical Possibilities
The most commonly used plastic molding process, injection molding, is
used to create a large variety of products with different shapes and sizes.
There are a few precautions when designing something that will be made
using this process to reduce the risk of weak spots. First, streamline
your product or keep the thickness relatively uniform. Second, try and
keep your product between 2 to 20 inches.
The size of a part will depend on a number of factors (material, wall thickness, shape,process ect). Here are some ranges of the sizes.
Method Raw Materials Maximum Size Minimum Size
Injection Moulding (thermo-plastic) Granules, Pellets, Powders 700 oz.
Less than 1 oz.
Injection Moulding (thermo-setting) Granules, Pellets, Powders 200 oz.
Less Than 1 oz.
Machining
Moulds are built through two main methods: standard machining and EDM.
Standard Machining, in its conventional form, has historically been the
method of building injection molds. With technological development, CNC
machining became the predominant means of making more complex molds with
more accurate mold details in less time than traditional methods.
The electrical discharge machining (EDM) or spark erosion process has become widely used in mold making. As well as allowing the formation of shapes which are difficult to machine, the process allows pre-hardened molds to be shaped so that no heat treatment is required. Changes to a hardened mold by conventional drilling and milling normally require annealing to soften the steel, followed by heat treatment to harden it again. EDM is a simple process in which a shaped electrode, usually made of copper or graphite, is very slowly lowered onto the mold surface (over a period of many hours), which is immersed in paraffin oil. A voltage applied between tool and mold causes spark erosion of the mold surface in the inverse shape of the electrode.
Typical Materials Used
Epoxy, nylon, polyethylene, and polystyrene are all used for this process.
Other material like phenolic requires special care and equipment to prevent
the material form curing before the mold is completely filled. Epoxy and
phenolic are both thermosetting plastics. When phenolic is used by injection
molding, the moldability is good. However the moldability of the other
four are excellent. Whichever of the five types of materials you choose,
they will be in pellet, powder, or granule form. [3]
Epoxy has a specific gravity of 1.12 to 1.24 and melts at 248 F, Nylon has a specific gravity of 1.01 to 1.15 and melts somewhere between 381-509 F, Phenolic has a specific gravity of 1.34 to 1.95 and melts at 248 F, Polyethylene has a specific gravity of .91 to .965 and a melting point of 230 to 243 F, and Polystyrene has a specific gravity of 1.04 to 1.07 and melts at 338 F.
Cost
The cost of manufacturing moulds depends on a very large set of factors
ranging from number of cavities, size of the parts (and therefore the
mold), complexity of the pieces, expected tool longevity, surface finishes
and many others. The initial cost is great, however the piece part cost
is low, so with greater quantities the overall price decreases.
Injection Moulding process
Small injection moulder showing hopper, nozzle and die area
Injection moulding cycle
For the injection moulding cycle to begin, four criteria must be met:
mould open, ejector pins retracted, shot built, and carriage forward.
When these criteria are met, the cycle begins with the mould closing.
This is typically done as fast as possible with a slow down near the end
of travel. Mold safety is low speed and low pressure mold closing. It
usually begins just before the leader pins of the mold and must be set
properly to prevent accidental mold damage. When the mold halves touch
clamp tonnage is built. Next, molten plastic material is injected into
the mold. The material travels into the mold via the sprue bushing, then
the runner system delivers the material to the gate. The gate directs
the material into the mold cavity to form the desired part. This injection
usually occurs under velocity control.
When the part is nearly full, injection control is switched from velocity control to pressure control. This is referred to as the pack/hold phase of the cycle. Pressure must be maintained on the material until the gate solidifies to prevent material from flowing back out of the cavity. Cooling time is dependent primarily on the wall thickness of the part but also depends on the material being molded. Production molding usually requires faster cooling. Water is often channeled throughout the dies to produce faster cooling times. During the cooling portion of the cycle after the gate has solidified, plastication takes place.
Plastication is the process of melting material and preparing the next shot. The material begins in the hopper and enters the barrel through the feed throat. The feed throat must be cooled to prevent plastic pellets from fusing together from the barrel heat. The barrel contains a screw that primarily uses shear to melt the pellets and consists of three sections. The first section is the feed section which conveys the pellets forward and allows barrel heat to soften the pellets. The flight depth is uniform and deepest in this section. The next section is the transition section and is responsible for melting the material through shear. The flight depth continuously decreases in this section, compressing the material. The final section is the metering section which features a shallow flight depth, improves the melt quality and color dispersion. At the front of the screw is the non-return valve which allows the screw to act as both an extruder and a plunger. When the screw is moving backwards to build a shot, the non-return assembly allows material to flow in front of the screw creating a melt pool or shot. During injection, the non-return assembly prevents the shot from flowing back into the screw sections.
Once the shot has been built and the cooling time has timed out, the mould opens. Mould opening must occur slow-fast-slow. The mould must be opened slowly to release the vacuum that is caused by the injection moulding process and prevent the part from staying on the stationary mould half. This is undesirable because the ejection system is on the moving mold half. Then the mould is opened as far as needed, if robots are not being used, the mold only has to open far enough for the part to be removed. A slowdown near the end of travel must be utilized to compensate for the momentum of the mold. Without slowing down the machine cannot maintain accurate positions and may slam to a stop damaging the machine. Once the mold is open, the ejector pins are moved forward, ejecting the part. When the ejector pins retract, all criteria for a molding cycle have been met and the next cycle can begin.
The basic injection cycle is as follows: Mould close – injection carriage forward – inject plastic – metering – carriage retract – mold open – eject part(s) Some machines are run by electric motors instead of hydraulics or a combination of both. The water-cooling channels that assist in cooling the mold and the heated plastic solidifies into the part. Improper cooling can result in distorted molding. The cycle is completed when the mold opens and the part is ejected with the assistance of ejector pins within the mold.
The resin, or raw material for injection molding, is most commonly supplied in pellet or granule form. Resin pellets are poured into the feed hopper, a large open bottomed container, which is attached to the back end of a cylindrical, horizontal barrel. A screw within this barrel is rotated by a motor, feeding pellets up the screw's grooves. The depth of the screw flights decreases toward the end of the screw nearest the mould, compressing the heated plastic. As the screw rotates, the pellets are moved forward in the screw and they undergo extreme pressure and friction which generates most of the heat needed to melt the pellets. Electric heater bands attached to the outside of the barrel assist in the heating and temperature control during the melting process.
The channels through which the plastic flows toward the chamber will also solidify, forming an attached frame. This frame is composed of the sprue, which is the main channel from the reservoir of molten resin, parallel with the direction of draw, and runners, which are perpendicular to the direction of draw, and are used to convey molten resin to the gate(s), or point(s) of injection. The sprue and runner system can be cut or twisted off and recycled, sometimes being granulated next to the moulding machine. Some moulds are designed so that the part is automatically stripped through action of the mould.