Three advantages and cautions about injection molding

Relative to traditional manufacturing processes like CNC machining which cut away substantial percentages of an original plastic block or sheet, scrap rates are so low. Note: waste plastic from injection molding manufacturing typically comes consistently from four areas: the sprue, the runners, the gate locations, and any overflow material called “flashing”.

The second part you produce is going to be practically identical to the first one. This is a wonderful characteristic when trying to produce brand consistency and part reliability in production. Plastic injection molding is such a precise method that the finished product to be very precise. In fact, accuracy is typically within 0.005 inches.

Most polymers may be used for injection molding, including all thermoplastics, some thermosets, and some elastomers. One cool benefit of plastic injection molding is that fillers can be added to components during processing, reducing the density of the liquid plastic while adding enhanced strength to the finished part. Plastic injection molding is an ideal process for industries or products where parts need to be strong. This allows product designers to choose from a vast selection of materials so they can choose exactly the right properties for the injection molded parts they need.

Upfront costs can be very high due to design, testing, and tooling requirements if you perform conventional injection molding practices. If you will produce parts in high volumes, you want to make sure you get the design right the first time. That is more complicated than you might think. Getting the design right includes:

-Initial prototype development is typically completed on a 3D printer and often in a different material (such as ABS plastic) than the final part will be constructed in

-Designing an injection mold tool for an initial production round

-Refining any and all details in the injection mold tool prior to mass-production in an injection mold manufacturing plant.

Tooling for industrial injection molding machines is a huge project. Before you can produce an injection molded part, you first have to design and prototype a part (probably via CNC or 3D printing), then you have to design and prototype a mold tool that can produce replicas of the part in volume. As you can imagine, all of the iteration required to get the tool correct prior to mass production requires both time and money. The APSX-PIM can save you a lot of time and money due to its small and aluminum molds by allowing you have multiple trial runs with a very low cost approach.

If you want to add plastic to the part you can always make the tool cavity larger by cutting away steel or aluminum. But if you are trying to take away plastic you need to decrease the size of the tool cavity by adding aluminum or metal to it. With APSX-PIM standard molds, it is not that expensive to make another version of the tool.

The goal is usually to choose the thinnest wall possible. Thinner walls use less material which reduces cost and take less time to cool, reducing cycle time. Keeping walls from being too thick is important to prevent inconsistencies in the cooling process resulting in defects like sink marks. A good rule of thumb is to keep walls less than or equal to 4mm thick. Conversely, if wall thickness is any thinner than 1mm or so, you might experience trouble filling the mold tool. Designers can compensate for this potentiality by using a material with a higher melt flow index like Nylon which is often suitable for walls as thin as 0.5mm.

Entry Cost: Typically, preparing a product for injection molded manufacturing requires a large initial investment if you use a large industrial size injection molding machinery. A mold can cost anywhere from $10,000 for a simple part up to $50,000 or more for a complicated part. Remember: The APSX-PIM costs only $12,500 and each mold averages around $2,000.

Production Quantity: Determine the number of parts produced at which injection molding becomes the most cost effective and the number of parts produced at which break even on investment

Part Design: You want to design the part from day one with injection molding in mind. Simplifying geometry and minimizing the number of parts early on will pay dividends down the road.

The main enemy of any injection molded plastic part is stress. When a plastic resin is melted in preparation for molding, the molecular bonds are temporarily broken due to the heat and force. As the molecules are pushed through each feature, they are forced to bend, turn and distort to form the shape of the part. As the material cools and the molecular bonds re-link the resin into its rigid form, these stresses are in effect locked into the part. Part stresses can cause warpage, sink marks, cracking, premature failure and other problems. You should design your parts with as much consideration for stress reduction as possible. Some ways to do this are by adding smooth transitions between features and using rounds and fillets in possible high stress areas.

The gate type and location selection are also an important factor for proper mold design. Place gates at the heaviest cross section to allow for part packing and minimize voids & sink. Be sure that stress from the gate is in an area that will not affect part function or aesthetics. Gates vary in size and shape depending upon the type of plastic being molded and the size of the part. Large parts will require larger gates to provide a bigger flow of resin to shorten the mold time. Small gates have a better appearance but take longer time to mold or may need to have higher pressure to fill correctly.