In this article, we gave an overview of how 3D printing is used to fabricate molds and dies for injection molding and die casting. In particular, additive manufacturing (AM) can be more cost-effective for small batches of parts; however, in some cases, the technology can provide some benefits that are unique to 3D printing, regardless of batch size. This is particularly true of 3D-printed metal molds and dies that can survive much longer than plastic molds discussed in part one.
The biggest benefit that 3D-printed molds and dies offer, regardless of batch size, is the ability to integrate conformal cooling channels (air passages that follow the shape of the mold/die cavity and core) that would be impossible with traditional technologies.
As it stands, molds and dies are typically made with CNC machines, with cooling channels usually drilled in secondary machining operations. As a result, heat dissipates more unevenly, leading to internal stresses and warpage within the part itself. More complex cooling strategies can be achieved through the addition of features called baffles, bubbles, and isobars, which increase the labor and cost of the part. If necessary, tooling might have to be made in segments for more intricate channels to be incorporated. The mold/die is then soldered together, which naturally shortens the life of the tooling.
With AM, cooling channels can be printed in any shape and closer to the part than possible with subtractive techniques. This, in turn, can improve part consistency, while also reducing cooling times, which in turn cuts down the time it takes to make a new part (referred to as “cycle times”). Fewer defective parts also mean less material scrap.
There are numerous examples where 3D-printed molds have improved the injection molding process. Czech tool manufacturer Innomia cut cycle time by 17 percent, ultimately also reducing production time to market from 18 to 13 days. Polish tooling and injection molding company FADO reduced cycle times by 30 percent. Linear Molds, of Michigan, reports that 20 to 30 percent of its tooling sales are 3D-printed inserts. Oyonnax Cedex was able to reduce the temperature of its tooling by 20°C, resulting in a 20-second drop in cooling times. Laser Bearbeitungs Center was able to cut its cycle time by 60 percent and scrap rate from 50 percent to zero.
The introduction of conformal cooling channels is really just the beginning of the benefits that 3D printing brings to the fabrication of molds and dies. The use of simulation software makes it possible to optimize the cooling pathways to reduce cooling and cycle time that much more. Topology optimization, generative design, and other simulation-based modeling techniques can be further applied to reduce the material used to fabricate the tooling, thus making the part lighter and easier to move, as well as cutting cooling time even more.