Designing metal parts? By incorporating both CNC machining and metal 3D printing into your manufacturing toolbox, you not only enjoy far greater flexibility in part design, but also gain the ability to procure them in less time and more cost-effectively than ever before. In order to take advantage of this, however, you must understand the shared strengths and inherent differences of each process, and how to best use them to your benefit.
Nowhere is this relationship more significant than the bond that exists between CNC machining and direct metal laser sintering (DMLS), the leading technology for 3D printing complex metal parts. The latter can produce virtually any part shape using nothing more than a laser beam and a pile of metal powder, but it can be a slow process. Machining on the other hand is more limited in terms of geometry, but offers far faster production speeds. The choice, then, of which to use is primarily a question of A) can the part or parts be machined, and B) how many parts need to be made?
In many cases, the two manufacturing processes can work together. Examples? Oftentimes metal-based additive manufacturing relies on its subtractive alter ego to finish the job. Holes must be bored or reamed, threads tapped or thread-milled, critical surfaces milled, turned, or ground to size. At the very least, 3D-printed parts need some manual TLC in the form of cleaning, blasting, and support removal, pretty much guaranteeing a visit to the machine shop.
What does all this mean to you or anyone looking for the most effective way to manufacture functional prototypes and lower quantities of end-use metal parts? Plenty. By adopting a strategy where metal 3D printing and machining can be different steps in the same manufacturing process, you can leverage the best of both worlds, eliminating surprises, reducing costs, and improving part design. Here’s a handful of design considerations to think about before diving into your next metal part design project.
As mentioned at the beginning of this design tip, it’s important to have a solid grip on the processes used to make them. We know this may be common knowledge to many engineers, so bear with us for a few paragraphs.
Of the five additive manufacturing technologies used at Protolabs (which account for the lion’s share of all 3D printing processes everywhere), DMLS is the only one that prints metal. Similar to any powder bed printing process, it uses a laser (or lasers) to fuse flour-sized grains of metal powder within the machine’s build chamber. Starting from the bottom up, the machine fuses one paper-thin workpiece layer at a time, with a recoater blade dragging fresh powder across the top after each pass until the part is complete.
By comparison, machining uses super-hard cutting tools to remove metal, either by rotating said tool against and around a fixed workpiece (milling), or by moving a stationary cutting tool against and around a rotating workpiece (turning). There’s far more to the machining process than this micro-explanation, but what’s important to know right now is that machining picks up where DMLS leaves off. In other words, DMLS adds material in single layers. Machining removes material, sometimes in large hunks, but sometimes very lightly in order to attain fine surface finishes.
Although DMLS can create extremely complex shapes that might otherwise be un-manufacturable, it’s not without its limitations. For starters, significant heating and cooling of the metal takes place as the laser does its work, creating internal stresses that must be removed via post-build heat-treating. This means little to the people designing the part, except that stress relief equates to some amount of part movement and therefore some loss of accuracy. This is one reason—though not the only one—why even a well-designed DMLS-produced part requires machining of any part feature where tolerances tighter than ±0.1mm are required.
Another reason for combining DMLS and machining is surface finish. On a vertical or horizontal surface, DMLS produces part roughness about equal to a sand casting. All other surfaces will see some amount of stair-stepping, an effect that’s largely dependent on how the part is situated in the build chamber. If your part design requires a smooth finish, it will need to be blasted, sanded, or quite possibly machined. This last part is no big deal, unless your part design calls for a fine finish on a surface that the end mill, drill, or turning tool can’t reach. Whatever the case, be sure to call out such critical features on your CAD model when submitting to Protolabs, so the features needing secondary processing, including machining, can be identified.
Support structures should also be considered when designing metal parts in additive manufacturing. DMLS is a little like building a metal sandcastle—without some seashells and twigs to hold the thing together, the ramparts will fall, the architraves crumble. With DMLS, scaffold-like supports are needed to keep the semi-molten metal from drooping, curling, or otherwise misbehaving. Oftentimes, these supports can be removed with a Dremel tool, but machining may be the preferred method where larger part volumes are called for, or when the workpiece is headed to the machine shop anyway for one of the drilling, milling, or turning operations mentioned previously.
Unlike DMLS, which requires nothing more than a simple “build plate” to carry the workpiece through to completion, machined parts must be clamped, bolted, or otherwise securely fixtured to the machine to prevent cutting tool-induced movement. If your 3D-printed workpiece is composed entirely of curved, organic shapes (which is one of 3D printing’s greatest appeals), how will the machinist hang on to it for turning or milling? Check with an applications engineer at Protolabs, but you might need to design in a pair of parallel surfaces or some mounting holes by which to clamp the 3D-printed workpiece for machining.
Lastly, there’s the metal to think about. The lasers used by DMLS don’t really “care” how hard or tough a metal is, but cutting tools sure do. DMLS is known for its ability to 3D print aerospace- and medical-grade metals like titanium, Inconel, cobalt chrome, and others, and even though different laser parameters and build speeds may be called for, it does so with relative impunity. Machining those same metals, on the other hand, requires lighter depths of cut, slower speeds and feeds (a little machining-speak here), and will consume more cutting tools and machining time. To see all of Protolabs metal options for machining and 3D printing, head over to the material comparison guide. Beyond the guide’s list, you may have other materials-related questions.
For example, if Protolabs doesn’t machine a certain material, it doesn’t necessarily mean we also would not post-machine it in 3D printing—we might. For these specific questions, contact one of our applications engineers at 877-479-3680 or email@example.com.
The overall point is this: You can in fact leverage the best of both worlds—3D printing and machining—together for metal parts, but carefully consider the design options covered in this tip. Machining and metal 3D printing are deep, complex technologies, and it’s only by understanding how each will affect your design project that success will be achieved. Ask questions, embrace each process, and understand that both are close-knit partners in manufacturing.
If you have a metal part design that could benefit from combining 3D printing and CNC machining, you can indicate that during the 3D printing quoting process. When uploading your CAD file, select the custom finish option and add notes specifying which features or surfaces require additional finishing. You can also attach documents, like a drawing, to identify tolerances, surface finishes, and other manufacturing requirements.