Additive Manufacturing and CNC Machining: Separate Together? Hear the Recorded Webinar
A maker of CNC machine tools and a maker of AM technology come together to describe integrating additive and subtractive into an efficient process for production.
A production cell employing both additive and subtractive processing. Machining cycle times are shorter than additive build times, so only one machining center is needed to support the three additive machines. An unloading station allows for parts that need to be removed from the cell for heat treatment after the additive build but prior to machining.
Examples of freeform parts built using RPM’s laser deposition technology for metal additive manufacturing. A close look at this selection reveals that even some of these sample parts have been machined.
This 23-inch diameter Inconel 718 combustor case demonstration part was grown additively in a cycle that took 132 hours. The part made this way is an example of a process involving a long build time and shorter machining time. But likely there are other ways of thinking about using additive and subtractive together for a part like this, the presenters note. Rather than growing the entire form, for example, perhaps an initially machined shell could have the features extending from the OD grown onto it additively.
The presentation by Wade Anderson of Okuma and Robert Mudge of RPM Innovations is available for viewing in its recorded version. As part of the talk, Mudge discusses the strengths and operation of his company’s laser deposition technology.
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Wade Anderson of Okuma, a machine tool builder, and Robert Mudge of RPM Innovations, a maker of metal AM technology using laser deposition, recently collaborated to deliver a webinar on integrating subtractive and additive operations into an automated process for part production. Their presentation, “Using Additive AND Subtractive Manufacturing to Multiply Productivity,” can now be heard in itsrecorded version.
A process that is able to leverage these two capabilities together could generate a finished, high-value part with very little in the way of prior processing. That is, the capabilities of additive could be used to create an intricate part without any need for casting, forging or assembly of smaller components, while machining could then ensure that this part meets tight tolerance requirements for dimensions and surface finish.
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But does the use of additive and subtractive together in this way mean that both of the operations ought to occur in the same machine?
Not necessarily, the two men say. In full production, they argue that the more efficient and effective process is likely to be the one that keeps these operations separate, but links them together through some kind of shared automation such as a flexible manufacturing system (FMS). Arguments for keeping the capabilities separate can be found on both the additive and subtractive sides.
玛吉解释了为什么金属是favo的效率rs keeping this operation in its own machine. The reasons he gives include:
- Moisture control.The use of coolant impedes control over the argon environment of the laser machine.
- Material efficiency.In a dedicated AM machine, much of the metal powder not used in a given build can be reclaimed. But letting the powder become mixed with chips prevents this reclamation.
- Secondary processing.The part might require a heat treatment process prior to machining. Separating the machines makes it easier for a step such as this to come between the two operations.
Wade, meanwhile, sees the argument from the machining side. He says, “In the machine tool world, the biggest opportunity we see for efficiency gain isincreased utilization.” Combining machining and additive into one machine negatively affects utilization, he says, because it removes opportunities to balance the use of both capabilities. Additive is liable to proceed far more slowly than the subtractive cutting. That is why, in the FMS cell that he and Mudge propose, a single five-axis machining center is sufficient to support the output of three RPM laser deposition machines linked to the same cell. (See video animation of that cell withinthis article.)
Mudge picks up on the utilization point with a detailed cost breakdown that considers a part requiring 40 hours of subtractive build time and 10 hours of machining. Within the 50 total hours required to make this part, the separation of the two operations between different machines leaves the machine tool open to take on 40 hours of additional work (not to mention freeing up 10 hours on the additive machine).
To see Mudge’s analysis within the full presentation on additive and subtractive, including to the audience questions asked while the presentation was live,view the archived webinar.
