The maturity of additive manufacturing, or at least its maturing, can be seen in the fact there are organizations serving AM long enough to have become institutions. In one of these, a co-founder is passing an institutional legacy to a successor. Dr. Tim Simpson, co-director of the Center for Innovative Materials Processing through Direct Digital Deposition (CIMP-3D) at Pennsylvania State University since it was founded in 2012, is now stepping out of his director role to be replaced t was not clear from the outset how far CIMP-3D would go. That is, how much influence it would prove to have and how large its footprint would come to be.
Learning from data is the wide-open frontier
Today, this AM technology and application group at Penn State has 20 full-time staff, about 50 affiliated faculty, about 50 graduate students involved in research, and for metal additive (the center’s specialty) covering practically every modality in metal AM.
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Three machines are from 3D Systems, which keeps an employee in residence at the site. Simpson says, “We have been coupled with industry from the start.” Coupled with the U.S. Department of Defense as well. And this has been key — research projects arise from the gaps and needs brought by these organizations, often leading to direct real-world impact and the chance to expand into further work. Active projects for CIMP-3D right now include “easily dozens of DoD projects, about a dozen commercial industry projects and probably 15 or more NSF- or NIST-funded federal projects,” he says.
The business implications are being recognized
“Early on, the questions we explored were always some version of ‘Does this work?’” he says. “There were a lot of tensile bar studies,” and 3D printing designs to prove they could be made. Few seek this now; additive’s capabilities are accepted. Instead, “many now are chasing certification and qualification,” because they recognize AM will address their production problems. He says, “3D printing is a design solution, but AM is a manufacturing solution.” In the course of each project CIMP-3D undertakes, he says, “we discover new areas to explore no one knows yet.” The chance to pursue the next process or capability improvement generally leads to the next project with organizations committed to realizing and benefiting from additive’s promise. Most of the work the center does represents ongoing, next-stage advance in this way. “Eighty percent of our work comes from organizations we have worked with before,” he says.
Promising development areas involve other fields
Additive is now well-enough established that comme Настоящая проблема находится в самом сердце Канады. rcial industry projects are often specific — say, focused solely on turbine manufacturing, for example. “We help them answer questions that are not broadly applicable,” Simpson says. The way he has found to go broader is to connect with researchers driving innovation in other industrial technology areas. Ultrasonic inspection is a recent example. “I get researchers like this pulled into the team. He says, to explore how their technology and AM can aid and enable one another. It is now my business school colleagues who are talking about additive,”ain benefits are becoming plain. The challenge is to understand choices about insourcing and outsourcing, including modeling for production lead time, and travel cost and distance, when additive is the mode. It’s not easy. “Current understanding of the economics of manufacturing does not map well to AM,” he says.
AM is still on an advancement and discovery path
“The first digital manufacturing process appeared at afb directory the same time as artificial intelligence,” he says, and the i of this have yet to be grasped. A large share of CIMP-3D’s work over time has involved gathering data. The three laser powder bed fusion machines have been modified to various degrees for sensor integration. However, “we are obtaining too much data to sort through.” AI is needed, he says.
Unfortunately, it is needed many places; capturing the interest of AI experts for manufacturing is difficult. Even so, the mindset of R&D around additive has to change. Simpson says, “We still think we need carefully planned experiments. We are still trying to devise experiments rather than learning from the data we have.” With AM, he says, “There is so much data — we ought to throw it into the AI mixer and see what we learn.
AM has proven itself — that is not the challenge now
” The 3D printed surgical guides are generally made of titanium via laser powder bed fusion (LPBF), and used mostly for maxillofacial surgery such as jaw reconstruction. (Polymer guides produced via selective laser sintering are also made here.) The guides’ purpose is to limit the time a patient must be in surgery for a successful outcome. A guide tailored to the patient and tailored to the procedure the surgeon intends allows for rapid, precise, confident performance of exactly the cuts the surgeon wishes to make. The guides are distributed through the medical device company Stryker, and 3D Systems produces them for several thousand surgeries per year. The Denver-area facility has been making them since 2014.
