NSF Backs UNF Research to Stamp Out Defects in Metal 3D Printing

Home-NSF Backs UNF Research to Stamp Out Defects in Metal 3D Printing

Backed by a newly awardedNational Science Foundationgrant, researchers at theUniversity of North Floridaare developing an automated monitoring system that detects and corrects defects in metal 3D printing layer by layer, in real time.

Dr. Longfei Zhou, assistant professor of advanced manufacturing engineering, is leading the project alongside a team of undergraduate researchers, including advanced manufacturing engineering seniors Maria Fernanda Ocrospoma Figueroa, Tessa Baur, and Taylor Uhren.

Both Ocrospoma and Baur hold leadership roles in UNF’s SAMPE chapter and recently brought home top honours at the global Additive Manufacturing Competition atSAMPE 2026 Seattle, with Baur finishing first and Ocrospoma second.

A Layer-by-Layer Quality Control System

The core of the project is an automated monitoring system designed to observe each layer of a print in real time, identify irregularities as they emerge, and apply targeted corrections on the spot, rather than waiting until a build is complete to discover problems. By intervening early and precisely, the system aims to reduce failed parts without disrupting the broader printing workflow.

The team explained that catching problems before they compound translates directly into savings, fewer scrapped parts, lower operational costs, and a lighter environmental footprint. Beyond the lab, the team sees the work as a contribution to the long-term resilience of domestic manufacturing, where higher yields and greener production methods go hand in hand.

Beyond the technical outcomes, the project carries an educational and open-access mission. New course modules and lab activities will introduce students to the role of data and automation in modern manufacturing. The team also intends to release datasets, trained models, digital-twin software, and baseline decision policies publicly, so the benefits extend well beyond UNF.

An Industry-Wide Push to Close the Quality Gap

Laser powder bed fusion has become a cornerstone of advanced manufacturing, enabling the production of highly complex components for aerospace, healthcare, and energy sectors. Yet despite its capabilities, the process remains vulnerable to a subtle but costly flaw: streaking caused when the machine’s powder-spreading mechanism disturbs the metal bed mid-print. Left unaddressed, these streaks compromise structural integrity, forcing manufacturers to discard parts or restart entire builds, a drain on both materials and energy.

Source: 3D Printing Industry