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AM Powder Flowability Capabilities at NASA Marshall Space Flight Center (MSFC) Additive Manufacturing (AM) powder flowability is critical to metal 3D printing, because the more fluid the powder is, the better powder spreads. AM Powder Flowability Capabilities at NASA MSFC studies density, flow, particle size distribution, and morphology for programs such as Moon-to-Mars Planetary Autonomous Construction Technology (MMPACT), ASTM Proficiency Testing for AM and Powder Metallurgy, and MSFC’s AM team. Examining and measuring powder characteristics is essential for improving flowability of AM powder and ensuring lot-to-lot consistency, which will help to prevent defects in manufactured parts. The Contamination Control Team (CCT) uses several methods to characterize AM powder. Optical particle size distribution and morphology analyses determine particle parameters including size, circularity, convexity, and dimensions. The Carney and Hall Flowmeter Funnel measures time it takes powder to flow through a funnel to compare relative flowability (free-flowing and non-free-flowing). In addition to this, the device utilizes a density cup which determines apparent density. Lastly, the Revolution Powder Analyzer measures dynamic powder flowability and behavior over time via digital imaging. Using the CCT’s lab, the team has produced ASTM Powder Proficiency Testing results with flow rates, apparent density, particle size distribution, and tap density on titanium-based and nickel-based powder and compared data with other companies/labs. Morphology data was also collected for various regolith simulant powder for the MMPACT program. Lastly, the CCT used morphology data to examine the flowability of Inconel 718 powder for Selective Laser Melting (SLM) and Directed Energy Deposition (DED) printers at MSFC. The CCT’s essential work in studying and enabling AM powder characterization has helped and will continue to help study new and refined powders in the AM industry.
Document ID
20230007595
Acquisition Source
Marshall Space Flight Center
Document Type
Presentation
Authors
Justin McElderry
(Marshall Space Flight Center Redstone Arsenal, Alabama, United States)
Richard Boothe
(Marshall Space Flight Center Redstone Arsenal, Alabama, United States)
Date Acquired
May 15, 2023
Subject Category
Metals and Metallic Materials
Meeting Information
Meeting: National Space & Missile Materials Symposium (NSMMS)
Location: Tucson, Arizona
Country: US
Start Date: June 26, 2023
End Date: June 29, 2023
Sponsors: Northrup Grumman
Funding Number(s)
WBS: 585777.08.20.20.68.05.01
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.
Keywords
Additive Manufacturing
AM Powder Characterization
Powder
Morphology
Particle Size Distribution
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