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ASTM Selected Technical Papers
Structural Integrity of Additive Manufactured Parts
By
Nima Shamsaei
Nima Shamsaei
Symposium Chair and STP Editor
1
Auburn University
,
Auburn, AL,
US
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Steve Daniewicz
Steve Daniewicz
Symposium Chair and STP Editor
2
The University of Alabama
,
Tuscaloosa, AL,
US
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Nik Hrabe
Nik Hrabe
Symposium Chair and STP Editor
3
National Institute of Standards and Technology
,
Boulder, CO,
US
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Stefano Beretta
Stefano Beretta
Symposium Chair and STP Editor
4
Politecnico di Milano
,
Milan,
IT
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Jess Waller
Jess Waller
Symposium Chair and STP Editor
5
National Aeronautics and Space Administration
,
HX5, Las Cruces, NM,
US
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Mohsen Seifi
Mohsen Seifi
Symposium Chair and STP Editor
6
ASTM International
,
Washington, DC,
US
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ISBN:
978-0-8031-7686-7
No. of Pages:
594
Publisher:
ASTM International
Publication date:
2020

The current version of NASA standards for manned spaceflight hardware does not contain sufficient detail for the certification of additively manufactured components. The development of additive manufactured standards is currently in work by several standards organizations. NASA, however, cannot wait on these organizations to develop such standards. NASA and its program partners in manned spaceflight (i.e., Commercial Crew, Space Launch System, and the Orion Multi-Purpose Crew Vehicle) are actively developing additively manufactured components for flight as early as 2019. NASA has formed a team to explore the creation of an agency specification for additive manufactured (AM) components. This team includes representatives from nine NASA centers along with representatives from the Federal Aviation Administration, Air Force, and Army. The team concluded that the best way forward would be to create three standards. One each for crewed space flight, non-crewed space flight, and aeronautics. Each standard will be based on the principles of recently released Marshall Space Flight Center (MSFC) Technical Standard MSFC-STD-3716, Standard for Additively Manufactured Spaceflight Hardware by Laser Powder Bed Fusion in Metals. The team agreed that the standard would be written for mature AM technologies and agreed on which families of materials would and would not be applicable. The team developed the structure of the standards and associated standards and created a three-tiered classification system. A matrix was developed that will aid in the creation of tailoring strategies for the various classifications and applications.

1.
Standard for Additively Manufactured Spaceflight Hardware by Laser Powder Bed Fusion in Metals
, MSFC-STD-3716 (
Huntsville, AL
:
NASA Marshall Space Flight Center
, October 18,
2017
).
2.
Specification for Control and Qualification of Laser Power Bed Fusion Metallurgical Processes
, MSFC-STD-3717 (
Huntsville, AL
:
NASA Marshall Space Flight Center
, October 18,
2017
).
3.
Risk Classification for NASA Payloads
, NPR 8705.4 (Hampton, VA:
NASA
, June 12,
2012
).
4.
Fracture Control Requirements for Spaceflight Hardware
, NASA-STD-5019A (Hampton, VA:
NASA
, February 26,
2016
).
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