Metallic Environmentally Resistant Coating Rapid Innovation Initiative Under Extreme Space Environments
Metallic Environmentally Resistant Coating Rapid Innovation Initiative Under Extreme Space Environments
- Neue Suche nach: S. Rengifo
- Neue Suche nach: A. R. Gray
- Neue Suche nach: W. Scott
- Neue Suche nach: S. Rengifo
- Neue Suche nach: A. R. Gray
- Neue Suche nach: W. Scott
Mission concepts such as JPL’s Endurance-A campaign will utilize rovers such as Astrolab’s FLEX concept to explore the lunar surface. For these types of systems, lightweight alloys such as aluminum (Al) and titanium (Ti) are often specified to minimize mass while maintaining structural integrity [1,2,3]. Such alloys, however, exhibit poor tribological response in the form of high friction and wear, especially in extreme space environments and with the additional presence of lunar regolith. This shortens the lifetimes of these systems which have a requirement to traverse 1,00km/year [2,3]. The MERCRII project is ad-dressing the technology need of this and future rover missions by developing advanced wear- and radiation-resistant coatings for lightweight parts to extend the lifetime and sustainability of both lunar and Martian assets. The MERCRII project focuses on the technology taxonomies of exploration destination systems, mission infrastructure, and sustainability and supportability to explore both new and existing coating technologies, including material formulations and application methods. Several material formulations were considered for their wear resistance and fracture toughness and the following were chosen for Phase I testing: Nickle Titani-um (NiTi), Aluminum Oxide (AlO), and Ti64 with hBN at two and ten vol percent (Ti-2vol%hBN and Ti-10vol%hBN).
Dokumentinformationen
Metallic Environmentally Resistant Coating Rapid Innovation Initiative Under Extreme Space Environments
Technology Showcase for Future NASA Planetary Science Missions ; 2023 ; Galveston, TX, US
Aufsatz (Konferenz)
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Englisch