3D-MAT, a thermal protection material for the Artemis Generation

Written by Copernical Team Friday, 24 May 2024 16:24

font size decrease font size increase font size
Print
Email

Write a comment

3D-MAT, a thermal protection material for the Artemis Generation — The 3D-MAT thermal protection material. Credit: NASA

The 3-Dimensional Multifunctional Ablative Thermal Protection System (3D-MAT) is a thermal protection material developed as a critical component of Orion, NASA's newest spacecraft built for human deep space missions. It is able to maintain a high level of strength while enduring extreme temperatures during re-entry into Earth's atmosphere at the end of Artemis missions to the moon.

3D-MAT has become an essential piece of technology for NASA's Artemis campaign that will establish the foundation for long-term scientific exploration on the moon and prepare for human expeditions to Mars, for the benefit of all.

The 3D-MAT project emerged from a technical problem in early designs of the Orion spacecraft. The compression pad—the connective interface between the crew module, where astronauts reside, and the service module carrying power, propulsion, supplies, and more—was exhibiting issues during Orion's first test flight, Exploration Flight Test-1, in 2014.

NASA engineers realized they needed to find a new material for the compression pad that could hold these different components of Orion together while withstanding the extremely high temperatures of atmospheric re-entry.

Using a 3D weave for NASA heat shield materials had been explored, but after the need for a new material for the compression pad was discovered, development quickly escalated.

This led to the evolution of 3D-MAT, a material woven with quartz yarn and cyanate ester resin in a unique three-dimensional design. The quartz yarn used is like a more advanced version of the fiberglass insulation you might have in your attic, and the resin is essentially a high-tech glue. These off-the-shelf aerospace materials were chosen for their ability to maintain their strength and keep heat out at extremely high temperatures.

3D-MAT is woven together with a specialized loom, which packs the yarns tightly together, and then injected with resin using a unique pressurized process. The result is a high-performance material that is extremely effective at maintaining strength when it's hot, while also insulating the heat from the spacecraft it is protecting.

Within three years, 3D-MAT went from an early-stage concept to a well-developed material and has now been integrated onto NASA's flagship Artemis campaign. The use of 3D-MAT in the Orion spacecraft's compression pad during the successful Artemis I mission demonstrated the material's essential role for NASA's human spaceflight efforts.

This development was made possible within such a short span of time because of the team's collaboration with small businesses including Bally Ribbon Mills, which developed the weaving process, and San Diego Composites, which co-developed the resin infusion procedure with NASA.

The team behind its development won the NASA Invention of the Year Award, a prestigious honor recognizing how essential 3D-MAT was for the successful Artemis flight and how significant it is for NASA's future Artemis missions. The inventor team recognized includes Jay Feldman and Ethiraj Venkatapathy from NASA's Ames Research Center in California's Silicon Valley, Curt Wilkinson of Bally Ribbon Mills, and Ken Mercer of Dynovas.

3D-MAT has applications beyond NASA as well. Material processing capabilities enabled by 3D-MAT have led to other products such as structural parts for Formula One racecars and rocket motor casings. Several potential uses of 3D-MAT in commercial aerospace vehicles and defense are being evaluated based on its properties and performance.

Provided by NASA

Citation: 3D-MAT, a thermal protection material for the Artemis Generation (2024, May 24) retrieved 24 May 2024 from https://phys.org/news/2024-05-3d-mat-thermal-material-artemis.html

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.