Publication Date:
2019-08-13
Description:
From the humid, corrosion-friendly atmosphere of KSC, to the extreme heat of ascent, to the cold vacuum of space, the Space Shuttle faced one hostile environment after another. One of those harsh environments the hydrogen environment existed within the shuttle itself. Liquid hydrogen was the fuel that powered the shuttle s complex, powerful, and reusable main engine. Hydrogen provided the high specific impulse the bang per pound of fuel needed to perform the shuttle s heavy lifting duties. Hydrogen, however, was also a potential threat to the very metal of the propulsion system that used it. The diffusion of hydrogen atoms into a metal can make it more brittle and prone to cracking a process called hydrogen embrittlement. This effect can reduce the toughness of carefully selected and prepared materials. A concern that exposure to hydrogen might encourage crack growth was present from the beginning of the Space Shuttle Program, but the rationale for using hydrogen was compelling. This paper outlines the material characterization, anomaly resolution, and path to understanding of hydrogen embrittlement on superalloys through the course of the SSME program. Specific examples of nickel alloy turbine housings and single crystal turbine blades are addressed. The evolution of fracture mechanics analytical methods is also addressed.
Keywords:
Composite Materials
Type:
M10-0376
,
7th Modeling and Simulation Meeting; May 03, 2010 - May 07, 2010; Colorado Springs, CO; United States|4th Spacecraft Propulsion Joint Subcommittee Meeting; May 03, 2010 - May 07, 2010; Colorado Springs, CO; United States|57th JANNAF Joint Propulsion Meeting; May 03, 2010 - May 07, 2010; Colorado Springs, CO; United States|5th Liquid Propulsion Meeting; May 03, 2010 - May 07, 2010; Colorado Springs, CO; United States
Format:
text
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