For long-duration space missions outside of Earth orbit, reliability considerations will drive higher levels of redundancy and/or on-board spares for life support equipment. Component scaling will be a critical element in minimizing overall launch mass while maintaining an acceptable level of system reliability. Building on an earlier reliability study (AIAA 2012-3491), this paper considers the impact of alternative scaling approaches, including the design of technology assemblies and their individual components to maximum, nominal, survival, or other fractional requirements. The optimal level of life support system closure is evaluated for deep-space missions of varying duration using equivalent system mass (ESM) as the comparative basis. ...
As NASA looks beyond the International Space Station toward long-duration, deep space missions away ...
This report describes a flexible, reliable, deep space life support system design approach that uses...
A hardware system's failure rate often increases over time due to wear and aging, but not always. So...
The National Aeronautics and Space Administration is in a process of evaluating future targets for s...
Cost-effective high reliability can be achieved in future space life support systems through careful...
Recycling life support systems can achieve ultra reliability by using spares to replace failed compo...
Life support system architectures for long duration space missions are often explored analytically i...
Reliable life support systems are required for deep space missions. The probability of a fatal life ...
Long-endurance human spaceflight - such as missions to Mars or its moons - will present a never-befo...
Long duration human missions beyond low Earth orbit, such as a permanent lunar base, an asteroid ren...
NASA's technology development roadmaps provide guidance to focus technological development on areas ...
It is sometimes optimistically hoped that a space life support system can be kept working throughout...
The National Aeronautics and Space Administration's (NASA) technology development roadmaps provide g...
Long-Term Objective: Identify optimal advanced life support system designs that meet existing and pr...
A published Mars mission is used to explore the methods and costs to achieve ultra reliable life sup...
As NASA looks beyond the International Space Station toward long-duration, deep space missions away ...
This report describes a flexible, reliable, deep space life support system design approach that uses...
A hardware system's failure rate often increases over time due to wear and aging, but not always. So...
The National Aeronautics and Space Administration is in a process of evaluating future targets for s...
Cost-effective high reliability can be achieved in future space life support systems through careful...
Recycling life support systems can achieve ultra reliability by using spares to replace failed compo...
Life support system architectures for long duration space missions are often explored analytically i...
Reliable life support systems are required for deep space missions. The probability of a fatal life ...
Long-endurance human spaceflight - such as missions to Mars or its moons - will present a never-befo...
Long duration human missions beyond low Earth orbit, such as a permanent lunar base, an asteroid ren...
NASA's technology development roadmaps provide guidance to focus technological development on areas ...
It is sometimes optimistically hoped that a space life support system can be kept working throughout...
The National Aeronautics and Space Administration's (NASA) technology development roadmaps provide g...
Long-Term Objective: Identify optimal advanced life support system designs that meet existing and pr...
A published Mars mission is used to explore the methods and costs to achieve ultra reliable life sup...
As NASA looks beyond the International Space Station toward long-duration, deep space missions away ...
This report describes a flexible, reliable, deep space life support system design approach that uses...
A hardware system's failure rate often increases over time due to wear and aging, but not always. So...