S. R. Curley scite author profile

Life support is vital to human spaceflight, and most current life support systems employ single-use hardware or regenerable technologies that throw away the waste products, relying on resupply to make up the consumables lost in the process. Because the long-term goal of the National Aeronautics and Space Administration is to expand human presence beyond low-earth orbit, life support systems must become self-sustaining for missions where resupply is not practical. From May through October 2011, the life support team at the Johnson Space Center was challenged to define requirements, develop a system concept, and create a preliminary life support system design for a non-planetary Deep Space Habitat that could sustain a crew of four in near earth orbit for a duration of 388 days. Some of the preferred technology choices to support this architecture were passed over because the mission definition has an unmanned portion lasting 825 days. The main portion of the architecture was derived from technologies currently integrated on the International Space Station as well as upcoming technologies with moderate Technology Readiness Levels. The final architecture concept contains only partially-closed air and water systems, as the breakeven point for some of the closure technologies was not achieved with the mission duration.

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A Madre Evaluation Report 3. Detection and Analysis of AMR Test 6210

Headrick¹,

Curley²,

Thorp³

et al. 1962

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Portions of the trajectory of the Vertical Balloon, AMR Test 6210, were monitored with the Madre radar from Chesapeake Bay Annex. Detection was accomplished via direct look.Post flight position data from AMR and the Madre data from the trajectory were combined to confirm the vertical pattern of the Madre antenna. PROELE STATUSThis is an interim report on one phase of the problem; work is continuing on this and other phases. AUTHDRIZATION

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A MADRE Evaluation Report 5: Detection and Analysis of Trailblazer IIA

Curley¹,

Headrick²,

Ahearn³

et al. 1962

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ABSTRACT[Secret]The four-stage Trailblazer Ha was launched from Wallops Island for the purpose of studying phenomena associated with the high speed reentry bodies. The Madre radar observed portions of the -trajectories of all f o u r stages. The first stage was observed throughout the most of its flight. The second stage was observed on the way up until it left the antenna pattern and again on the way down when it reappeared in the antenna pattern. The other two stages were observed just prior to and during reentry. PROBLEM STATUSThis is an interim report on one phase of the problem; work is continuing on this and other phases.

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Altair Lander Life Support: Design Analysis Cycles 4 and 5

Anderson

Curley

Rotter

et al. 2011

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NASA is working to develop a new lunar lander to support lunar exploration. The development process that the Altair project is using for this vehicle is unlike most others. In "Lander Design Analysis Cycle 1" (LDAC-1), a single-string, minimum functionality design concept was developed, including life support systems for different vehicle configuration concepts, first for a combination of an ascent vehicle and a habitat with integral airlocks, and then for a combined ascent vehicle-habitat with a detachable airlock. In LDAC-2, the Altair team took the ascent vehicle-habitat with detachable airlock and analyzed the design for the components that were the largest contributors to the risk of loss of crew (LOC). For life support, the largest drivers were related to oxygen supply and carbon dioxide control. Integrated abort options were developed at the vehicle level. Many life support failures were not considered to result in LOC because they had a long enough time to effect that abort was considered a feasible option to safely end the mission before the situation became life threatening. These failures were then classified as loss of mission (LOM) failures. Many options to reduce LOC risk were considered, and mass efficient solutions to the LOC problems were added to the vehicle design at the end of LDAC-2. In LDAC-3, the new design was analyzed for large contributors to the risk of LOM. To avoid ending the mission early or being unable to accomplish goals like performing all planned extravehicular activities (EVAs), various options were assessed for their combination of risk reduction and mass cost. This paper outlines the major assumptions, design features, and decisions related to the development of the life support system for the Altair project through LDAC-3.

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S. R. Curley

Tests of remote skywave measurement of ocean surface conditions

Deep Space Habitat ECLSS Design Concept

A Madre Evaluation Report 3. Detection and Analysis of AMR Test 6210

A MADRE Evaluation Report 5: Detection and Analysis of Trailblazer IIA

Altair Lander Life Support: Design Analysis Cycles 4 and 5

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