Environmental Control and Life Support System Developed for Deep Space Travel

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dc.creatorStapleton, Thomas
dc.creatorHeldmann, Michael
dc.creatorTorres, Miguel
dc.creatorO'Neill, Jonathan
dc.creatorScott-Parry, Tracy
dc.creatorCorallo, Roger
dc.creatorWhite, Kimberly
dc.creatorSchneider, Scott
dc.date.accessioned2017-07-06T17:04:09Z
dc.date.available2017-07-06T17:04:09Z
dc.date.issued2017-07-16
dc.descriptionThomas Stapleton, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionMichael Heldmann, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionMiguel Torres, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionJonathan O'Neill, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionTracy Scott-Parry, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionRoger Corallo, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionKimberly White, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionScott Schneider, United Technologies Corporation Aerospace Systems (UTC), USA
dc.descriptionICES501: Life Support Systems Engineering and Analysis
dc.descriptionThe 47th International Conference on Environmental Systems was held in South Carolina, USA on 16 July 2017 through 20 July 2017
dc.description.abstractNASA outlined plans to journey from the current Low Earth Orbit toward earth independent exploration, evolving habitat capacity to support a trip to Mars, a planetary visit, and return home 3 years later. The Environmental Control and Life Support Systems (ECLSS) are being developed to enable this vision. UTAS completed the first phase of this advancement, or NextSTEP, in September 2016, and is currently working on the second phase design for a universal ECLSS Module to support the different habitats. The team defined an evolutionary path that advances a 90-day Cislunar ECLSS toward a deep space, 1,100-day configuration. Integral to this configuration are: a Universal ECLSS Pallet design that enhances in-flight maintenance and, Integrated ECLSS Control System that enables the use of Machine Learning algorithms, intelligent sensors, and a state-of-the-art cross-pallet communication. The overarching design activities included in this effort define a time dependent strategy enabling deep space exploration.
dc.format.mimetypeapplication/pdf
dc.identifier.otherICES_2017_44
dc.identifier.urihttp://hdl.handle.net/2346/72885
dc.language.isoeng
dc.publisher47th International Conference on Environmental Systems
dc.subjectModularity
dc.subjectDevelopment
dc.subjectDeep Space
dc.subjectECLS
dc.subjectLife Support
dc.titleEnvironmental Control and Life Support System Developed for Deep Space Travelen_US
dc.typePresentations

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