David Smitherman scite author profile

This paper describes the recently developed point of departure design for a long duration, reusable Mars Transit Habitat, which was established during a 2016 NASA habitat design refinement activity supporting the definition of NASA's Evolvable Mars Campaign. As part of its development of sustainable human Mars mission concepts achievable in the 2030s, the Evolvable Mars Campaign has identified desired durations and mass/dimensional limits for long duration Mars habitat designs to enable the currently assumed solar electric and chemical transportation architectures. The Advanced Exploration Systems Mars Transit Habitat Refinement Activity brought together habitat subsystem design expertise from across NASA to develop an increased fidelity, consensus design for a transit habitat within these constraints. The resulting design and data (including a mass equipment list) contained in this paper are intended to help teams across the agency and potential commercial, academic, or international partners understand: 1) the current architecture/habitat guidelines and assumptions, 2) performance targets of such a habitat (particularly in mass, volume, and power), 3) the driving technology/capability developments and architectural solutions which are necessary for achieving these targets, and 4) mass reduction opportunities and research/design needs to inform the development of future research and proposals. Data presented includes: an overview of the habitat refinement activity including motivation and process when informative; full documentation of the baseline design guidelines and assumptions; detailed mass and volume breakdowns; a moderately detailed concept of operations; a preliminary interior layout design with rationale; a list of the required capabilities necessary to enable the desired mass; and identification of any worthwhile trades/analyses which could inform future habitat design efforts. As a whole, the data in the paper show that a transit habitat meeting the 43 metric tons launch mass/trans-Mars injection burn limits specified by the Evolvable Mars Campaign is achievable near the desired timeframe with moderate strategic investments including maintainable life support systems, repurposable structures and packaging, and lightweight exercise modalities. It also identifies operational and technological options to reduce this mass to less than 41 metric tons including staging of launch structure/packaging and alternate structural materials.

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Space Transportation Infrastructure Supported By Propellant Depots

Smitherman

Woodcock²

2011

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Transit Habitat Design for Mars Exploration

Polsgrove

Simon

Waggoner

et al. 2018

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Habitat Concepts for Deep Space Exploration

Smitherman

Griffin²

2014

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Future missions under consideration requiring human habitation beyond the International Space Station (ISS) include deep space habitats in the lunar vicinity to support asteroid retrieval missions, human and robotic lunar missions, satellite servicing, and Mars vehicle servicing missions. Habitat designs are also under consideration for missions beyond the Earth-Moon system, including transfers to near-Earth asteroids and Mars orbital destinations. A variety of habitat layouts have been considered, including those derived from the existing ISS designs and those that could be fabricated from the Space Launch System (SLS) propellant tanks. This paper presents a comparison showing several options for asteroid, lunar, and Mars mission habitats using ISS derived and SLS derived modules and identifies some of the advantages and disadvantages inherent in each. Key findings indicate that the larger SLS diameter modules offer built-in compatibility with the launch vehicle, single launch capability without on-orbit assembly, improved radiation protection, lighter structures per unit volume, and sufficient volume to accommodate consumables for long duration missions without resupply. The information provided with the findings includes mass and volume comparison data that should be helpful to future exploration mission planning efforts.

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Space Launch System Co-Manifested Payload Options for Habitation

Smitherman

2015

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The Space Launch System (SLS) has a co-manifested payload capability that will grow over time as the rocket matures and planned upgrades are implemented. The final configuration is planned to be capable of inserting a payload greater than 10 metric tons (mt) into a trans-lunar injection trajectory along with the crew in the Orion capsule and the service module. The co-manifested payload is located below the Orion and its service module in a 10-meter high fairing similar to the way the Saturn launch vehicle carried the lunar lander below the Apollo command and service modules. A variety of approaches have been explored that utilizes this co-manifested payload capability to build up infrastructure in deep space in support of future asteroid, lunar, and Mars mission scenarios. This paper is a report on the findings from the Advanced Concepts Office study team at the NASA Marshall Space Flight Center, working with the Advanced Exploration Systems Program on the Exploration Augmentation Module Project. It includes some of the possible options for habitation in the co-manifested payload volume on SLS. Findings include module designs that can be developed in 10mt increments to support these missions, including overall conceptual layouts, mass properties, and approaches for integration into various scenarios for near-term support of deep space habitat research and technology development, support to asteroid exploration, and long range support for Mars transfer flights.

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Internal Layout for a Cis-Lunar Habitat

Griffin¹,

Smitherman

Howe

2013

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The distance between Orlando, FL and Miami, FL is 377 km (234 mi.). This is the approximate orbital altitude of the Russian Salyut and MIR space stations; Skylab and the existing International Space Station (ISS). With the exception of the Apollo missions, virtually all human space flight has occurred within the distance between Orlando and Miami. In other words, very close to the Earth. This is significant because NASA's goal is to explore Beyond low-Earth Orbit (BEO) and is building the Space Launch System (SLS) capable of sending humans to cis-lunar space, the surface of the Moon, asteroids and Mars. Unlike operations in low-earth orbit, astronauts on BEO missions do not have rapid emergency return or frequent resupply opportunities and are exposed to potentially lethal radiation. Apollo missions were by comparison short. The longest was 12.5 days compared to cis-lunar missions currently being sized for 60 and 180 days. For radiation, one of the largest solar particle events (SPE) on record (August 4-9, 1972) occurred between the Apollo 16 and 17 flights. This was fortunate because the magnitude of this SPE would likely have been fatal to astronauts in space suits or the thin-walled Lunar Excursion Module. A cislunar habitat located at one of the Earth-Moon Lagranian points (EM L2) is being studied. This paper presents an overview of the factors influencing the design and includes layout options for the habitat. Configurations include ISS-derived systems but there is an emphasis on SLS-derived versions using a propellant tank for the habitat pressure vessel.

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SLS-Derived Lab: Precursor to Deep Space Human Exploration

Griffin

Lewis

Eppler

et al. 2015

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