On the development of advanced life support systems maximally reliant on biological systems

John A. Hogan; Robert M. Cowan; Jitendra A. Joshi; Peter Strom; Melvin S. Finstein

doi:10.4271/981535

On the development of advanced life support systems maximally reliant on biological systems

John A. Hogan, Robert M. Cowan, Jitendra A. Joshi, Peter Strom, Melvin S. Finstein

School of Environmental and Biological Sciences, Environmental Science

Research output: Contribution to conference › Paper › peer-review

5 Scopus citations

Abstract

Distant and/or long-term missions, particularly Mars and lunar bases, will require a high degree of regenerative systems utilization. Bio-regenerative systems inherently lend themselves to integrative application, and can serve multiple processing functions in Advanced Life Support (ALS) systems. Striving for maximal use of bio-regenerative systems can reveal possibilities and relationships difficult to conceptualize within the context of a "unit process" methodology common to physico-chemical (P/C) systems. The required regenerative functions of biomass production and solid, liquid, and air processing are discussed, and a potential integrated ALS system scenario including "soil'based" plant production is developed to illustrate potential ramifications of biological (and P/C) system integration.

Original language	English (US)
DOIs	https://doi.org/10.4271/981535
State	Published - Dec 1 1998
Event	28th International Conference on Environmental Systems - Danvers, MA, United States Duration: Jul 13 1998 → Jul 16 1998

Other

Other	28th International Conference on Environmental Systems
Country/Territory	United States
City	Danvers, MA
Period	7/13/98 → 7/16/98

All Science Journal Classification (ASJC) codes

Automotive Engineering
Safety, Risk, Reliability and Quality
Pollution
Industrial and Manufacturing Engineering

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10.4271/981535

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title = "On the development of advanced life support systems maximally reliant on biological systems",

abstract = "Distant and/or long-term missions, particularly Mars and lunar bases, will require a high degree of regenerative systems utilization. Bio-regenerative systems inherently lend themselves to integrative application, and can serve multiple processing functions in Advanced Life Support (ALS) systems. Striving for maximal use of bio-regenerative systems can reveal possibilities and relationships difficult to conceptualize within the context of a {"}unit process{"} methodology common to physico-chemical (P/C) systems. The required regenerative functions of biomass production and solid, liquid, and air processing are discussed, and a potential integrated ALS system scenario including {"}soil'based{"} plant production is developed to illustrate potential ramifications of biological (and P/C) system integration.",

author = "Hogan, {John A.} and Cowan, {Robert M.} and Joshi, {Jitendra A.} and Peter Strom and Finstein, {Melvin S.}",

year = "1998",

month = dec,

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doi = "10.4271/981535",

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T1 - On the development of advanced life support systems maximally reliant on biological systems

AU - Hogan, John A.

AU - Cowan, Robert M.

AU - Joshi, Jitendra A.

AU - Strom, Peter

AU - Finstein, Melvin S.

PY - 1998/12/1

Y1 - 1998/12/1

N2 - Distant and/or long-term missions, particularly Mars and lunar bases, will require a high degree of regenerative systems utilization. Bio-regenerative systems inherently lend themselves to integrative application, and can serve multiple processing functions in Advanced Life Support (ALS) systems. Striving for maximal use of bio-regenerative systems can reveal possibilities and relationships difficult to conceptualize within the context of a "unit process" methodology common to physico-chemical (P/C) systems. The required regenerative functions of biomass production and solid, liquid, and air processing are discussed, and a potential integrated ALS system scenario including "soil'based" plant production is developed to illustrate potential ramifications of biological (and P/C) system integration.

AB - Distant and/or long-term missions, particularly Mars and lunar bases, will require a high degree of regenerative systems utilization. Bio-regenerative systems inherently lend themselves to integrative application, and can serve multiple processing functions in Advanced Life Support (ALS) systems. Striving for maximal use of bio-regenerative systems can reveal possibilities and relationships difficult to conceptualize within the context of a "unit process" methodology common to physico-chemical (P/C) systems. The required regenerative functions of biomass production and solid, liquid, and air processing are discussed, and a potential integrated ALS system scenario including "soil'based" plant production is developed to illustrate potential ramifications of biological (and P/C) system integration.

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U2 - 10.4271/981535

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M3 - Paper

T2 - 28th International Conference on Environmental Systems

Y2 - 13 July 1998 through 16 July 1998

ER -

On the development of advanced life support systems maximally reliant on biological systems

Abstract

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All Science Journal Classification (ASJC) codes

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