Stoichiometric model of a fully closed bioregenerative life support system for autonomous long-duration space missions

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2023-08-16 DOI:10.3389/fspas.2023.1198689
A. Vermeulen, Alvaro Papic, Igor Nikolic, Frances M. T. Brazier
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Abstract

Bioregenerative life support systems (BLSS) are vital for long-duration and remote space missions to increase mission sustainability. These systems break down human waste materials into nutrients and CO2 for plants and other edible organisms, which in turn provide food, fresh water, and oxygen for astronauts. The central idea is to create a materially closed loop, which can significantly reduce mission mass and volume by cutting down or even eliminating disposable waste. In most BLSS studies only a fraction of the resources, such as food, are provided by the system itself, with the rest taken on board at departure or provided through resupply missions. However, for autonomous long-duration space missions without any possibility of resupply, a BLSS that generates all resources with minimal or no material loss, is essential. The goal of this study is to develop a stoichiometric model of a conceptually fully closed BLSS that provides all the metabolic needs of the crew and organisms. The MELiSSA concept of the European Space Agency is used as reference system, consisting of five interconnected compartments, each inhabited by different types of organisms. A detailed review of publicly available MELiSSA literature from 1989 to 2022 revealed that no existing stoichiometric model met the study’s requirements. Therefore, a new stoichiometric model was developed to describe the cycling of the elements C, H, O, and N through all five MELiSSA compartments and one auxiliary compartment. A compact set of chemical equations with fixed coefficients was established for this purpose. A spreadsheet model simulates the flow of all relevant compounds for a crew of six. By balancing the dimensions of the different compartments, a high degree of closure is attained at steady state, with 12 out of 14 compounds exhibiting zero loss, and oxygen and CO2 displaying only minor losses between iterations. This is the first stoichiometric model of a MELiSSA-inspired BLSS that describes a continuous provision of 100% of the food and oxygen needs of the crew. The stoichiometry serves as the foundation of an agent-based model of the MELiSSA loop, as part of the Evolving Asteroid Starships (E|A|S) research project.
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用于自主长时间太空任务的全封闭生物再生生命支持系统的化学计量模型
生物再生生命支持系统(BLSS)对于长时间和远程太空任务至关重要,以提高任务的可持续性。这些系统将人类排泄物分解为营养物质和二氧化碳,用于植物和其他可食用生物,进而为宇航员提供食物、淡水和氧气。核心思想是创建一个物质闭环,通过减少甚至消除一次性废物,可以显著减少任务质量和体积。在大多数BLSS研究中,只有一小部分资源,如食物,由系统本身提供,其余资源在出发时携带或通过补给任务提供。然而,对于没有任何补给可能性的自主长时间太空任务来说,一个能够在最小或没有物质损失的情况下产生所有资源的BLSS是至关重要的。本研究的目标是开发一个概念上完全封闭的BLSS的化学计量模型,该模型提供船员和生物体的所有代谢需求。欧洲航天局的MELiSSA概念被用作参考系统,由五个相互连接的隔间组成,每个隔间居住着不同类型的生物。对1989年至2022年公开的MELiSSA文献的详细审查显示,没有任何现有的化学计量模型符合该研究的要求。因此,开发了一个新的化学计量模型来描述元素C、H、O和N通过所有五个MELiSSA隔间和一个辅助隔间的循环。为此,建立了一组具有固定系数的紧凑化学方程。电子表格模型模拟了六名船员的所有相关化合物的流动。通过平衡不同隔室的尺寸,在稳定状态下实现了高度封闭,14种化合物中有12种表现出零损失,氧和CO2在迭代之间仅表现出较小的损失。这是受MELiSSA启发的BLSS的第一个化学计量模型,该模型描述了机组人员100%的食物和氧气需求的连续供应。作为进化小行星星舰(E|A|S)研究项目的一部分,化学计量是MELiSSA回路基于代理的模型的基础。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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