将全尺寸灰水膜曝气生物反应器与反渗透系统集成用于空间废水处理。

IF 3.3 4区 工程技术 Q2 CHEMISTRY, PHYSICAL Membranes Pub Date : 2024-05-30 DOI:10.3390/membranes14060127
Ghaem Hooshyari, Arpita Bose, W Andrew Jackson
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引用次数: 0

摘要

迄今为止,国际空间站(ISS)上的生命支持系统或即将执行的月球/火星任务计划中的生命支持系统都不包括用于废水处理的生物反应器,尽管它们在处理陆地废水方面的应用无处不在。然而,与在微重力环境中运行的系统相比,部分重力生境的新重点降低了对处理系统复杂性的要求,而且可能会增加含有表面活性剂的大容量废水(如洗衣和淋浴),这使得目前的国际空间站废水处理系统变得不合适,因为表面活性剂可能会产生泡沫,使用非再生系统(如混合吸附床)会增加消耗品需求,系统复杂,以及对沉淀和/或生物污垢故障的敏感性。将简单的生物反应器与海水淡化(如反渗透)相结合的混合系统可以减少系统和耗材的质量,降低复杂性。我们的目标是评估一个由膜通气生物反应器(MABR)和低压商业反渗透系统组成的系统,以处理部分重力栖息地废水。MABR 可以作为唯一的废水收集池(容积可变),接收产生的所有废水。MABR 处理了超过 20,750 升的灰水,能够去除超过 90% 的溶解有机碳 (DOC),产生的出水 DOC < 14 mg/L,BOD < 12 mg/L,并将超过 90% 的氨氮氧化为氮氧化物。单个反渗透膜(260 克)能够处理超过 3000 升的 MABR 污水,产生的反渗透渗透液 DOC < 5 毫克/升,TN < 2 毫克/升,TDS < 10 毫克/升,消毒后基本符合 ISS 饮用水标准。该系统的未优化质量和体积为 128.5 千克。消耗品包括氧气(约 4 克/机组人员-天)、反渗透膜和预过滤器(1.7 克/机组人员-天)。对于有四名乘员的为期一年的飞行任务,系统和消耗品的总重量约为 141 千克,可产生约 15 150 千克的处理水,因此投资回收期为 13.4 天(四名乘员的投资回收期为 3.35 天)。鉴于本研究中的人与生物圈反应器的运行时间为 500 天,而在以前的研究中,类似系统的运行时间超过 3 年,因此系统的总成本会非常低。这些结果凸显了混合处理系统在太空栖息地的潜在应用,也可直接应用于采用源分离系统的地面应用。
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Integration of Full-Size Graywater Membrane-Aerated Biological Reactor with Reverse Osmosis System for Space-Based Wastewater Treatment.

To date, life support systems on the International Space Center (ISS) or those planned for upcoming moon/Mars missions have not included biological reactors for wastewater treatment, despite their ubiquitous use for the treatment of terrestrial wastewaters. However, the new focus on partial gravity habitats reduces the required complexity of treatment systems compared with those operating in micro-gravity, and the likely addition of large-volume wastewaters with surfactant loads (e.g., laundry and shower) makes the current ISS wastewater treatment system inappropriate due to the foaming potential from surfactants, increased consumable requirements due to the use of non-regenerative systems (e.g., mixed adsorbent beds), the complexity of the system, and sensitivity to failures from precipitation and/or biological fouling. Hybrid systems that combine simple biological reactors with desalination (e.g., Reverse Osmosis (RO)) could reduce system and consumable mass and complexity. Our objective was to evaluate a system composed of a membrane-aerated bioreactor (MABR) coupled to a low-pressure commercial RO system to process partial gravity habitat wastewater. The MABR was able to serve as the only wastewater collection tank (variable volume), receiving all wastewaters as they were produced. The MABR treated more than 20,750 L of graywater and was able to remove more than 90% of dissolved organic carbon (DOC), producing an effluent with DOC < 14 mg/L and BOD < 12 mg/L and oxidizing >90% of the ammoniacal nitrogen into NOx-. A single RO membrane (260 g) was able to process >3000 L of MABR effluent and produced a RO permeate with DOC < 5 mg/L, TN < 2 mg/L, and TDS < 10 mg/L, which would essentially meet ISS potable water standards after disinfection. The system has an un-optimized mass and volume of 128.5 kg. Consumables include oxygen (~4 g/crew-day), RO membranes, and a prefilter (1.7 g/crew-day). For a one-year mission with four crew, the total system + consumable mass are ~141 kg, which would produce ~15,150 kg of treated water, resulting in a pay-back period of 13.4 days (3.35 days for a crew of four). Given that the MABR in this study operated for 500 days, while in previous studies, similar systems operated for more than 3 years, the total system costs would be exceedingly low. These results highlight the potential application of hybrid treatment systems for space habitats, which may also have a direct application to terrestrial applications where source-separated systems are employed.

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来源期刊
Membranes
Membranes Chemical Engineering-Filtration and Separation
CiteScore
6.10
自引率
16.70%
发文量
1071
审稿时长
11 weeks
期刊介绍: Membranes (ISSN 2077-0375) is an international, peer-reviewed open access journal of separation science and technology. It publishes reviews, research articles, communications and technical notes. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. Full experimental and/or methodical details must be provided.
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