科技报告详细信息
Scale-Up of the Carbon Dioxide Removal by Ionic Liquid Sorbent (CDRILS) System
Yates, Stephen F ; Kamire, Rebecca J ; Henson, Phoebe ; Bonk, Ted ; Loeffelholz, David ; Zaki, Rehan ; Fox, Eric ; Kaukler, William ; Henry, Chris
关键词: ABSORBERS (MATERIALS);    CARBON DIOXIDE REMOVAL;    DEEP SPACE;    DESIGN ANALYSIS;    DESORPTION;    IONIC LIQUID;    LIQUID PHASES;    MANAGEMENT SYSTEMS;    MEMBRANES;    NITROGEN;    RELIABILITY;    SCRUBBERS;    SORBENTS;    STABILITY;    TECHNOLOGY UTILIZATION;    VAPOR PRESSURE;    VAPOR PHASES;   
RP-ID  :  ICES-2019-302,M19-7229
美国|英语
来源: NASA Technical Reports Server
PDF
【 摘 要 】

The Carbon Dioxide Removal by Ionic Liquid Sorbent (CDRILS) system is designed for efficient, safe and reliable carbon dioxide (CO2) removal from cabin air on long-duration missions to the Moon, deep space, and Mars. CDRILS integrates an ionic liquid sorbent with hollow fiber membrane contactors for rapid CO2 removal and recovery. The liquid-based system provides continuous CO2 delivery, which avoids complicated valve networks to switch between absorbing and desorbing beds and enables simpler integration to the Sabatier without the need for the CO2 Management System (CMS). Ionic liquids are particularly desirable as liquid absorbents for space applications since they are non-volatile, non-odorous, and have high oxidative stability. The hollow fiber membrane contactors offer both high contact area and rigorous containment between the gas and liquid phases in a microgravity environment. Scale-up of the CDRILS technology has presented a series of fascinating challenges, since the interaction between hollow fiber properties, ionic liquid properties and performance is complex. Properties measured with lab-scale hollow fiber contactors are used to estimate the performance of contactors that are similar in scale to flight-scale demonstrations. To accomplish this, component and system models have been built to relate the key scrubber and stripper design and operating variables with performance, and experiments directed to validate the models have been performed. System size, weight and power are determined by component selection, arrangement, and operating conditions. Reliability will be extremely important for any long-range mission and depends on the stability of the ionic liquids and hollow fiber contactors. We report on our continuing long term stability experiments for the ionic liquid and contactor materials and our investigation of the physical properties of additional ionic liquids.

【 预 览 】
附件列表
Files Size Format View
20190030422.pdf 1962KB PDF download
  文献评价指标  
  下载次数:15次 浏览次数:16次