Browsing by Author "Howard, Jeanie"
Now showing 1 - 2 of 2
- Results Per Page
- Sort Options
Item Evaluation of Brine Processing Technologies for Spacecraft Wastewater(45th International Conference on Environmental Systems, 2015-07-12) Shaw, Hali L.; Flynn, Michael; Wisniewski, Richard; Lee, Jeffery; Jones, Harry; Delzeit, Lance; Shull, Sarah; Sargusingh, Miriam; Beeler, David; Howard, Jeanie; Howard, Kevin; Harris, Linden; Parodi, Jurek; Kawashima, BrianBrine drying systems may be used in spaceflight. There are several advantages to using brine processing technologies for long-duration human missions including a reduction in resupply requirements and achieving high water recovery ratios. The objective of this project was to evaluate four technologies for the drying of spacecraft water recycling system brine byproducts. The technologies tested were NASA’s Forward Osmosis Brine Drying (FOBD), Paragon’s Ionomer Water Processor (IWP), NASA’s Brine Evaporation Bag (BEB) System, and UMPQUA’s Ultrasonic Brine Dewatering System (UBDS). The purpose of this work was to evaluate the hardware using feed streams composed of brines similar to those generated on board the International Space Station (ISS) and future exploration missions. The brine formulations used for testing were the ISS Alternate Pretreatment and Solution 2 (Alt Pretreat). The brines were generated using the Wiped-film Rotating-disk (WFRD) evaporator, which is a vapor compression distillation system that is used to simulate the function of the ISS Urine Processor Assembly (UPA). Each system was evaluated based on the results from testing and Equivalent System Mass (ESM) calculations. A Quality Function Deployment (QFD) matrix was also developed as a method to compare the different technologies based on customer and engineering requirements.Item Optimization of the Distiller Calcium Limiter (DCaL) System for Calcium Removal in Spacecraft Wastewater(44th International Conference on Environmental Systems, 2014-07-13) Shaw, Hali; Flynn, Michael; Wisniewski, Richard; Delzeit, Lance; Shull, Sarah; Sargusingh, Miriam; Beeler, David; Howard, Jeanie; Howard, Kevin; Kawashima, Brian; Hayden, AnnaThe Distiller Calcium Limiter (DCaL) system removes calcium scale precursors from spacecraft wastewater. Previous research has indicated that the DCaL system successfully removes calcium, preventing the formation of calcium scale on heat transfer surfaces. The objective of this study was to optimize the DCaL system; this includes completing a mass balance, determining the optimum ion exchange membranes (anion and cation), and determining the effectiveness of electrodialysis reversal. Three membrane pairs were tested: Astom Neosepta® AMX/CMX (anion/cation), Astom AHA/CMB, and proprietary research membranes AEM/CEM. Tests were conducted using three individual test stands with different cell stacks that contained the membranes. The feed used for testing consisted of CaCl2 (20 g/L) and NaCl (25 g/L). The results from the testing were used to determine which membrane was the most efficient at removing calcium. A chemical compatibility test was then conducted by completing permselectivity tests, which were used to compare new membranes versus membranes that were previously soaked in brine (a concentrated urine mixture containing chromic acid) for 99 days. SEM images were also taken of the membranes soaked in brine to view any physical changes that may have occurred. The effect of electrodialysis reversal was determined by completing tests using ISS simulated wastewater (US/Russian chromic acid ISS pretreatment) and the DCaL-WFRD system. Three material balance tests were conducted to distinguish the ion transfer rates and water transfer rates. A vacuum test was completed to determine whether the electrodialysis stack could hold vacuum. Based on testing, the results showed that the Astom Neosepta® AMX and CMX membranes provided the highest performance in terms of calcium removal and chemical compatibility. The results also showed that electrodialysis reversal improves calcium removal and prevents fouling of the membranes. The material balance confirmed that the DCaL system removes calcium; however, additional tests are necessary to obtain data with better resolution and to determine the effect of more complex feed mixtures.