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An analysis model has been developed for analyzing/optimizing the integration of a carbon dioxide removal assembly (CDRA), CO2 compressor, accumulator, and Sabatier CO2 reduction assembly. The integrated model can be used in optimizing compressor sizes, compressor operation logic, water generation from Sabatier, utilization of CO2 from crew metabolic output, and utilization of H2 from oxygen generation assembly. Tests to validate CO2 desorption, recovery, and compression had been conducted in 2002-2003 using CDRA/Simulation compressor set-up at NASA Marshall Space Flight Center (MSFC). An analysis of test data has validated CO2 desorption rate profile, CO2 compressor performance, CO2 recovery and CO2 vacuum vent in the CDRA model. Analysis / optimization of the compressor size and the compressor operation logic for an integrated closed air revitalization system is currently being conducted

Following a series of anomalies of the carbon dioxide removal assembly (CDRA) on the International Space Station (ISS), a CDRA teardown, test, and evaluation (TT&E) effort found that the sorbent material was not retained as intended by the packed beds and that presence of the sorbent in the check valve and selector valves was the cause of the failure of these components. This paper documents the development of design data for an in-line filter element. The purpose of the in-line filter is to provide temporary protection for on-orbit CDRA hardware until the bed retainment system can be redesigned and replaced.

Performance testing of the International Space Station Carbon Dioxide Removal Assembly flight hardware in the United States Laboratory during 1999 is described. The CDRA exceeded carbon dioxide performance specifications and operated flawlessly. Data from this test is presented.

This paper describes testing of four-bed molecular sieve (4BMS) development hardware in support of future operations of the International Space Station (ISS) Carbon Dioxide Removal Assembly (CDRA). During 1998, testing of a MSFC 4BMS included operations with the 4BMS inlet air drawn directly from the cabin atmosphere instead of the baseline air source downstream of a Condensing Heat Exchanger (CHX), operating with high carbon dioxide (CO2) loading, and long duration operation in a power save mode. Additionally, testing with increased coolant water temperature was performed to determine effects on the systems CO2 removal performance.