Monolithic Trace-Contaminant Sorbents Fabricated from 3D-printed Polymer Precursors

The current trace-contaminant (TC) removal technology for use in Extravehicular Activities (EVAs) involves the use of a packed bed of acid-impregnated granular charcoal, which is difficult to regenerate. In this paper, results will be presented on the development of vacuum-regenerable TC sorbents for use in the Portable Life Support System (PLSS). The sorbents will be derived from 3D-printed polymer monoliths (e.g., honeycomb structures), which will then be carbonized and oxidized in order to develop porosity, and also to enhance the TC-sorption capacity. Results will be presented on the following aspects of carbon-sorbent development: (1) precursor selection; (2) monolith fabrication; (3) shape retention and strength; (4) carbon surface and porosity characterization; (5) TC-sorption capacity and vacuum-regeneration; (6) pressure drop; and (7) sub-scale sorbent prototype.

The use of predominantly microporous monolithic carbon is associated with the following benefits: (a) high TC-sorption capacity; (b) low pressure drop; (c) rapid vacuum (pressure-swing) desorption due to thin monolith walls and low pressure drop; (d) good thermal management (high thermal conductivity and low adsorption/desorption thermal effects associated with physisorption); and (e) good resistance to dusty environments.