Contaminated air, whether in a crewed spacecraft cabin or terrestrial work and living spaces, is a pervasive problem affecting human health, performance, and well being. The need for highly effective, economical air quality processes spans a wide range of terrestrial and space flight applications. Typically, air quality control processes rely on absorption-based processes. Most industrial packed-bed adsorption processes use activated carbon. Once saturated, the carbon is either dumped or regenerated. In either case, the dumped carbon and concentrated waste streams constitute a hazardous waste that must be handled safely while minimizing environmental impact. Thermal catalytic oxidation processes designed to address waste handling issues are moving to the forefront of cleaner air quality control and process gas decontamination processes. Careful consideration in designing the catalyst substrate and reactor can lead to more complete contaminant destruction and poisoning resistance. Maintenance improvements leading to reduced waste handling and process downtime can also be realized. Performance of a prototype thermal catalytic reaction based on ultra-short waste channel, monolith catalyst substrate design, under a variety of process flow and contaminant loading conditions, is discussed.
[1]
William C. Pfefferle,et al.
Development and Performance of Microlith™ Light-Off Preconverters for LEV/ULEV
,
1997
.
[2]
Jay L. Perry,et al.
Microlith based sorber for removal of environmental contaminants
,
2004
.
[3]
Klaus Ammann.
Development of the Catalytic Oxidizer Technology for the European Space Programme
,
1989
.
[4]
J. L. Perry,et al.
International Space Station Alpha trace contaminant control subassembly life test report
,
1995
.
[5]
S. Block,et al.
Disinfection, sterilization, and preservation
,
1977
.
[6]
John Graf,et al.
A Regenerable Sorbent Bed for Trace Contaminant Removal
,
1999
.