Composting on Mars or the Moon: II. Temperature feedback control with top-wise introduction of waste material and air.

Whereas Earth-based composting reactors that effectively control the process are batch operations with bottom-to-top airflow, in extraterrestrial application both the fresh waste and the air need to be introduced from above. Stabilized compost and used air would exit below. This materials flow pattern permits the addition of waste whenever generated, obviating the need for multiple reactors, and the incorporation of a commode in the lid.

Composting on Mars or the Moon: I. Comparative evaluation of process design alternatives.

As a candidate technology for treating solid wastes and recovering resources in bioregenerative Advanced Life Support, composting potentially offers such advantages as compactness, low mass, near ambient reactor temperatures and pressures, reliability, flexibility, simplicity, and forgiveness of operational error or neglect. Importantly, the interactions among the physical, chemical, and biological factors that govern composting system behavior are well understood. This article comparatively evaluates five Generic Systems that describe the basic alternatives to composting facility design and control.

Biological removal of gaseous ammonia in biofilters: space travel and earth-based applications.

Gaseous NH3 removal was studied in laboratory-scale biofilters (14-L reactor volume) containing perlite inoculated with a nitrifying enrichment culture. These biofilters received 6 L/min of airflow with inlet NH3 concentrations of 20 or 50 ppm, and removed more than 99.99% of the NH3 for the period of operation (101, 102 days).

Composting of solid waste during extended human travel and habitation in space.

As part of a Controlled Ecological Life Support System (CELSS) for long term human travel and habitation in space, the resources in solid waste may be regenerated through the microbiological process of composting. This would release CO2 for photosynthetic uptake while transforming the waste to a smaller volume and weight of stabilized and sanitized compost. To continue the biodegradation and complete the cycling of nutrients, the compost would be incorporated into soil used in growing food crops.

Physical modeling of the composting ecosystem.

A composting physical model with an experimental chamber with a working volume of 14 x 10 cm (0.5 ft) was designed to avoid exaggerated conductive heat loss resulting from, relative to field-scale piles, a disproportionately large outer surface-area-to-volume ratio. In the physical model, conductive flux (rate of heat flow through chamber surfaces) was made constant and slight through a combination of insulation and temperature control of the surrounding air.