Powering OSCAR

Recycling waste has been an issue on Earth for decades. The OSCAR project seeks to find ways to make sure that it does not become an issue in space. The main focus of OSCAR is the combustion of waste and reclamation of gaseous products in microgravity. The first phase of testing relies on a ground rig that operates both under normal (Earth) gravity and in drop tower tests that briefly simulate a microgravity environment. In the second phase, a test will be performed during a suborbital flight were the experiment will be carried out in microgravity. Throughout the spring term, interns have played an integral part in continuing the progress made by the project. They performed work in upgrading the electrical and mechanical systems that make up OSCAR. They made multiple improvements to the test rig's operating software to improve readability and usability. They prepared and edited documents that were vital to the engineering process. And, they were responsible for performing lab tests and refining the lab operations document and procedure. The interns were a big help in maintaining the rigorous test schedule.

OSCAR, which stands for Orbital Syngas Commodity Augmentation Reactor, is to find a way to
turn astronaut waste into chemical energy. The two parts of this are important: finding a way to dispose of waste
generated in space, and seeing if there is a way to recycle that waste into chemical energy.
The importance of the disposal aspect is that there is currently no way to dispose of, or recycle, waste that is created
in space other than jettisoning it (which is what the ISS does via empty supply capsules). As manned missions go
deeper into space, that method will no longer be viable, as a craft would essentially be littering the space and planets
that they visit.
Energy reclamation is also important because of the high monetary and spatial costs of sending supplies on space
missions. Every little bit extra that can be reused out of what is sent can save room and funds for other supplies. The facet of this problem that the OSCAR project is focusing on is how to combust waste in zero gravity.
Combustion in the presence of gravity is one of those things that is taken for granted. When something burns on Earth,
the flames rise above the fuel as oxygen flows from underneath. In microgravity, the flames surround the object
completely, which restricts the amount of oxygen that can reach the fuel, and retards the combustion. OSCAR uses a
vortex reaction chamber to counter this phenomenon.
The OSCAR test rig will eventually be tested on a suborbital flight to see if it is an effective solution to the issue
in real-world conditions. Currently, there is a prototype test rig that is fully functional. This rig has been previously
tested in a 2 second drop test at Glenn Research Center’s (GRC) Zero Gravity Facility (ZGF). (The free-fall conditions
of the drop mimic microgravity, if only for a brief period of time).
This session’s focus was on upgrading the test rig and software, updating the paperwork, performing additional
lab tests, and readying the rig for the five second drop test, again at GRC.
II. Upgrades
The state of the testing rig at the start of the session was in between its configurations for the two second drop
tower and the five second drop tower. The rig needed upgrades to address various insufficiencies that either were
discovered during the two second campaign or were a direct result of the differences between the two drop tower
setups. The main differences that had to be handled were the increase in shock loads from 30g to 65g, a difference in
drop indicating signal (on the falling edge of a pulse instead of a change from high to low), and the ambient pressure
of the test apparatus (the two second tower dropped the rig in atmosphere, while the five second tower drops in
vacuum).