OPTIMIZATION OF THE MIXSTIX PLATFORM ALEXIS DUNHAM AND SAM JOHNSON DEPARTMENT OF CHEMICAL AND BIOLOGICAL ENGINEERING
Design Elements Tested
Background Nanoracks markets a Mixstix product that allows for contained experiments to be sent into space. The current Mixstix design, however, has minor flaws that need to be improved upon for ease of operation by the crewmembers and customers. The main goal of this project was to decrease the anomaly rate to less than 15% while making the product more cost effective.
Screw Clamp
Biovalve
KECK Ramp Clamp
Black Threaded White Threaded 430 Tubing Types Evaluated End Cap End Cap
The vacuum pressure, vibration, time, and shipping tests were used to determine leakage through the clamps and end caps.
Testing Results
The boiling test determined whether the tubing material would hold up if a customer were to sterilize via boiling.
Original Mixstix Design Vortex (Vibration) Test Screw End Cap (Right) Regular End Cap (Left)
Parylene Coated Silicone Tubing
Clamp
Boiling Test
Heat Sealing Test
Vacuum Pressure Test
The heat-sealing test was used to determine if heat sealing would be compatible with tubing materials. A tubing database was created to summarize chemical compatibility of 430 different tubing options.
Recommended Design The recommended product uses a polyvinyl chloride tube along with new black threaded end caps. The clamp from the original Mixstix is included in the recommended design based on performance.
Assembled Original Mixstix Design
The original Mixstix design consist of two end caps, a silicon tube coated in parylene, clamps, zip ties, and screws for the screw end cap. The main source of leakage is through the end caps and clamp of the Mixstix.
The redesign has eliminated the need for zip ties and the parylene coating.
Assembled Recommended Design
Economics
Acknowledgements Special thanks to our sponsor Nanoracks.
2023 Capstone Project