Oral Presentation Only
Authors: Natalie A. Ramm (Taylor University) , Bill G. Solyst (Taylor University) , Ben C. Fisher (Taylor University) , Reid E. Dodge (Taylor University) , Anthony J. Pollina (Taylor University) , Paul G. Kuehl (Taylor University)
The main objective of this balloon launch is to test the release of a ten meter boom in microgravity (free fall) at 25 km altitude. The successful release and unraveling of the tether will be a monumental achievement in the area of Pico-Satellite capabilities. In addition to the ten meter boom, a new design of inserting a smaller balloon inside of the parachute for a less chaotic decent in free fall has been implemented with success. Microgravity is an important environment for experimentation. There is a short period of microgravity after the payload is dropped before resistive forces become significant. Microgravity gives an opportunity to test equipment in roughly zero Gs with only a few percent of the Earth's atmosphere. This project tests a real mass model satellite and attempts to optimize a balloon launch for space environment testing. Other important experiments included in this launch consist of the GaAs Solar Array Testing, Thermal Surface Model Testing, Communications link testing with a new nickeltitanium wire J-pole antenna and a Tether Release Model computer simulation that will be compared to the actual experimental execution of the tether release.
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How to Cite: Ramm, N. A. , Solyst, B. G. , Fisher, B. C. , Dodge, R. E. , Pollina, A. J. & Kuehl, P. G. (2012) “Micro Gravity Balloon Drop: Tether Release”, Academic High Altitude Conference. 2012(1). doi: https://doi.org//ahac.8326