Description
The standard for hybrid fuel grains is Hydroxyl-terminated polybutadiene (HTPB). With the advances in additive manufacturing, the promise of 3D printed fuel grains has become a possibility. Yet, 3D printed grains do not have as good of a regression rate as the casted HTPB grains. However, with 3D printing, the core of these grains can be printed to maximize surface area in contact with the oxidizer. The goal of this research is to print hybrid rocket fuel grains with various core geometries and test them on a small-scale hybrid test stand. While the hot fires are still under testing at the time of this abstract, the manufacturing posed an interesting outcome, being more time intensive than expected, contradicting the initial hypothesis of faster manufacturing. Future endeavors will continue research into the cores of the 3D printed grains, possible multi-material made grains and creating core structures for HTPB grains from 3D printed materials.
Details
Title
- The Manufacturing and Effects of Core Geometry in 3D Printed Fuel Grains
Contributors
- Rust, Daniel William Yun Jin (Author)
- Rajadas, John (Thesis director)
- Taconi, Carolyn (Committee member)
- Materials Science and Engineering Program (Contributor)
- Barrett, The Honors College (Contributor)
Date Created
The date the item was original created (prior to any relationship with the ASU Digital Repositories.)
2019-05
Resource Type
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