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- Creators: Department of Physics
Description
This paper studies the history and development of ion propulsion systems and survey past, present, and developing technology with their applications to space missions. This analysis addresses the physical design parameters and process that is a part of designing and optimizing a gridded ion thruster. It also identifies operational limits that may be associated with solar-powered ion propulsion systems and posits plausible solutions or alternatives to remedy such limitations. These topics are presented with the intent of reviewing how ion propulsion technology evolved in its journey to develop to today's systems, and to facilitate thought and discussion on where further development of ion propulsion systems can be directed.
ContributorsTang, Justine (Author) / White, Daniel (Thesis director) / Dahm, Werner (Committee member) / Mechanical and Aerospace Engineering Program (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
This thesis examines how a recently proposed concept for a highly-truncated aerospike nozzle
can be expected to perform at altitudes corresponding to ambient pressures from sea-level to
full vacuum conditions, as would occur during second-stage ascent and during second-stage
descent and return to Earth. Of particular importance is how the base pressure varies with
ambient pressure, especially at low ambient pressures for which the resulting highly underexpanded flows exiting from discrete thrust chambers around the truncated aerospike merge to
create a closed (unventilated) base flow. The objective was to develop an approximate but
usefully accurate and technically rooted way of estimating conditions for which the jets issuing
from adjacent thrust chambers will merge before the end of the truncated aerospike is reached.
Three main factors that determine the merging distance are the chamber pressure, the altitude,
and the spacing between adjacent thrust chambers. The Prandtl-Meyer expansion angle was
used to approximate the initial expansion of the jet flow issuing from each thrust chamber.
From this an approximate criterion was developed for the downstream distance at which the
jet flows from adjacent thrust chambers merge. Variations in atmospheric gas composition,
specific heat ratio, temperature, and pressure with altitude from sea-level to 600 km were
accounted for. Results showed that with decreasing atmospheric pressure during vehicle
ascent, the merging distance decreases as the jet flows become increasingly under-expanded.
Increasing the number of thrust chambers decreases the merging distance exponentially, and
increasing chamber pressure results in a decrease of the merging distance as well.
ContributorsHerrington, Katie (Author) / Dahm, Werner (Thesis director) / Takahashi, Timothy (Committee member) / Barrett, The Honors College (Contributor) / Mechanical and Aerospace Engineering Program (Contributor) / Department of Physics (Contributor)
Created2024-05