Plume impingement avoidance in spacecraft rendezvous and docking applications
This dissertation aims to provide a brief overview of the satellite rendezvous and docking problem and its challenges. The main focus of this work is the plume impingement problem. When a target and a chaser spacecraft are in rendezvous; or when the chaser is in the process of docking onto the ta...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2018
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/76035 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This dissertation aims to provide a brief overview of the satellite rendezvous and docking
problem and its challenges. The main focus of this work is the plume impingement problem.
When a target and a chaser spacecraft are in rendezvous; or when the chaser is in the
process of docking onto the target, it fires its thrusters to perform a manoeuvre in order
to achieve the desired position and orientation. While firing these thrusters, the exhaust
plume from the thrusters can cause damage to the other spacecraft. When the spacecraft’s
plume impinges on other spacecraft or docking stations, this is known as plume impingement.
Plume impingement avoidance constraints’ study continues to be a virgin area in the vast
scope of satellite rendezvous and docking. For this reason, this work aims to address
plume impingement as one of the important challenges of rendezvous and docking.
Plume impingement can have severe consequences such as damage to sensitive equipment
on the surface of the impinged spacecraft. Plume can also generate large forces and torques
which prove to be disruptive. This could lead to a situation where there may be a loss of
control authority. Care must, therefore, be taken while firing the thrusters of the spacecraft
when it is below a minimum distance of separation from other spacecraft or space
stations. To this end, plume impingement avoidance constraints need to be incorporated
into an optimization problem. Since this constraint is a complex one, addressing this is a
challenge which must not be overlooked. In addition to impingement caused at the instant
at which spacecraft fires its thrusters, impingement can also occur for an extended time
period. The reason for this can be attributed to the time it takes for the plume to decay.
This means that it must not be assumed that plume exists instantaneously. Instead, care
must be taken such that other vehicles and docking stations are safe from impingement for
the entire duration which the plume takes to decay.
This work provides a concise summary of the advancements made so far; formulates an
optimization problem incorporating plume impingement avoidance as a constraint; introduces
the plume decay problem and incorporates decay into the constructed problem.
Lastly it lays down the framework for incorporating plume decay into the formulated problem. |
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