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[PPR-Screenshot]
Posted on March 29, 2024March 29, 2024 by Andy Tomaswick

Thermal Modeling of a Pulsed Plasma Rocket Shows It Should Be
Possible To Create One

We've reported on a technology called pulsed plasma rockets (PPRs)
here at UT a few times. Several research groups have worked on
variations of them. They are so popular partly because of their
extremely high specific impulse and thrust levels, and they seemingly
solve the trade-off between those two all-important variables in
space exploration propulsion systems. Essentially, they are an
extremely efficient propulsion methodology that, if scaled up, would
allow payloads to reach other planets in weeks rather than months or
years. However, some inherent dangers still need to be worked out,
and overcoming some of those dangers was the purpose of a NASA
Institute for Advanced Concepts (NIAC) project back in 2020. 

Originally granted to Howe Industries, a design shop that has
received several NIAC grants (including two in 2020 itself), the
purpose of this project was to model the design of a fully functional
PPR in modeling software to see if the necessary materials and power
systems are available for a rocket that can provide 100 kN of thrust
and over 5,000 seconds of specific impulse. 

In essence, a PPR takes a fuel pellet made out of some form of
fissionable material (in this case, uranium), and zaps it into a
plasma, then emits the plasma out the back for a forceful thrust.
Rockets with this design can carry much less fuel than standard
chemical rockets, but their design must be significantly larger due
to the heating constraints put on the system by creating the plasma
in the first place.

SciShow discusses a scaled down version of the PPR proposed in the
paper.
Credit - SciShow Space

Those heating constraints were one of the Phase I NIAC study's main
focal points in 2020. In particular, this study focused on analyzing
the barrel the fuel pellet is released into to see if it could
withstand the extreme temperatures created by handling a plasmatized
uranium pellet.

To do this modeling, the team at Howe Industries used a modeling
software called MCNP6 to check where particles went in the system and
thereby calculate how much heat would be collected on other parts of
the system where it wasn't desired. MCNP6 uses a Monte Carlo
simulation methodology, which calculates where neutrons will be
created from the fission reaction that makes the plasma and where
those neutrons will impact the rest of the spacecraft.

Those plasmas would have to be created about once every second,
according to the calculations done by Howe Industries, and each pulse
must reach an energy level of around 1 keV - much smaller than
industrial-level nuclear fission reactors but a relatively high
number for a spacecraft propulsion system. That energy is turned into
heat, and while some of the heat is effectively used to eject the
plasmatized uranium out as a thrust propellant, the rest is absorbed
by other parts of the system. 

Troy Howe, one of the paper's authors, discusses his research into
the PPR.
Credit - Interstellar Research Group YouTube Channel

The barrel was a part of that system that is particularly important
in these thermal calculations. The modeled barrel was made out of
low-enriched uranium but of a different type than the projectile,
allowing the energy to heat the projectile and not the barrel itself.
However, a small part of the barrel would be made of highly enriched
uranium, allowing for rapid plasma propagation in an otherwise
relatively stable system.

That's not to say that none of the heat generated by the fission
reaction would end up in the barrel. Still, by the author's
calculations as part of their final report, an active cooling system
should be enough to lower the temperature to a point where at least
the barrel itself wouldn't melt. Other parts of the system, such as
the nozzle and a rotating drum that helps handle the fuel pellet,
will be modeled in future work.

Additional future work would include building benchtop prototypes of
these systems to test them out, though the prospect of working with
highly enriched uranium as part of this process seems daunting.
However, NIAC hasn't yet funded a Phase II study of the PPR system,
so for now, it is resigned to a nicely modeled project and another
step forward in an idea that has plenty of history. Maybe someday, it
will find its time to shine.

Learn More:
Howe et al. - Pulsed plasma rocket- developing a dynamic fission
process for high specific impulse and high thrust propulsion
UT - Magnetic Fusion Plasma Engines Could Carry us Across the Solar
System and Into Interstellar Space
UT - Plasma Thruster Could Dramatically Cut Down Flight Times to the
Outer Solar System
UT - Plasma Rocket Could Help Pick Up Space Trash

Lead Image:
Model of the PPR design proposed in the paper.
Credit - Howe et al.

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CategoriesRockets TagsNIAC, plasma engine, plasma rockets

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