When I
wrote this blog (I’m sticking to my guns on that term), I was at a crossroads
of whether to stay at LANL or go somewhere where I might have a better chance
of getting fission power established in space. I had signed the paperwork to
accept a severance package, but my Division Leader came by 15 minutes before
the rescission deadline and said the Lab would fund an experiment that David
Dixon, Pat McClure and I had proposed. I faxed in my rescission form 5 minutes
before the deadline, and 6 months later the DUFF experiment was completed, and
now KRUSTY is proceeding.
Update
on Low Power Space Reactors
DUFF
(Demonstration Using Flattop Fissions) was an amazing success and the highlight
of my career thus far (choose your favorite meaning... Homer's favorite beer, Dixon's middle name, or getting off your duff). For less than the
cost of 1 LANL FTE (~$600K), we were able to conceive and pull off the first
fission power system test within the DOE (if you’re waiting for the proviso, e.g.
in several years or within the last decade, there isn’t one – every power reactor
that has operated within the DOE was completed or under construction before DOE
was formed in 1977. Now, DUFF was
clearly a very simple test, but that’s by design – we had to prove to NASA,
DOE, LANL, and especially ourselves that is was still possible to do anything
“real”.
DUFF was
a rudimentary test of a fission power system which linked a compact fast
reactor with Stirling converters via heat pipes (DUFF_Final_Report). Other “firsts” were
the first test of a reactor that used heat-pipes to transfer fission power, and
the first fission system to using Stirling energy converters. In addition to simply producing electricity
(lighting the panel) with fission energy, and numerous lessons learned
(DUFF_Lessons_Learned), the thing that impressed me most was how well the experimental
results matched the codes that others (MCNP) and I (FRINK) have written. Prior
to DUFF I had always wondered in the back of my mind if we were fooling
ourselves with our confidence in our models (we still may be, but it’s much
less likely than before).
KRUSTY
(Kilowatt Reactor Using Stirling TechnologY) takes DUFF to the next level, and very
close to prototypic of the proposed Kilopower reactor (Kilopower_Rx_Concept). The entire
core, structure, heat pipes, and power conversion will be flight prototypic,
including the power levels and temperatures. If it succeeds there will be no
questions about reactor operation and dynamics; the key remaining risks will be
lifetime risks with the materials and components.
When we
were proposing DUFF 2.5 years ago, the vast majority of people we told said we
were nuts (stupid, naïve, etc.), and those were the people we trusted enough to
tell. In retrospect, if we had operated
business-as-usual they would have been correct.
We basically plowed forward without taking no for an answer. We had daily obstacles that threatened
success, but instead of pausing to rethink what we were doing or why, we took each
obstacle head-on and stuck to our goal of light-the-bulb-or-bust. In the end, it turned out that almost every
obstacle was not actual policy and regulation, it was people’s long standing expectations
and interpretations of policy and regulation, which had morphed into a
potentially encumbered bureaucratic process (where there is no real incentive
for a decision maker to approve anything new or different).
One of
the many reasons DUFF succeeded was by keeping the team small. If we had gone to the DOE office that “specializes”
in space reactors, at best they would have said we need to spend millions to
ensure that we’re testing the right system (i.e. trade studies) and millions
more to prove that the test would work (because failure might make them look
bad). Why not spend far less to simply see if it works? I think the answer is that wasting millions
on a paper studies cannot get a bureaucrat in trouble (in fact the more money
that flows through their office the better), while making a decision and taking
a risk can; note: I’m not talking safety
risk here, we spent the time and money to meet all safety requirements within
our $600K, it’s that “decision makers” these days get kudos for compliance and not
upsetting the apple cart rather than accomplishment, so there’s little
incentive to do anything new. DOE has a
“process” for doing things the “right way”, which requires that every decision
is backed by reams of paper and the consensus of grey beards. The aforementioned DOE office claims we are
“cowboys that will eventually mess-up and therefore kill space reactor interest
for good”; the grand irony is that this office has done absolutely nothing to
bring life to space reactors, and if it wasn’t for a few cowboys there would be
life to kill. Thankfully NASA and NNSA are
very supportive of KRUSTY Better yet, the
KRUSTY team from GRC, MSFC, Y12 and LANL is perfect for the job (lean, driven,
and expert in their fields), so if we can navigate the bureaucratic/political
obstacles then we might have an operating prototypic space reactor in <3
years. Finally, the “market” for 500 W to 1 kW fission power systems may be growing,
as it is becoming clearer how expensive future Pu238 will be (assuming that the
capacity factors of the ~50 year old reactors can meet the goals for Pu238
production in the first place).
Update
on Surface Power
What I’ve learned over the past 2.5 years has made me favor the heat-pipe (HP) reactor even more as compared to the pumped-liquid-metal (LM) reactor. Even back then, I thought the choice of a pumped-liquid metal system for FSP was ill-advised. I preferred the HP reactor, based on my initial 2005 pros and cons list (FSP_Cooling_Pros&Cons), but agreed to go along with LM because I was assured the ALIP pump was “proven”, plus the LM reactor does indeed integrate better with Stirling engines at the FSP power level. The latter may still be true, but I think KRUSTY/Kilopower will help alleviate some integration concerns, and at higher Stirling powers a boiler (operating with gravity) should be lower risk than a pumped-loop. More importantly, the electromagnetic ALIP pump has performed so poorly that it provides a major question mark for the future. The pump needs an efficiency of ~15% to design an attractive system (~10% to have a fighting chance), and the actual pumps have run at <5%; fortunately some testing can proceed (e.g. testing of the Stirling converter) due to the existence of wall sockets, although at efficiencies that low, the pump could heat the flow as much as the reactor simulator.
What I’ve learned over the past 2.5 years has made me favor the heat-pipe (HP) reactor even more as compared to the pumped-liquid-metal (LM) reactor. Even back then, I thought the choice of a pumped-liquid metal system for FSP was ill-advised. I preferred the HP reactor, based on my initial 2005 pros and cons list (FSP_Cooling_Pros&Cons), but agreed to go along with LM because I was assured the ALIP pump was “proven”, plus the LM reactor does indeed integrate better with Stirling engines at the FSP power level. The latter may still be true, but I think KRUSTY/Kilopower will help alleviate some integration concerns, and at higher Stirling powers a boiler (operating with gravity) should be lower risk than a pumped-loop. More importantly, the electromagnetic ALIP pump has performed so poorly that it provides a major question mark for the future. The pump needs an efficiency of ~15% to design an attractive system (~10% to have a fighting chance), and the actual pumps have run at <5%; fortunately some testing can proceed (e.g. testing of the Stirling converter) due to the existence of wall sockets, although at efficiencies that low, the pump could heat the flow as much as the reactor simulator.
In
addition, the LM selection for FSP was for a lunar mission, whereas emphasis
has subsequently changed to Mars. A Mars
vs Moon comparison shifts some of the pros and cons discussion between
technologies: a) long transit time brings the substantial NaK loop freeze-thaw
issue into play, b) the pumped system needs considerably more startup up power,
which will be tougher to provide for a Mars mission, c) the long communication
delay is more significant for the pumped system because startup/control is more
complex, d) increased gravity makes a HP-to-Stirling boiler HX look much better,
and e) atmosphere increases HP system reliability because CO2 can fill gaps
between HPs and HX (to provide gas conduction) if the braze fails.
Of course
another big thing that has changed is the success of DUFF. The “no one has ever operated a heat pipe
reactor before” opposition is gone; I don’t think that DUFF really solved a
major unknown, but it removed this perpetual red herring (why it was a red
herring is explained elsewhere in the blog/references). The other exciting development is the
explosion of 3D printing (additive manufacturing), which has quickly moved
beyond the plastic regime to high temperature metals. This could help all concepts, but clearly
benefit the HP reactor the most. If you
look at aforementioned pros and cons list, manufacturing was one of the major
disadvantages of the HP reactor. 3D
printing might effectively eliminate this disadvantage, for the core block, HP
integration, and perhaps most notably a HP-to-gas heat exchanger. A traditionally fab’d HX would have100s of
welds (doable, but with potential failure modes), a 3D printer could do it with
none!
Lastly,
politics and policies have continued to evolve that make dealing with HEU (highly
enriched uranium) increasingly more costly and with more programmatic risk. In my opinion, the US is wasting several
billion dollars a year in the name of safeguards, but I’ll leave that blog for
someone else to write. Certain space
reactor applications will always require HEU to be attractive on a mass basis,
but others could be revisited. In
general, the higher power the reactor, the lower the penalty of going to LEU –
still a major mass penalty for a fast reactor, but maybe less than a factor of
2, as opposed to in some cases a factor of 4 or more. I am also sticking to my guns on avoiding
moderated systems (hydrogen bearing) like the plague, although in some cases
some spectral softening via BeO or graphite could make some sense (but I’d bet
against it).
A
high-power Mars surface reactor, say 1 MWt (~200 kWe Brayton), might be in the
range where LEU would not create a show-stopping mass hit, while it could
remain near the “sweet-spot” I’ve previously referred to in development
(because of the increased fuel inventory, lower power density). In this power range the trade would be between
a HP reactor and a gas-cooled (GC) reactor – my gut tells me the HP would be
lower risk, but the GC would have to be seriously considered (assuming any
lander would be impressive enough to handle the mass of an LEU GC reactor). The lowest-risk system might be a low-temperature
Brayton (~900 K) with a SS/UO2-HP reactor (maybe UN and/or maybe super-alloy if
the potential loss-of-ductility risk was worth another 100 K). We’ve considered >1 MW HP reactors in the
past for use on Earth (MW_HP_Reactors), and while they might provide several headaches during construction, MW Mars surface HP reactors would be the easiest to qualify (without a GNT) and offer very high system reliability. If a high temperature Brayton (>1100 K)
was available, then I might consider the GC concept that we designed for JIMO –
a Nb1Zr/Re/UN core with a super-alloy pressure shell. The need for a higher-temperature
concept would depend mostly on mass limitations and the difficulty of deploying
large radiators on the Mars surface.
Update
on Nuclear Thermal Propulsion (NTP)
I have
spent a lot of time over the past 2 years designing NTRs for NASA. Honestly, there nothing more interesting to
work on as a reactor designer; attempting to balance neutronics, temperatures,
peaking factors, flow rates, Mach numbers, and pressures while pushing the
materials to their limits. The fact that
they were able to build and test some of these machines in the 60s is truly
astounding – the people working on ROVER/NERVA were the super heroes of nuclear
engineering! However, now that I am even
more familiar with what was actually accomplished, I am even more pessimistic
about the ability to successfully develop an NTR in today’s environment. The old photos and videos might make NTRs
look like a done deal, but in addition to not solving fuel erosion after
repeated nuclear test iterations, they never got to the point of testing an NTR
that was prototypic to the proposed flight system. Also, the closest-to-prototypic rocket test
(XE) had a substantially lower pump outlet pressure and chamber temperature
than the designs currently being touted by NASA and DOE (proposing 1900
psi/2750 K whereas XE was 970 psi/2280 K, actually <2100 K net if you
include the turbine exhaust); the Peewee reactor hit an impressive 2550 K
(still a ways from 2750), but did not integrate this performance with potential
engine dynamics. More so, the XE test
did not include the dynamic effects of returning turbine exhaust to the system,
and more importantly the effect of moderated tie-tubes, which have extremely
large neutronic feedback coefficients (the hydrogen worth is huge, especially
at the proposed pressures). I’m fairly
confident in these “facts”, but not 100% sure, so if I’m wrong on something let
me know. As for my opinions, think about
this… in the 60s, when nuclear testing was orders of magnitude simpler/cheaper
to pull off, they performed more than a dozen nuclear tests and still hadn’t
tested a prototypic system or solved fundamental problems with the fuel. Then, add that the previous testing was at
substantially lower temperatures and pressures than what is currently being
sold as a heritage technology. My
opinion is that a cermet-fueled NTR would have a better chance of being
developed that a composite-fueled concept (for various reasons that I won’t
expand on now), but both should not be considered at all until we take several
successful steps in developing simpler space reactor systems; although by then
it will probably make more sense to pursue NEP than NTP regardless.
Finally, I've been dismayed as proponents of NTP and NEP have overemphasized the risks of radiation in space. In response, over a year ago I wrote a response entitled "A Trip To Mars Reduces an Astronaut's Risk of Cancer" (Space_Radiation_Risk).
Finally, I've been dismayed as proponents of NTP and NEP have overemphasized the risks of radiation in space. In response, over a year ago I wrote a response entitled "A Trip To Mars Reduces an Astronaut's Risk of Cancer" (Space_Radiation_Risk).
