Presented without comment. It speaks for itself.
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Wednesday, February 25, 2026
Saturday, February 21, 2026
Space-Based AI? Not Easy!
I see a lot of hoopla and speculation about why Elon Musk has “officially” changed his goal from Mars to the moon. The answer is simple in the shorter term: money talks!
Musk’s companies SpaceX and Tesla are both serious
government contractors. SpaceX provides
launch services to NASA and to DOD, plus
it is contracted to attempt to land humans on the moon for NASA’s Artemis
program. I am unsure whether the Tesla
connection has to do with electric vehicles or the “Powerwall”, but that does not really matter.
The point is, much of
the income for both SpaceX and Tesla come from their government contracts. It is one thing to honestly try to fulfill a contract
and fail. It is quite another thing to
default by not making the attempt.
Musk is being paid by no one to go to Mars. Why is this hard for anyone to
understand? He must focus SpaceX’s contracted
efforts on the moon, or else lose
funding, and worse, all credibility as a government contractor.
There’s also been a lot of hoopla over recent Musk
statements about AI data centers, in
space, or maybe on the moon. I see all sorts of speculation about
this, none of it based on any sort of facts.
AI data centers involve enormous amounts of power. All of that power gets eventually converted
to waste heat, which must be gotten rid
of, somehow. Yes,
space is cold, but getting rid of
waste heat in space is just NOT that easy!
In space, there is no
heat loss capability due to either convection or conduction. There is only thermal radiation to the cold
background of deep space. On the
moon, there could be conduction into the
lunar surface, but no convection, because there is no air. Mars is similar, with “air” that is close to vacuum.
As for “in space”,
the cheapest destination is Earth orbit.
And from there, the only way to
shed waste heat, is to radiate it into
deep space.
I ran some numbers.
They do NOT look very good, if
one is limited to a coolant temperature compatible with cooling silicon
electronics, which is near the boiling
point of water at normal atmospheric pressure.
Thermal radiation is bound by physics to be inefficient, until the radiating surface is well above 1000
F. The relative effects are given in the
figure.
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Sunday, February 15, 2026
The El Paso Airport Shutdown Fiasco
Update 2-17-2026: A slightly toned-down version of this ran as a board-of-contributors column in the Waco Tribune-Herald, Tuesday, 17 February, 2026.
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A few days ago, the
FAA closed all airspace over El Paso,
Texas, for 10 days, catching everyone by surprise. A few hours later, they rescinded that order, but a lot of damage to air travel had been
done. And, during the closure, even emergency services like air ambulances
were grounded. This caused a lot of
problems, and created the uproar we have
seen in the news recently.
Lies and misinformation and wild speculations immediately
flooded both the internet and the news.
There were mentions of laser weapons,
of drug cartel drones, of
military involvement, and more, all of it very confusing. This initially was made even worse by lies
about what happened, from Trump
administration figures.
As usual, there were
grains of truth in many of these speculations,
but how it all fits together is very different. The drug cartels really do use drones to
smuggle drugs across the border. That
really is the best way for them to do it.
Which brings up the next question:
how do you stop the drones?
Somehow, Customs and
Border Protection (CBP) obtained a military laser weapon intended to shoot down
incoming drones. How they obtained
it, and from what agency within the
military, is still unclear. What they did with it, is the start of a big problem.
Without notifying the city of El Paso, the airport,
the FAA, or anybody else, CBP started trying to identify and shoot down
some drug cartel drones. They did this
in close proximity to the airport, which
is quite close to the Rio Grande border,
actually.
That was the first big mistake: not telling anybody. The second mistake was misidentifying a party
balloon as a drone. Given the small sizes as seen from a
distance, that is quite understandable. They shot it down with the laser.
Exactly what happened next is unclear, but somehow the FAA learned of lasers being
used near the El Paso airport, probably
from their air traffic control employees in the tower, and maybe the pilots flying near the
airport. Even low-power lasers near
airports are already a forbidden and illegal hazard nationwide. That is what prompted the FAA to close the
airspace over El Paso entirely, because
they did not know what was going on.
It is not clear exactly who finally called whom and when, but when the FAA learned it was CBP trying to
shoot down drug smuggling drones, and
their activity had ceased, FAA rescinded
the shutdown. About this same time, the administration figures started claiming
that their border agents shot down a drug smuggling drone with a laser
weapon, as if that would “justify”
disrupting air travel around El Paso so badly.
Then, the “party
balloon” thing surfaced, as it
inevitably would, if CBP had misidentified
a balloon as a drone, and shot it
down. Most likely, that is why they stopped firing the laser
weapon, when they realized they had made
a target identification mistake. There
are a lot of drones flying over the border,
so confusion and mistakes are easily understandable.
Since the event, I
noticed that no administration or CBP people have admitted to what really
happened. The administration has ceased
lying about “shooting down a drone”,
which indicates the veracity of the claim that CBP downed a party
balloon by mistake.
What this episode really indicates is the extreme
incompetence of Trump appointees heading various agencies. This was evidently an experiment to see if
CBP could actually shoot down drug-smuggling drones with a military laser
weapon. If they could, that would certainly be something we all can
agree that they should be doing, if they
can do it “right”.
But doing this dangerous experiment right next to a busy
airport in a big city, was stupid in
the extreme, because it endangered
significant commercial air traffic!
Doing it without telling anyone they were going to do it, was even stupider! Not understanding that the main difficulty
would be target identification, plus ignoring
the hazard of laser injury to innocent bystanders, was egregiously stupid!
The proper place to have done this was many miles further
downstream, away from El Paso and its
airport. There would less drug drone
traffic to shoot at, but the risk to air
travel would have been far lower, and
the local airspace closure to do it “right” would have affected far fewer
people.
So why did they not do it “right”?
I already told you:
incompetent appointees.
Appointees willing to do anything Trump wants, but demonstrably incompetent to do anything
right. Our government is rife with
such. We see it almost every day in the
news.
You can fix that, at
the mid-term election, by voting out of
office all of Trump’s enablers in Congress.
You can, unless he can
successfully steal it with voter suppression and gerrymandering, something all of you have also already seen
going on in the news.
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Since I first wrote this, I did find out that the laser weapon was Blue Halo’s LOCUST weapon, pictured. Supposedly, this is a 20 KW laser system. Blue Halo has been acquired by Aerovironment. The weapon was seen at a conference mounted to an Army Strycker vehicle. It was also seen near El Paso last August, according to Axios.
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Friday, February 13, 2026
More About Trump Treasons
This is essentially the text I sent to my federal
representation, as of this date:
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These are but two headlines I saw on the PBS NewsHour
Website on this date, related to the
weakening of NATO by Trump’s insults and threats toward our allies:
Strained U.S. ties loom over NATO leaders ahead of Munich
Security Conference
By Nick Schifrin, Veronica Vela
'Are we still on the same team?' Ischinger asks as Trump fuels NATO tensions
By Nick Schifrin, Sonia Kopelev, Dan Sagalyn
Our NATO alliance helps to protect us all against Putin’s Russia. Putin and his Soviet predecessors have all wanted to weaken or destroy NATO, but could not! Trump is doing it for Putin, as the quoted headlines attest! Putin’s Russia is the indisputable enemy of the US (and most of Europe). Trump weakening the alliance is doing what Putin wants but cannot do himself. And THAT is aid and comfort to the enemy, per the Constitution!
The US and NATO have an ally and proxy in Ukraine, to help hold back Putin’s ambitions in
Europe. (I think it was a mistake not to
put Ukraine into NATO long ago, long
before even Putin’s illegal annexation of the Crimea.) Nevertheless,
Ukraine has held back Putin with aid and weapons from the US and
Europe, for several years, even past the invasion.
Trump took office for his second term and almost immediately
stopped US aid to Ukraine. Within but
days he removed the US sanctions that had impeded Russia in its invasion. It has since taken about a year to deplete
the weapons coming only from Europe, so
that Zelenskyy is forced to surrender and sue for peace, on some or all of Putin’s terms, which is so very evidently the entire point
of Trump’s so-called “peace process”.
The image dates to August 2025. At one of Trump’s “peace process” meetings.
How is forcing an ally to surrender to an enemy NOT
providing aid and comfort to that enemy?
That’s one count of aid and comfort treason for betraying
Ukraine, and multiple counts of aid and
comfort treason for every ally in NATO that Trump has alienated. Including especially Denmark and
Greenland, against which he threatened
war!
DO SOMETHING ABOUT TRUMP’S TREASONS! Or else be complicit in them!
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There will be a reckoning for these crimes; it is coming!
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Incompetents End the Fight Against Climate Change
Donald Trump and his appointed EPA Administrator Lee Zeldin have ended the EPA’s fight against climate change by repealing the EPA’s “endangerment finding” policy. That policy was supported by very-strong, evidence-based science that cannot rationally be disputed.
These two men are entirely incompetent to judge the
veracity of a scientific finding! We
already know that about Trump and the many lies he tells, including the long-debunked “climate change
is a hoax”. He demonstrably does not value truth or fact, and never has.
Zeldin is not competent to make that judgement either. He got a law degree, not a science degree, and has only ever been an elected politician! He knows nothing of science! So why did Trump put him over the EPA? Because he would do what Trump wanted him to
do, no matter how wrong. The same as all his other appointees.
This further endangers the lives and livelihoods of
Americans by “justifying” the repeal of all the pollution regulations, making Trump’s giant corporate donors
(especially but not exclusively in the fossil fuel industry) even richer! They get richer at YOUR expense, I might add!
Your air and water are about to get dirtier, to the point of killing a lot of people. We have seen this before, and it took decades to fix.
The EPA guy Zeldin is not the only incompetent Trump has
appointed (nearly all of them are). The
other most glaring example is his HHS Secretary, RFK Jr.
This idiot wants to take away from you all the immunizations that keep
you and your children safe from things like polio, smallpox,
diptheria, tetanus, yellow fever,
Covid, and the flu. And even things like mumps, measles,
and chickenpox (which sometimes do kill,
especially measles).
His anti-vaccine lies have already caused massive disease outbreaks. But he got his kids vaccinated! How hypocritical is that? Does that tell you anything? It should!
If you are tired of being treated like crap by these incompetent
idiots, then vote them all out of
office! That includes Trump, who is not only an incompetent idiot, but a convicted felon, and a now-almost-successful wannabee dictator,
who has created a secret police force to
intimidate you, out of what used to be ICE. Plus,
he is the most prolific egregious liar I have ever seen, since Hitler’s propaganda minister
Goebbels. And all his underlings do the
same lying, about everything!
You are paying the price for his tariffs! You are getting infected by the
diseases he refuses to fight! You
are going to die fighting the wars he needlessly starts. You will be killed for his
desires! You believed his lies
and voted him in, twice! You should be ashamed!
You need to write your representation and demand that
Trump and all his incompetent appointees be impeached and removed! Go
protest! Do something! I already have!
And stop believing the lies!
Myself, I never did
believe any of them, but then I was
taught science and facts and critical thinking in the public schools, long before these idiots dumbed those schools
down, with their stupid tests!
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Tuesday, February 3, 2026
The Trump Dictatorship Is Here
The Trump dictatorship
is almost fully in place, today! The figure shows 7 of
10 hallmarks fully in place, with the
other 3 mostly completed. Looking at it should
scare the ever-lovin’ hell out of you!
And this dictator is also a traitor, on at least 2 counts of the aid-and-comfort type of treason, as defined in our Constitution. He has betrayed one ally (Ukraine) to the enemy (Putin), and he has weakened all our alliances by angering or threatening to attack allies!
We are already in a
situation where we cannot trust the public statements of any high official in
this Trump administration. Not the
leadership of the DOJ, not the leadership of the FBI, not Homeland
Security, not Health and Human Services, not the FDA. They
all lie egregiously, essentially every time they speak. We
have already seen it! You dare believe NOTHING that any of them say!
All these appointed offices have been packed with dedicated Trump supporters as their leadership, who will very apparently say anything Trump wants, or do anything Trump says, no matter how illegal or evil. We’ve seen our immigration agencies turned into a secret police force, deliberately being brutal to intimidate the population, and killing people! This has occurred in several opposition-led cities, the latest being Minneapolis.
You can no longer believe even the Supreme Court! There were 3 pre-existing far-right justices, to which Trump added 3 dedicated supporters, and THAT is where the current Supreme Court majority came from, that has made such bad decisions recently! They have been very busy over-ruling lower court decisions that were not in favor of Trump, which are coming from those lower courts Trump has not yet packed with rabid supporters. And, they gave Trump immunity for any crimes he commits while in office!
Some lower courts are already packed with rabid Trump supporters. This is why needless court delays forced Jack Smith to drop two slam-dunk-conviction criminal cases against Trump, because they would not go to trial before the 2024 election, which Trump might win (and he did). Without those needless delays, Trump would have been in jail and therefore un-electable, by the 2024 election time.
Summarizing: both the Executive and Judicial branches are essentially already taken over and neutralized as the sources of any opposition to Trump.
As for Congress, opposition there is already neutralized because (and as long as) the Trump personality cult that used to be the GOP holds the majority of seats in both houses. Which is also why I believe there will be no laws made to retard any of this evil that is going on, including that being done by the secret police force.
Possible premature loss of control over Congress is why Trump is so desperate to steal the 2026 election with the gerrymandering he demanded! If he gets past that election with his control of Congress still intact, he will have time to finish purging the military of high-ranking officers who might oppose him. Once that purge is achieved, he no longer needs or cares about control of Congress! Trump as a military-supported dictator will be a fait accompli.
If Trump fails to steal the 2026 election, he is in some trouble, with an impeachment coming from the House. It only takes a simple majority to do that, and he has already publicly warned his supporters about that risk. But, it takes a 2/3 majority in the Senate to convict him! I don't foresee a 2/3 majority of the opposition coming from the 2026 election in the Senate, so a significant number of disaffected GOP members would have to vote with the opposition to convict. I do NOT believe that to be a very probable outcome!
Failure to convict in the Senate leaves him in place as dictator, and if that happens, he will convert the 2028 election to something rigged or a sham, should he live that long. If he does not live that long, we are in for civil wars to see which cultist succeeds him as dictator. That will likely have factions of the military fighting each other, and killing us, too.
That failure-to-convict outcome leaves ONLY revolution in the streets as the lone remaining way to get rid of him, before it is too late and we are destroyed by civil wars among competing dictator-wannabees trying to succeed him! And, he will be fully-supported by the surviving high-ranking military officers, by somewhere around the 2026 election time, or shortly thereafter. “We the people” outnumber the military, but they outgun us! Revolution in the streets is a bloodbath at best!
And the real problem with revolution is, about half of "we the people" were suckered by the lies into becoming Trump cult believers and voting this dictator into office! Twice! That likely means there are fewer of us than we'd need, by far, to fight the revolution. Why? Because nothing changes the minds of fervent cult believers! They will fight against the rest of us, whether it is for Trump, or one of his successors. Why? Because they prefer belief over facts and evidence!
Let's just say I am pessimistic about our future as a free people. VERY pessimistic!
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Sunday, February 1, 2026
Rocket Nozzles
This article is intended to acquaint the nontechnical or
non-specialized person with the basics of compressible flow in rocket nozzles, and how they are sized for rocket engines and
rocket vehicles. Scope here is limited
to only conventional bell nozzles.
The author had two 20-year careers, the first in aerospace/defense new product
development engineering. He is
qualified! The second was mostly
teaching at all levels from high school to university, but with some civil engineering and aviation
work, as well.
Nontechnical and non-specialized people have difficulty with
this topic, because the behavior of
supersonic compressible gases is quite foreign to their experience. This paper attempts to address that, as simply as is possible, so that the behavior is not so foreign as to
obscure what is needed to do the figuring.
A familiarity with high school-level algebra is the only
math required! There are spreadsheet
tools to do this kind of figuring, but
it really helps for the user to understand what the spreadsheet is actually
doing for him or her. That’s how to
detect input problems.
The converging-diverging passage of a rocket nozzle is quite
unlike the garden hose sprayer gun or spray nozzle that most people are
familiar with! On the subsonic side of
the throat, behavior is familiar, because the flow accelerates in speed (and the
pressure drops) as the passage narrows.
It is the supersonic side, downstream of the min-area throat, where behavior is quite unlike common
experience. The supersonic flow
continues to accelerate in speed (with further drop in pressure) as the
passage grows larger! Other
than that, the nozzle works to expel a
fast jet that creates thrust, by means
of the large pressure drop from upstream of the nozzle out to ambient
conditions. That is grossly the same as
the garden hose sprayer experience,
actually. Just the
supersonic-side details are different!
The gases cool off as they accelerate in speed, because the sum of the heat energy and the
flow kinetic energy, anywhere in the
nozzle, is a constant that pretty much
matches the heat energy of the almost-stationary gases upstream of the
nozzle. Energy conservation is not all
that unfamiliar a concept, even for
nontechnical people.
Everyone is familiar with the reaction “thrust” of a garden
hose, or more especially that of a small
fire hose. That thrust is the momentum
of the ejected stream of water. The
faster it moves, the bigger the thrust. The more water is ejected, the bigger the thrust. Simple!
In the compressible nozzle, the momentum of the ejected stream of gas is also part of the reaction thrust, but there are pressure forces that are also part of the thrust, unlike the water hose. The pressure of the gas just as it leaves the supersonic nozzle exit can be quite different from the surrounding atmospheric pressure! The thrust of a rocket nozzle is the sum of the exit momentum and the pressure forces at the exit plane. See Figure 1.
Figure 1 – Fundamentals of Compressible Flow Nozzles
That difference in pressure between the exiting gas stream
and the surrounding atmosphere leads to some behaviors of such nozzles, that would otherwise look incomprehensible to
the nontechnical or non-specialized person.
There is a force associated with the exiting gas pressure that adds to
thrust, and a force associated with the
surrounding atmospheric pressure that subtracts from thrust. Both of these pressures act upon the flow
cross section area right at the exit plane.
As shown in Figure 2,
when the exiting gas pressure is greater than atmospheric, we say that the nozzle is
“underexpanded”, since expansion to just
the right size larger exit area, would
reduce that exiting gas pressure to exactly atmospheric, while at the same time increasing its speed still
further. This is the leftmost image in
the figure, corresponding to a high
chamber-to-ambient pressure ratio. The
exiting plume actually spreads out wider after leaving the nozzle exit, because its pressure really is higher than
atmospheric.
For the same geometry,
the “perfect expansion” to atmospheric pressure, at a slightly lower chamber-to-ambient
pressure ratio, is the second image in
the figure. That exiting plume neither
spreads wider, nor does it narrow, after leaving the nozzle exit! The pressure forces add to zero, leaving only the momentum component of
thrust.
The third image shows what happens when the exiting gas
pressure is lower than atmospheric, but
not by too much. We call this “overexpanded”, because at this pressure ratio, we would need less expansion of the nozzle
passage than we have, to bring the exit
pressure back up to equal to atmospheric. The plume actually does contract
some, after leaving the nozzle exit! Under certain circumstances, the indicated oblique shock waves from the
exit lip can actually be seen, often as the lead in a series of “shock
diamonds”.
Figure 2 – Nozzle Behavior as Chamber to Ambient Pressure
Ratio Reduces
Where one gets into trouble is illustrated in the 4th
and 5th images in the figure,
where the chamber-to-ambient pressure ratio is too low for proper
operation. The oblique shocks first
coalesce into a normal shock wave at the exit plane, then move a bit upstream, causing flow to separate-off of the inner
wall of the nozzle! The lower the
chamber-to-ambient pressure ratio, the
further upstream this shock-separation phenomena moves! Flow downstream of a normal shock is always
subsonic (meaning very low speed), so
there is very little thrust, once the
shock is inside the nozzle and separating the flow from the wall.
The “trouble” one gets into is called “shock-impingement
heating”. Where the shock wave hits the
nozzle wall (causing flow separation),
there is a large but very local amplification of the rate at which heat
is transferred from the hot gas to the cool wall. The nozzle can actually burn through and
fail, in a matter of only several
seconds, when this happens!
The last (rightmost) image in the figure shows what happens
when the atmospheric backpressure exceeds about 50-some percent of the chamber
pressure. The throat “unchokes” (goes
subsonic), and flow throughout the
nozzle is subsonic. There is no useful
thrust when this happens. There is
almost no useful thrust even when choked,
if shock-induced flow separation occurs.
There is none when unchoked.
Most rocket engines have a set of turbopumps, with pre-burners of one sort or another to
create modestly-hot gases at high pressure,
which then get used to drive those turbopumps. How this is done varies, and is what we call the “cycle” of the
engine.
Those details do not matter to the functioning of the
rocket nozzle! All that stuff up to
the chamber right before the nozzle entrance is just a “hot gas generator” that
feeds the nozzle. It is the nozzle
that creates the thrust and its associated performance with that hot gas.
The only effect of the engine “cycle” upon that nozzle
behavior is whether-or-not any of the turbopump drive gas gets dumped
overboard, without going through that
nozzle! That does reduce the
performance , even at the same thrust! This is indicated in Figure 3, among several other things.
Figure 3 – How the Engine and Nozzle Work Together to Create
Thrust
There are a couple of nozzle efficiency factors that depend
upon the exact geometry going through the nozzle. The effective flow area of the throat is
slightly smaller than its geometric area,
because of “boundary layer displacement” effects. This can be held to a minimal difference, by using a smooth profile curve through that
throat, from ahead to downstream. Effectively,
you just need the profile radius of curvature to be about the same as
the throat diameter, in order to get a
good, high discharge coefficient CD.
The shape of the supersonic expansion passage, called the nozzle “bell”, influences something called the nozzle
kinetic energy efficiency factor ηKE. Curved bells,
like that illustrated, have half-angles
that are large near the throat, and
smaller near the exit lip, which need to
be averaged. Simple conical bells have only
the one half-angle. Curved bells
require careful design using a computer program that does something called
“method of characteristics” analysis.
Conical bells of half-angle equal to the average curved-bell half
angle, have exactly the same kinetic
energy efficiency, but are only somewhat
longer than the curved bell. They
require no complicated analysis in order to lay out a design!
This ηKE factor measures the effect of having
many of the exiting streamlines oriented not exactly aft. There is a very simple empirical estimate of
this efficiency, computed with the bell
average half angle, as shown in the
figure. It applies to the momentum
component of thrust, but not to the
pressure-forces component of thrust.
One does need to address the subsonic contraction area ratio
from chamber to throat! If this is not
large enough, the flow Mach number at
the nozzle entrance may be too high to use the measured chamber pressure as if
it were the “total” or “stagnation” pressure for the nozzle flow. There is a simple correction factor to
increase measured chamber pressure slightly,
in order to have exactly the right “total” pressure for the nozzle
thrust analysis.
Note in the figure that there is a nozzle massflow, that depends upon both throat
geometric area and its discharge coefficient. That massflow may not be the massflow
actually drawn from propellant tankage,
if there is dumped bleed from the turbopump drives! It is the massflow drawn from tankage that
affects rocket vehicle masses, so
for “rocket equation estimates” of vehicle performance, the specific impulse needs to be computed
from thrust using that total massflow,
not just the nozzle massflow!
The other factor affecting calculation of the nozzle
massflow is the “chamber characteristic velocity”, usually denoted as “c*”. That will be discussed below. Just be aware that experimental values are far
more reliable than theoretical thermochemical estimates.
In figuring all these things out, one needs to be aware that there are two
different design applications, each
with its own sizing methods. Those are
“vacuum design”, for use outside the
atmosphere, and “atmospheric
design”, for use down in the
atmosphere. They are done differently
using the same basic math, just in a
different sequence and with different constraints. See Figure 4.
We start by determining the “right” nozzle bell area
expansion ratio. For the vacuum
case, this number is assumed from the
outset! For the atmospheric design
case, this is determined by the pressure
ratio at the exit, in one fashion or
another. There are actually 3 distinct
options to do atmospheric design sizing.
Be aware that the very same math will analyze the chamber to
throat contraction for us, determining
whether we need to factor-up the chamber pressure measurement.
Figure 4 – Both Streamtube and Ratio Analyses Get Used First
Vacuum sizing is done to a presumed max expansion ratio,
limited only by having the engine (or engines) actually fit behind the
stage. There is simply no such thing
as a “vacuum-optimized” design!
Everything about it is constraint-driven, and constrained even more if gimballing is
needed for thrust vector control. See Figure
5.
Figure 5 – Essentials of Vacuum Nozzle Sizing
Atmospheric nozzle sizing is done in one of three distinct
ways, starting with appropriate ratios
of expanded pressure to chamber total.
These all use the same math, just
not in quite the same ways. This is
shown in Figure 6.
Figure 6 – Three Options for Atmospheric Nozzle Sizing
The option on the left in the figure is “standard” sea level
perfect-expansion sizing. One knows a
suitable chamber pressure. One
assumes the expanded exit plane pressure to be exactly equal to sea level
atmospheric pressure. That sets
the ratio of expanded pressure to total.
From that comes the exit Mach number, and from that, the expansion area ratio. These three items (and a nozzle kinetic
energy efficiency) are needed to get a thrust coefficient, in turn a way to book-keep where the thrust
comes from.
Sea level nozzles have good thrust at sea level, but their thrust does not increase much, as you climb to higher altitudes. Which in turn means the specific impulse does
not increase very much with altitude. They
typically have rather low area expansion ratios.
If you want to average a higher specific impulse as you
climb to much higher altitude, you can
obtain it by sizing the expansion ratio to a higher altitude’s ambient
pressure (top right), or by sizing
the nozzle to incipient separation at sea level (bottom right). The penalty you pay for that higher average
specific impulse during ascent, is lower
thrust right at sea level, at
liftoff, when weight is largest! So,
the design point selection is a tradeoff! These do have somewhat larger area expansion
ratios.
Clearly the compressible streamtube analysis math is crucial
to running numbers for a nozzle. This streamtube
math is illustrated in Figure 7.
Figure 7 – Compressible Streamtube Analysis
This is the analog to V1A1 = V2A2
in incompressible flow, that many people
have actually heard of, or actually even
used. The equation is different, but it is the same fundamental idea! However,
everything is figured relative to the choked min area at the throat.
One case of interest is finding the area ratio from a known
Mach number. That is a direct
solution. Just fill in the formula
items, starting with the gamma
constants.
The other case of finding Mach number from a known area
ratio has no direct solution, because
the equation is what they call “transcendental” in Mach number! It is impossible to isolate Mach number in
the equation, because it appears in two
places under very different mathematical circumstances (different exponents and
functional forms).
For that case, there
is only the iterative (trial-and-error) solution. Keep guessing Mach numbers until the equation
result is the area ratio you really want.
That is where spreadsheet-assist is so useful: it makes such iteration very easy, boiling down to just inputting the guesses in
one cell and looking at the result in another cell.
The other piece of this math is the set of compressible flow
ratios, static vs total (or
stagnation). Those are shown in Figure
8. These are “reversible” in the
sense that a known Mach number gets you all the ratios, and a known pressure ratio can be solved
directly for a Mach number. The basic
math here is based on total/static ratios,
but their inverses are what we need for thrust coefficient and flow
separation. Those inverses are included.
Figure 8 – The Compressible Flow Ratios
We use the thrust coefficient form of this math to
separate the variables, allowing
expansion ratio to be determined before actually sizing dimensions to meet a
thrust requirement. You cannot do
that, working directly in the primitive
variables! That thrust-sizing math based
on thrust coefficient is shown in Figure 9.
Thrust coefficient has two components, the vacuum thrust coefficient, and a correction term that reduces it
somewhat to the thrust coefficient down in the atmosphere. The vacuum thrust coefficient is actually
independent of the specific value of chamber pressure! The correction term depends directly upon
chamber pressure and ambient pressure,
so that the down-in-the-atmosphere thrust coefficient is also dependent
explicitly upon them, as well.
Once you know the thrust coefficient, you can use it, your intended chamber total pressure, and a thrust requirement, to find the geometric throat area. Knowing the expansion (and contraction) area
ratios, lets you define those chamber
and exit areas from that throat area!
Very simple, actually.
Once you have a throat area,
you can compute nozzle massflow,
adjust it to total, and compute
specific impulse. That is discussed
below.
Figure 9 – Thrust Coefficient Math Equations
The math for thrust-based sizing is a bit more complicated than simple performance of an already-sized configuration. This is shown in Figure 10.
Figure 10 – Thrust Requirement-Based Sizing of Dimensions
and Flow Rates
By definition of the thrust coefficient, thrust is the product of thrust
coefficient, chamber total
pressure, and geometric throat area! Once you have a thrust coefficient
defined, you can size throat area from a
required thrust value and your chamber pressure. The contraction and expansion ratios then
size those areas from your sized throat.
You can use the sized throat area, your chamber total pressure, the c* model for your propellant at that
pressure, and your throat discharge
coefficient, to size the nozzle
massflow. That and the dumped bleed
fraction define your total massflow drawn from tankage. In turn,
that and your sizepoint thrust define your sizepoint specific
impulse.
Computing performance of an already-sized system is even
easier, as is also shown in the
figure. You compute the thrust from
thrust coefficient at that altitude and your chamber pressure, and you already know the total flowrate at
that pressure. Thrust at altitude divided
by total massflow rate is specific impulse at that altitude. Very simple indeed!
Be aware that all of these estimates are computed
assuming there is no shock-separation going on in the nozzle bell! So, you
must check for that! If it
occurs, your calculated performance data
are no good! Do not use them!
The math predicting flow separation is an old correlation
from designing tactical missile rocket nozzles.
It is slightly conservative. The
math is given in Figure 11.
Figure 11 – Math for Dealing With Flow Separation
The use of this empirical correlation is quite
straightforward when computing performance vs altitude at any given throttle
setting. The nozzle expansion has a
fixed ratio of exit plane pressure to chamber total pressure. From that,
the correlation determines the ratio of separation backpressure to
chamber total pressure. That ratio and
your operating chamber total pressure,
give you the value of backpressure that will risk inducing flow
separation.
If your ambient atmospheric pressure is less than, or just equal to, the separation pressure, no separation occurs and your thrust and performance
estimates are good. If your ambient
atmospheric pressure exceeds the separation pressure, shock-separation will occur, and your thrust and performance estimates are
no good! Simple as that!
When sizing an atmospheric nozzle for incipient separation
at sea level (as discussed above), you
use the empirical correlation in reverse (which is also shown in the
figure). You know a suitable value of
your chamber total pressure, and you
literally set the separation pressure equal to sea level atmospheric
pressure. Their ratio determines the
expansion pressure ratio exit-to-chamber for your design process. That gets you a Mach number, and from that, the expansion area ratio. From them,
thrust coefficient is easy to find.
You have to think about your rocket vehicle and where it is
flying, to determine suitable thrust
requirements. Some items typical of
launch vehicles are given in Figure 12.
Cases do vary, though!
Figure 12 – Typical Considerations for Thrust Requirements
For launch vehicles, you need to accelerate the vehicle at half a
standard gee or more, above the
retarding effects of drag and the pathwise weight component. Such would apply at vehicle masses
appropriate to stage ignitions, where
vehicle weight is high. The half-gee
figure is only a rule-of-thumb minimum.
If you achieve lower, you will definitely
“dawdle around” at low speeds near the launch pad burning off lots of
propellant, without it actually buying
you very much in the way of flight speed.
Higher gee is better, but that
requires more thrust, and the engines
might not fit behind the stage. It’s a
tradeoff!
Vehicle acceleration also has max values, especially if crewed, but a lot of potential payloads have similar
acceleration limits. Those limits might
be roughly in the 4 to 6 gee range. You
can always turn off some engines while throttling others, to stay within such limits. They would occur when vehicle masses are
low, near stage burnout.
The nozzle massflow equation uses characteristic velocity c*
as the denominator. You must have a
suitable model for this value,
consistent with your propellant combination and design chamber
pressure. In the real world, c* is weakly dependent upon chamber pressure
as a power function. This is shown in Figure
13.
Figure 13 – About Chamber Characteristic Velocity (c*)
You must run a thermochemical code (computer program) on
your propellant combination at your intended chamber pressure, and your intended oxidizer-to-fuel
ratio, to determine the resulting
combusted chamber temperature and gas properties. These are theoretical values, and from them a theoretical c* can be
computed with the equation shown. It
will have a very weak power-function dependence upon chamber pressure.
In the real world,
delivered test c* is always a little less than the theoretical
value, by a factor we call the “c*
efficiency”. This factor also typically
has a weak power-law dependence on chamber pressure. Therefore,
the actual experimental delivered c* is best modeled as a weak power-law
dependence upon chamber pressure, with
an exponent that is usually crudely in the vicinity of 0.01. All of this is
shown in the figure.
In Figure 14 is a table of values for PR = Pt/Pc vs
Mach number, including values for Ac/At, created with the usual factors, for gamma = 1.2 as “typical”. Plotting Pt/Pc vs Ac/At reveals the
importance of allowing for non-zero Mach number at station c (the aft “chamber”, right before the nozzle entrance).
Pc is always measured on real engines as a simple static
pressure tap. This is the total pressure
fed to the nozzle only if the Mach number of the flow in the chamber is trivially
close to zero. For the recommended
and often-observed Ac/At ratios, this
Mach number is simply not trivial, so
the Pt/Pc ratios are not trivially close to 1!
The error incurred by using Pc as Pt would seem to range from about 1%
to 6%. Pt = Pc * (Pt/Pc for the Ac/At
ratio).
Figure 14 – Why Accounting for the Contraction Ratio Is
Important
For an engine with a maximum nominal chamber pressure of
around 3000-4000 psig in test, one might
select a pressure transducer of nominal 5000 psig capability at the very
least, which might have an accuracy of
0.25% of full scale. That would be an
expected error of 12.5 psi. That is the
inherent uncertainty, within which one simply
cannot distinguish measurements.
For 3000 psig Pc,
that 12.5 psi is 0.42% error, and
for 4000 psig, it is 0.31% error. Most of the Pt/Pc error factors in the figure
are very much larger than that, so
correcting for Pt/Pc before doing a nozzle analysis, really is crucial for getting accurate
results!
To Sum Up
Everything shown here is basically pencil-and-paper
calculation stuff, using the algebra
equations given in the figures.
However, this is better done with
spreadsheet software, to make iteration
much easier! In particular, the computation of exit Mach number from the
nozzle area expansion ratio is inherently iterative.
The latest and best version of my own spreadsheet for this
is the Excel spreadsheet file “liquid rockets.xlsx”. It has 3 worksheets, one the nozzle-sizing work space, one has a compressible flow streamtube tool
for relating Mach number and expansion ratio,
and there is one that is a propellant data library. There is a “.PNG” file that goes with
it, as the template for your results
report. You just copy-and-paste your
results into a copy of it.
Figure 15 is an overall view of the nozzle-sizing
worksheet, where it is too small to read
things in this view. The main working
area is top left across to the top center,
the results to be copied are top right,
and there are tables and plots of altitude performance across the
bottom.
Figure 16 shows the compressible flow tool worksheet
that supports this. You just iterate
your Mach number until you get the desired area ratio, then copy the pressure ratio for pasting into
the main working space. Figure 17 shows the propellant data
library worksheet. You just copy what
you need, and paste it in where it goes,
in the main workspace space.
Figure 18 shows just that portion of the nozzle
sizing worksheet where you actually do your sizing. It is large enough to read easily. Figure 19 shows just that portion of
the nozzle sizing worksheet where your results are summarized. This is what you copy, and then paste it into the results
report.
Figure 20 shows an image of the “.PNG” file that you
make a copy of, and then paste your
results into it, and finally do some
minor final edits as needed. This “.PNG”
file was drawn in the old 2-D Windows “Paint” software, which is where I do my copying and pasting
and editing.
Figure 15 – Overall View of the Main Nozzle-Sizing Worksheet
in the Spreadsheet File
Figure 16 – Image of the Compressible Flow Tool Worksheet
Figure 17 – Image of the Propellant Library Worksheet
Figure 18 – Image of the Main Working Area of the
Nozzle-Sizing Worksheet
Figure 19 – Image of the Results Summary Block on the
Nozzle-Sizing Worksheet
Figure 20 – Image of the “.PNG file” Results Report Into
Which Results Get Pasted
Such spreadsheet tools already exist and are freely
available to interested persons. In
particular, a good spreadsheet embodying
the rocket nozzle math calculations, is
available as part of the course materials included with the “orbits+” course
materials on the Mars Society’s “New Mars forums” website. These are available to anyone for free
download. That rocket spreadsheet is same
“liquid rockets.xlsx” that was just described.
You go to the forums website newmars.com/forums/. Go to the “interplanetary transportation”
topic and select the “orbital mechanics traditional” thread. The links to all sorts of lessons and multiple
spreadsheets are in those postings.
These go way beyond just rocket nozzle sizing and performance, to include orbital mechanics, and even entry, descent,
and landing. All these materials
are located in an online dropbox accessed by those links.
The author has other materials and courses available
directly from him. Contacting him by
email is preferred at gwj5886@gmail.com. He has a blog site with all sorts of stuff
posted, much of it technical. That is http://exrocketman.blogspot.com. You may copy anything you like from that blog
site. He also has a presence on
LinkedIn, and another on Youtube under
the name “exrocketman1”.
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Appendix – Where the Thrust Coefficient Comes From
The boundary layer displacement factors are all very close
to 1 and so divide-out of all the Ae/At ratios.
It appears explicitly only in the nozzle massflow equation as CD, not in CF.
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