On Pressure Vessels

One can build an unpressurized liquid tank to any desired shape,  unless it is so large that the depth of liquid inside exerts a significant pressure all by itself.  The same is not true of pressurized vessels,  even small ones,  beyond a “single handful of psi” gage pressure inside it.  There are very good reasons these tanks are only made in spherical shapes,  or as right circular cylinders with hemispherical or spherical-segment ends. 

This document presumes the reader knows what “gage pressure” means,  and what mechanical stresses and strains are.

Figure 1 shows a cylindrical pressure vessel holding gage pressure P inside.  This could be a tank,  or even a pipe or a tube.  The “hoop stress” is given by the formula shown top right,  which is sometimes referred to as Barlow’s pipe stress formula,  which is a measure of the stress trying to  split the cylinder open longitudinally.  Technically,  you use the cylinder inside diameter for this formula (a requirement working with pipe and tubing),  but as long as the material thickness is small compared to the diameter,  something true of rocket cases and propellant tanks,  there is little-or-no perceptible difference between inside,  outside,  and average diameters. 

Bottom left,  the cross-section of the cylinder,  or any section through a sphere,  is shown.  For a cylinder,  the “axial stress” is that which resists the pressure trying to part one end of the vessel from the other.  For a sphere,  it’s just the “membrane stress” that resists splitting the sphere apart,  no matter the section orientation.  That stress works out to be just half the hoop stress,  as shown.

Figure 1 – Pressure Vessel Stresses In the Vessel Material

For a cylindrical pressure vessel fitted with hemispherical ends,  Figure 2 takes this notion a bit further,  showing as it does the stress distributions on a tiny patch of material,  located on either side of the joint.  The axial stresses match,  while the hoop direction stresses differ by a factor of 2.  There are (at least theoretically) no stresses perpendicular to the material itself (the radial direction from the cylinder axis,  or from the hemisphere’s center). 

This hoop stress mismatch at the joint corresponds to a strain mismatch in the circumferential direction,  in turn corresponding to a radial displacement mismatch between the cylinder material,  and the end (or “head”) material.  The cylinder swells radially under pressure twice as much as the end or “head” swells radially,  as measured at the joint.  This distorts both the cylinder and the head locally at the joint,  as the materials bend locally,  in order to try to stay joined.  This induces large bending stresses locally,  which add in certain ways to the hoop and axial (or membrane) stresses already described.  That makes the joint quite vulnerable to local overstress failure. 

The ”fix” for this is to locally thicken the cylinder and head materials at the joint.  In effect,  the extra material “sops up” the extra imposed stresses.  For boilers,  there are very specific guidelines for how much local thickening is needed,  and how far “local” extends away from the joint.  Those rules are the ASME boiler code,  which is legally mandatory everywhere in the country,  for designing and building boilers.  Every provision represents a life lost learning that lesson.  This is serious business!

Figure 2 – There Are Distortions With Extra Stresses At the Joints

There are choices allowed for how to implement those localized thickenings at the joints.  Those are depicted in Figure 3,  and also apply to solid rocket motor case designs.  You can increase the thickness toward the inside,  or toward the outside,  or even some of both,  just as long as enough  extra material is supplied.  Finite-element stress-strain analysis can refine this further.

The same figure also shows a variation on the spheroidal end,  where only a sphere segment is used as the end membrane.  This requires a connection ring that resists radial swelling at about the same rate as the end resists radial swelling at its attachment joint.  That way,  no thickening of the membrane is required,  the ring supplies that for the membrane.  You still need a local thickening of the cylinder material at its attachment to the ring,  because of the radial swelling mismatch.

This spherical segment and ring approach lets one enclose more volume within a given length,  without making the assembly any heavier than a full hemispherical end.  This is how most solid rocket motor case closures are designed.  It is a well-proven solution.  The flatter the membrane,  the heavier the ring gets,  though.  It’s a trade-off.

Figure 3 – Full Hemispherical Ends Vs. Spherical Segment Ends With Rings

There are many possible reasons for wanting to use other shapes for one or both cylindrical pressure vessel end heads.  As long as membrane stress is insignificant (meaning very low pressure indeed!),  you can do that!  But as soon as the pressure (and the stresses it induces) become significant,  those other shapes rapidly become infeasible.  This is shown in Figure 4,  where the two spheroidal options are depicted,  along with elliptical and conical ends.  A flat end fails even worse than the elliptical,  from similar stresses that are just higher,  plus a sharp corner effect that locally greatly magnifies the local stresses even further,  right at the corner.

There is one positive benefit to a conical end,  if an axially-directed load must be carried from the cone tip into the cylinder.  This is an efficient load path for such a load.  But it is still a lousy pressure vessel choice!  It will require a lot of internal stiffeners to keep it from trying to “go round”.  Those are going to add significant weight,  there is no way around that problem!  You must trade off the axial load path advantage against the big weight gain incurred to make a conical shape a pressure vessel.

Figure 4 – Which End Shapes Work and Which Do Not,  and Why

It is a common belief that an elliptical shape is as good as the ring and spherical segment.  This is not true from a pressure vessel design standpoint,  as the figure shows.  The elliptical head will try to “go round”,  inducing severe bending stresses.  It is volumetrically efficient,  which is why many unpressurized railroad tank cars use elliptical heads on cylindrical bodies.  But these tank cars are not pressurized!  Their evident abundance is deceptive regarding the pressure vessel issues.

That same effect is why you want to use circular cylinders as your basic tank body for a pressure vessel,  not some elliptical (or other) cross section shape.  Those other shapes will try to “go round” upon pressurization,  leading to enormous bending stresses and very rapid failure.  If you must put pressurized storage within some oddly-shaped volume,  you must fill it with multiple small circular cylinders!  The non-circular cross section is not,  and will never be,  a successful pressure vessel design!  This is why air mattress floats are made the way that they are,  for example:  multiple cylinders,  connected at the ends so as to fill together all at once.

Addendum:  Exact Analysis

The exact analysis for right circular cylinders and spheres is given in Figure 5,  along with the geometries that allow these formulations to be made from very simple measurements.  

Figure 5 – Exact Formulations

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Tariff Smarts?

I found this posted on LinkedIn,  where it was drawing quite a bit of readership.  It’s funny enough that I want to re-post it here.  Seems to be rather accurate,  really,  although the apes might be insulted by the comparison. 

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Starbuck’s Logo?

My wife found this on her Facebook.  It’s too good not to share.  Needs no comment.

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History Rhymes Pretty Close, Does It Not?

I found this on LinkedIn,  and thought I would post it here,  too.  It’s rather self-explanatory.  The parallel is quite eerie. 

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Dictatorship Is Upon You!

The main body of this article is almost exactly as I submitted it 7 August 2025 to the Waco Tribune-Herald newspaper (the “Trib”),  as a board-of-contributors item.  It is a final wake-up warning for anyone who bothers to look at it.  Update 8-19-2025:  It ran essentially unchanged in the Tuesday (8-19-2025) "Trib" on the opinion page.

The appended image below was not part of the submittal to the “Trib”,  it is something I found on-line at Getty images.  That photo was taken in Spain,  which is why the leftmost figure is their former dictator,  General Franco.  Left-to-right,  they are the dictators Franco,  Stalin,  Hitler,  and Trump.  (Missing:  Mussolini,  Putin,  Xi,  and many more.)  It would appear that most in Europe are very well aware of the evil that is happening to America!  They’ve seen this many times before!

I would only add that Trump subverting the Constitution he swore to uphold,  may not be treason per the two (and only two) definitions in that Constitution,  but it is something edging very close to treason!  Especially when throwing that Constitution away to impose a dictatorship upon America.  That imposition is now almost complete.

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Original article (highlighting added for posting here):

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Noah Feldman wrote an excellent column that appeared in the “Trib” on Thursday 7 August 2025.  While he did not use the same words as me to name what is going on,  he quite accurately described the ongoing imposition of a Trump dictatorship.  That is exactly what consolidating all federal power into the executive branch really means! 

The Supreme Court majority has been giving Trump everything he wants,  no matter how unconstitutional,  by over-ruling those lower courts’ rulings that go against him.  The Court’s minority dissent opinions clearly indicate this,  and they do indeed highlight the danger to our democracy,  if you bother to read them!  My voice is not alone!

The majority of Congress has essentially abdicated all its power to Trump,  by giving him anything he wants,  even when he tries to dismantle institutions Congress set up,  and refuses to spend funds Congress already allocated.  Both of those outcomes are entirely unconstitutional,  by the way!  Read it for yourself,  including all the amendments.  Congress’s last power,  the power of the purse,  is now no more! 

Between the Supreme Court and Congress,  the checks and balances have effectively already been destroyed!  That was the real point of Feldman’s column!

Trump has begun muzzling the free press and academic institutions,  as well as large corporations that might otherwise oppose what he does.  You’ve all seen this taking place in the news!  Almost no entity has stood up to him,  excepting Harvard,  and acting alone,  they have no chance!  Shame on those who failed to resist:  you have helped destroy our democracy!  Controlling all information is a hallmark of every dictatorship this world has ever seen!

Trump has weaponized ICE to do his bidding instead of following the law,  and greatly expanded it.  This is going to be his secret police to intimidate and oppress you all,  fulfilling the same role as Stalin’s KGB,  and Hitler’s Gestapo and SS.  Right now,  it is deporting everyone it can find with brown or dark skin,  legal or not,  and making them disappear to overseas prisons,  totally out of sight and beyond help! 

Hear my warning:  citizens of any color who oppose him are next!  The machinery to make people disappear is already in place!  That is another hallmark of dictatorship. 

Trump has weaponized multiple government departments and agencies with minions as their heads who will do his bidding,  not follow the law.  This,  too,  is a hallmark of every dictatorship the world has ever seen.  One of the evils is misusing executive power to punish opponents or people who say or do things Trump does not like,  such as the head of the bureau of labor statistics,  among many,  many others. 

You are about to lose your vote,  your clean air and water,  your medical care,  and your middle-class economy!  Trump and his minions have proven that they care not one whit about your life or anyone else’s,  they only care about staying in power to have control over all others!  Putting an incompetent vaccine denier in charge of your health care,  and gutting all the science budgets and environmental regulations,  is proof enough of this. 

Don’t listen to the lies,  look instead at what they have actually done!  Trump pardoned all the rioters that he incited to attack the halls of Congress,  actually starting before he lost the 2020 election.  You saw what they did,  live on television,  and you saw that Trump did not do anything to stop the rioters,  until it was clear that his congressional opponents would not be killed.  Why did he pardon the rioters?  Because they were well-demonstrated by their criminal actions to be supporters,  simple as that!  Some of whom have already gone on to commit more crimes after he pardoned them.

Why did Trump not want the Epstein files released?  Two simple reasons:  (1) he’s named in there multiple times,  which should surprise no one,  since he is an adjudged (and self-confessed) sex abuser,  in addition to being a convicted criminal (which he is now trying to overturn),  and (2) he and his minions have been lying to you for years about how the majority of their “deep state” opponents would be exposed there,  when the truth really is that they are mostly not listed.   Trump and his minions are actually the real “deep state”,  and they do not want you to know that,  before they can grab full dictatorial power over you!

The current between-census political gerrymandering talking place here in Texas (and a few other places) is part of the larger effort to rig the outcomes of all future elections.  This is exactly how the sham elections work in Putin’s Russia and in Iran,  among many others,  that being a hallmark of many dictatorships.  You’ve already seen this process start with the 2016 election:  the only elections not falsely claimed to be rigged are the ones Trump or his minions win.  The ones they lose,  they try to overturn.  Simple as that!

Your last chance to stop this is the 2026 mid-term election.  That is,  assuming their election-rigging efforts haven’t already rendered it a sham by then,  a very real risk! 

Once your vote is no more,  your only remaining choice to stay free is revolution in the streets!   And Trump knows that:  he has been cashiering all the high-ranking military officers who might choose to help you overthrow him.  Surprise,  surprise!

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Appended image:

L to R:  Spain’s Franco,  Russia’s Stalin,  Germany’s Hitler,  and America’s Trump. Photo is from Getty images,  freely available as a downloadable jpg file.  Taken at some sort of protest in Spain:  small figures being thrown into the fire.

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Rear of a Whale?

My wife found this on Facebook,  and it is too funny not to share.  Offered without further comment.

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Air Launch to Low Earth Orbit

There is a conundrum associated with launching to low Earth orbit from an airplane.  The illustration tries to sum up the various parts of it.  That is not to say that it cannot be done,  because it already has.  But,  it may,  or may not,  be an attractive way to do the mission.

The first part of this conundrum is the low speed of the launch aircraft (which for the Pegasus system is a wide-body subsonic airliner).  That forces the dropped rocket vehicle to be at least two-stage,  despite the advantage of the low stratospheric launch altitude.  As it says in the illustration,  speed at drop is the biggest influence on the rocket vehicle design,  and altitude the least,  although both are beneficial.  Mach 0.85 at 45,000 feet is but 822 feet/sec (0.25 km/s).  The drag loss of the rocket vehicle is (at least theoretically) less,  because it starts in thinner air up high.

The second part of this conundrum is not so obvious:  the level path angle of the carrier airplane at the drop point.   A low-loss non-lifting ballistic trajectory begun at stratospheric altitude would need a path angle at ignition on the order of 45 degrees,  maybe even a little more.  So,  either the carrier airplane,  or the rocket vehicle,  has to pull up rather sharply,  to reach that path angle from level flight.  One or the other must do this!

The usual airplane flying high in the stratosphere is at or near its “service ceiling”,  where there is barely enough wing lift being produced at an efficient angle of attack,  to hold up the weight,  and essentially all the thrust the airbreathing engines can make is just overcoming drag at the flight speed!  The airplane can neither accelerate path-wise,  nor can it climb!  That is the definition of “service ceiling”,  and for most planes,  it falls in the 45,000-55,000 foot altitude range,  at high subsonic speeds.  There have been exceptions:  the U-2 variants and the SR-71 variants could fly higher,  being very specialized designs.

Left unaddressed in the airplane,  the service ceiling problem puts the sharp pull-up task squarely upon the rocket vehicle to be dropped.  There are only two choices:  put wings on the rocket vehicle,  or fly it at very large angles of attack,  so that the cross-path vector component of its thrust is effectively a large lift force. 

Pegasus used large wings,  on the first stage of a two-stage rocket vehicle.  Those add both weight and drag,  especially drag-due-to-lift at the large lift coefficient needed to pull up sharply.  That pretty-well eats up the advantage gained by launching the rocket at elevated altitude in the thin air.  The wings are bigger than you would want,  precisely because of that thin air!  And that problem is why there have just not been that many Pegasus launches.

Leaving the wings off of the rocket vehicle forces you to pitch it up to very large angles of attack,  in the 45-75-degree range,  to get enough of a cross-path vector component of the rocket thrust,  to serve as the necessary lift force for a sharp pull-up maneuver.  That reduces the path-wise vector component of thrust,  while at the same time greatly increasing vehicle drag.  So,  you accelerate slowly( if at all) in rocket thrust during the pull-up maneuver,  using up a great deal of rocket propellant that adds nothing to your speed.  That also eats up any advantage of launching in the thin air,  way up high!

The only other feasible alternative is to add another large source of thrust to the launch airplane,  so that it can execute the pull-up maneuver into a zoom climb,  without stalling and falling out of the sky,  out-of-control.  Generally speaking,  you would add a source of thrust immune to the service ceiling effect,  and that is rocket thrust!  Your launch airplane would have to be modified for mixed (parallel-burn) rocket and gas turbine propulsion,  somewhat similar to the NF-104 and some of the early high-speed X-planes. 

So far,  no air-launch carrier plane has had this design approach,  but it certainly would be possible!  And it would take care of the high path angle requirement that is second only to speed at launch in importance,  while keeping the wings on the airplane where they belong,  and not on the rocket vehicle!

That leaves speed at launch,  the most important variable affecting the rocket vehicle design.  There are (or have been) very few supersonic aircraft designs that are also large enough to serve as a drop aircraft for a rocket vehicle of any significant size.  Those would include the B-58 Hustler (long-retired,  and none are left),  the SR-71 (also retired,  but very expensive to operate indeed),  and the B-1B bomber (currently in service as a military strategic bomber).  

The modifications to include rocket propulsion to the SR-71 likely would not fit within its very-critical shape.  The M-21 variant that launched the D-21 drone was limited in payload size,  to the size of that drone (not very large).  A rocket might be added in the tail cone of a B-1B,  but its payload would be limited to that which would fit in its bomb bay.  That B-1B option would reach a low supersonic launch speed at the high path angle needed,  with a rather-dangerous zoom climb and recovery after drop.

That brings up the danger of supersonic store separation.  There is a very good reason that most military aircraft,  even those capable of supersonic flight,  are limited to high-subsonic weapon release speeds.  That is because the inherent wobbles of a released store will include pitch-up,  thus developing lift.  At high enough speeds,  that lift generated by the wobbling store will exceed its weight,  and it can easily fly up and collide with the drop aircraft,  before the store’s drag can pull it behind. 

It cost a destroyed airplane and the life of one of the two crew,  to learn this lesson with the M-21 trying to launch a D-21 drone (without a booster) at just about Mach 3.   That is why the drone was re-fitted with a big booster,  and launched subsonically from B-52’s instead.  It’s not that supersonic store separation cannot be done (because that booster separated at Mach 3 from the D-21).  But successful supersonic store separation is very difficult to achieve,  and the risks of doing it are inherently very high.

So how fast a drop speed can be obtained?  That depends upon the gas turbine engines powering the launch aircraft.  Those are seriously limited by the high air temperatures associated with capturing supersonic air.  Most are limited to about Mach 2.5.  There are a very few that went faster:  those powering the XB-70 at Mach 3,  those powering the SR-71 variants at Mach 3.2,  and the 500 hour short-life,  replace-don’t-overhaul engines in the Mig-25 at Mach 3.5.  So,  to have a wide range of possible engines available for new designs,  it looks like Mach 2.5 at drop is “about it” with gas turbine.  Maybe Mach 3.

So,  the answer would seem to be a mixed-propulsion airplane with gas turbine propulsion,  augmented by parallel-burn rocket propulsion,  added to enable the zoom-climb by a sharp pull-up maneuver.  This would be at high altitude near 45,000 feet,  for the drop of the rocket vehicle.  To do this successfully,  the very difficult supersonic store separation problem must be very carefully addressed!  Both aircraft and crews are at serious risk.

Mach 2.5 at that altitude would be 2419 feet/second (0.737 km/s),  less than 10% of low circular orbit speed,  so one is still looking at a two-stage rocket vehicle to reach orbit.  Deliverable payload would be limited in size by the size of the drop aircraft,  since that in turn limits the size of the rocket vehicle it can drop.

In a word,  this has already been done with subsonic carrier aircraft,  although it has proven no more attractive than vertical rocket launch,  at best.  The supersonic release has yet to be tried,  and will prove both difficult and dangerous,  although the improvement in attractiveness may be worth that effort and risk.  No one yet knows. 

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Update 8-2-2025:  Please do not misunderstand,  air launch to LEO is possible and in fact has been done more than once!  It's just not easy,  because many of the problems associated with it are hard.  They are hard enough that the attractiveness of this approach is still in question,  relative to the tried-and-true vertical rocket launch. 

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Update 8-4-2025:  For an air launch-to-orbit carrier aircraft,  the gas turbine speed limitation could be gotten around by instead using ramjet propulsion,  which for a true high speed design might reach speeds between Mach 3 and Mach 4 in the stratosphere,  limited mainly by atmospheric drag of something inherently not a “clean” missile shape. 

One would still need the rocket component of a mixed-propulsion parallel-burn scheme to achieve the necessary climb angle at launch of the rocket payload,  and one would still need to solve the dangerous supersonic store separation problem.  But this would get the highest possible speed at launch,  at the right launch angle,  and at an altitude high enough to be beneficial.

The downside is that ramjet has no static thrust!  You will need some sort of booster to reach ramjet takeover speed,  and the necessary high-speed ramjet design is going to have a takeover speed in the Mach 1.8 to 2.5 range.   Given that rocket is needed to reach the high climb angle at launch,  that same rocket is likely the propulsion needed to reach takeover speed. 

Speeds will be limited by the percentage of frontal blockage area occupied by each of the two propulsion systems.  The airbreather is fundamentally lower in frontal thrust density than is the rocket,  so it needs to occupy the larger fraction of the total frontal blockage area. 

Being a lower percentage of vehicle frontal blockage area than the ~100% of a “clean” missile design,  the max possible speed capability of a ramjet (near Mach 6) cannot be reached with this kind of a vehicle.  But the ramjet weighs far less than any possible turbojet propulsion!  That makes a smallish rocket system feasible for getting off the ground with wings,  and reaching Mach 1.8 to 2.5 takeover speed at relatively low altitude. 

From there,  you climb in ramjet to high altitude at speeds near Mach 2.5,  and pull over level to accelerate to top speed in the thin air.  Fire up the rocket to climb steeply for the supersonic store separation,  then shut down the rocket and throttle-back the ramjet to execute a zoom climb and descent back into air dense enough to support controlled flight.  Cruise back in ramjet,  then glide to a landing with the rocket in reserve for go-around capability.

The real trade-off here,  yet to be evaluated,  is whether to integrate the two propulsion systems into some sort of combined-cycle rocket-ramjet,  or leave them as separate systems to be operated entirely separately.  Combined-cycle usually seriously compromises the performance of both components,  while parallel-burn does not,  instead running into the fraction-of-frontal area problem. 

And there is also the problem of there being “no such thing as cooling air” above about Mach 3 to 3.5 in the stratosphere.  Vehicle designs flying faster than that will need one-shot ablatives for their ramjet combustor and nozzle heat protection.  Which means you must swap-out the entire combustor and nozzle unit after every flight!  Given that eventuality,  you could do a solid propellant integral booster in the combustor and nozzle unit,  like a great big JATO motor,  for the initial takeoff.  That reduces the volume (and cross-sectional area) of the on-board propellants for the liquid rockets.  

None of these issues have been resolved for an air launch-to-orbit application. 

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