Saturday, April 19, 2025

Lightweight thermal protection for reentry of upper stages.

 Copyright 2025 Robert Clark


  In the blog post “Reentry of orbital stages without thermal protection, Page 2”, http://exoscientist.blogspot.com/2025/04/reentry-of-orbital-stages-without.html , I discussed some possibilities of thermal protection for the SpaceX Starship. Chief among them was the possibility that lightweight wings added might allow the stainless-steel Starship to survive reentry without added thermal protection at all. 

Other possible methods of thermal protection discussed there were a “parashield” of Dr. David Akin and inflatable conical shield experimented for the Cygnus capsule return.






  The method used there to estimate the temperature reached was calculation of the ballistic coefficient, 
β = (mass)/(drag coefficient*area). In a report by aerospace engineer Dr. David Akin, the estimated ballistic coefficient for the max temperature reached to be 800 C, so as not to need additional thermal protection, was ca. 20 kg/sq.m. 

 However, I calculated the ballistic coefficient for the Starship to be ca. 60 kg/sq.m. Note though this was using a much lower dry mass for the Starship than now obtains. The currently estimated dry mass of the reusable Starship is in the range 160+ tons. I believe this high mass for the reusable Starship is primary reason SpaceX is having difficulty getting effective TPS for it.

 My opinion is that SpaceX should first get an expendable Starship and then proceed to reusability. This approach worked spectacularly well for the Falcon 9.
 
 In this regard it is notable Elon Musk once estimated the dry mass of the expendable Starship as only 40 tons:

Elon Musk @ElonMusk
Probably no fairing either & just 3 Raptor Vacuum engines. Mass ratio of ~30 (1200 tons full, 40 tons empty) with Isp of 380. Then drop a few dozen modified Starlink satellites from empty engine bays with ~1600 Isp, MR 2. Spread out, see what’s there. Not impossible.
https://x.com/elonmusk/status/1111798912141017089?s=61

 Then in the following I’ll use the 40 ton value for the Starship dry mass. In this case, there might be an example that would give us a reusable thermal shield for a vehicle the size of Starship. I’m thinking of the X-33/Venturestar.

08287-C50-420-B-4-FDC-A69-B-37-A594-E87808.jpg

 The length in meters was 38.7m and width 39m. For the dry mass, the total gross weight was 2,186,000 lbs, propellant weight 1,929,000 lbs, and payload weight 45,000 lbs; giving a dry weight of 212,000 lbs, or 96,400 kg.

 Using a hypersonic drag coefficient of 2, and considering the triangular planform requires multiplying by 1/2 the length*width to get the area, the ballistic coefficient calculates out to be 96,400/(2*1/2*38.7*39) = 64 kg/sq.m.
 
 Remarkably close to the ballistic coefficient of the Starship at the 60,000 kg mass of the expendable’s dry mass + fairing mass.

 But the added weight of the metallic shingle TPS of the X-33/Venturestar can’t be too high to allow the ballistic coefficient to remain close to this value.
The areal density of the metallic shingle TPS was about 10 kg/sq.m:

REUSABLE METALLIC THERMAL PROTECTION SYSTEMS DEVELOPMENT
Max L. Blosser*, Carl J. Martin*, Kamran Daryabeigi*, Carl C. Poteet **
*NASA Langley Research Center, Hampton, VA, USA
** JIAFS, The George Washington University, Hampton, VA, USA
https://ntrs.nasa.gov/api/citations/200 … 095922.pdf

 The metallic tiles had better resistance to impact and rain than the ceramics at about the same weight.

04-A5-BF90-A019-4278-A5-CC-C3-F33-E7-AFF11.png
Fig.3 Layered metallic sheeting separated by insulation.


09-E4-AEC5-8-B96-424-E-A117-AC5-A11-E2-FC7-E.png

Fig.21 Metallic TPS at same weight of ceramic tiles, ~10kg/sq.m.

At a 10 kg/sq.m. areal density, the added weight covering just the lower half of the Starship would be (1/2)*Pi*9*50*(10 kg/sq.m.) = 7,060 kg, proportionally small enough that the ballistic coefficient would still be ca. 60 kg/sq.m.

This would be advantageous in that you don’t need added wings and you don’t need an additional conical thermal shield.

BUT for this to work SpaceX would have to go back to the smaller, expendable mass of the Starship. SpaceX had tested the X-33 metallic shingles and concluded they were inadequate. But that was with temperatures developed with the higher 160+ ton Starship. With a lighter dry mass, much reduced temperatures result.

Thermal Protection for the Falcon 9 Upper Stage.


 
 SpaceX had originally intended to make the Falcon 9 upper stage reusable as well as the first stage but decided it was too difficult and chose to only make the first stage reusable. They also engaged in attempts to recover the separated fairing half’s, but decided not to continue implementing this. 

 However, the metallic shingles of the X-33/VentureStar may provide a method to recover the upper stage and fairing.

 This page gives the F9 upper stage as 12.6m long, 3.66m wide at a dry mass of ~4,000 kg, and the fairing as 13.1m long, 5.2m wide, at ~ 1,750 kg:

Falcon 9 FT (Falcon 9 v1.2)
https://web.archive.org/web/20230710234357/https://spaceflight101.com/spacerockets/falcon-9-ft/

 The interstage has been estimated as weighing 1,000kg. Then using again a cylinder’s hypersonic drag coefficient of 2, the ballistic coefficient calculates out to be:

(4,000 + 1,750 + 1,000)/(2*(12.6*3.66 + 13.1*5.2)) = 29.5 kg/sq.m.

 This is well less than the desired 60 kg/sq.m point for metallic shingle TPS. But we have to make sure the added weight of the TPS still allows the ballistic coefficient to stay below this point.

 The weight of this added metallic shingle TPS would be (1/2)*Pi*(12.6*3.66 + 13.1*5.2)*10 kg/sq.m. = 1,800 kg. Adding this on, the ballistic coefficient would still only be 36 kg/sq.m.

 Another possibility though arises from the low ballistic coefficient of 29.5 kg/sq.m from the bare upper stage+fairing without TPS. This is close enough to the 20 kg/sq.m ballistic coefficient point for a stainless steel spacecraft not needing TPS, that should be investigated for the F9 upper stage.

 The tankage, fairing, and interstage would have to be replaced by stainless-steel. The tanks are aluminum-lithium. The specialty high-strength stainless-steel as used on Starship saves about 1/3rd the weight off aluminum-lithium tanks. But the fairing and interstage are composite. The stainless-steel alloys are about the same weight as the carbon-composites.

 Doing some rough estimates it will be approx. at the 20 kg/sq.m point if the tanks and fairing are converted to stainless-steel but the interstage is jettisoned and just use a lightweight steel plate to block the engine from the high temperature air stream during reentry. 

 



Thursday, April 10, 2025

Reentry of orbital stages without thermal protection, Page 2.

Copyright 2025 Robert Clark



SpaceX is having difficulty creating an effective thermal protection system. I think they should reconsider using wings for return. For instance using sufficiently lightweight wings, it may be possible no thermal protection would be needed at all.

This is the thesis put forward here. The idea behind it was an article that suggested with sufficiently low wing loading, weight per wing area, an orbital stage might need no thermal protection at all on reentry:


Wings in space.
by James C. McLane III
Monday, July 11, 2011
Wing loading (the vehicle’s weight divided by its wing surface area) is a prime parameter affecting flight. The antique aluminum Douglas DC-3 airliner had a big wing with a low loading of about 25 psf (pounds per square foot of wing surface). At the other end of the spectrum, the Space Shuttle orbiter has a high wing loading of about 120 psf. This loading, combined with an inefficient delta-shaped wing, makes the orbiter glide like a brick. A little Cessna 152 private plane features a wing loading of about 11 psf and modern gliders operate down around 7 psf. A space plane with huge lifting surfaces and a very low wing loading might not require any external thermal insulation at all. Building a space plane with a wing loading of, say, 10 psf should not be an impossible proposition. Perhaps some day it will be done.
http://www.thespacereview.com/article/1880/1

I discussed the possibility here:

Reentry of orbital stages without thermal protection? UPDATE: 7/1/2019
https://exoscientist.blogspot.com/2019/06/reentry-of-orbital-stages-without.html
(Note: I mistakenly used the half-surface area of a cylindrical stage in those calculations. This underestimates the wing loading, in psi units. So the stages discussed there appeared better than they actually were. In the calculations in this post, I’m using cross-sectional area.)

The proposer of this idea was the legendary spacecraft designer Maxime Faget, who was the chief designer of the Mercury capsule, the first U.S. manned space capsule. Then on that basis alone the possibility should be given serious consideration.

The parameter though used to measure the capability of a particular shape to slow down descent is not wing loading, weight divided by wing area, but the ballistic coefficient, (mass)/(drag coefficient*drag area), β = m/CDA, given in metric units, where the drag area is by cross-section. This takes into account the fact different shapes are more effective in slowing down the spacecraft by including the coefficient of drag CD as well as being more general than just looking at wings for the decelerator.

A couple of ways being investigated to get a lightweight decelerator are by using a inflatable and by using a foldable heat shield.

There are several variations of the inflatable heat shield idea, sometimes called a ‘ballute’. The most researched one is a conical inflatable heat shield. It’s being investigated for example as a heat shield to make the Cygnus cargo capsule reusable:





Here’s a research article on it:

HEART FLIGHT TEST OVERVIEW
9th INTERNATIONAL PLANETARY PROBE WORKSHOP 16-22 JUNE 2012, TOULOUSE
https://websites.isae-supaero.fr/IMG/pdf/137-heart-ippw-9_v04-tpsas.pdf

In this report, the mass used for their analysis is ca. 5,000 kg and the diameter of their conical decelerator is 8.3 meters. There is thermal protection applied but I gather less of it is needed since the conical aeroshell is just made of silicone rubber.

To get the low ballistic coefficient you want to minimize the dry mass of the upper stage or capsule being returned. This is a concept understood by spaceflight engineers: extra mass added to an upper stage subtracts directly from payload. So spaceflight engineers commonly try to minimize this dry mass.

I have discussed before I believe it is a mistake for SpaceX to want to go directly to a fully reusable upper stage. Elon Musk once estimated that an expendable Starship upper stage without fairing could be made at only 40 tons dry mass:

Elon Musk @ElonMusk
Probably no fairing either & just 3 Raptor Vacuum engines. Mass ratio of ~30 (1200 tons full, 40 tons empty) with Isp of 380. Then drop a few dozen modified Starlink satellites from empty engine bays with ~1600 Isp, MR 2. Spread out, see what’s there. Not impossible.
https://x.com/elonmusk/status/1111798912141017089?s=61

Now, in their attempts at making it fully reusable the dry mass has ballooned to ca. 160 tons or more. That huge dry mass is the primary reason why they are having difficulty finding effective thermal shielding.

Then in the following I’ll assume SpaceX does go first for an expendable Starship upper stage at ca. 40 tons dry mass. Then when they do proceed to reusability of the upper stage, if it is just ballistic coefficient determining the effectiveness of the heat shield, then for a spacecraft or stage about 9 times heavier than the HEART shield for the Cygnus, say, at 40,000+ kg, then the area needs to be 9 times more, that is, a conical shell about 25 meters in diameter.

BUT, the key questions is how does the mass of the decelerator scale with the size of the reentry spacecraft? In this report the added mass of the inflatable shield is a small proportion of the spacecraft being returned, in the range of 25%. But that is for a returned spacecraft of ca. 5,000 kg dry mass, with decelerator mass of ca. 1,300 kg.The report doesn’t discuss how the mass of the decelerator scales with size. You could make an argument it should scale with the cube of the decelerator diameter. The reason is because of not just the area increasing but the shield thickness also increasing to maintain shield strength. Then for a cone shield of 3 times larger diameter the mass would be 33 = 27 times heavier or 35,000 kg. That is quite larger percentage of the 40,000 kg stage dry mass. It is still much better than the 120+ ton added mass the Starship now has in the attempt to make it reusable.

On the hand, you could make an argument it should scale by the square of the diameter. The reason is you could use multiple copies of the smaller cone shields to cover the entire returning spacecraft. So it would be 32 = 9 times heavier or 9*1,300 = 11,700 kg being added to the dry mass. This would be a more palatable increase, if that is indeed the correct scaling.

This report though doesn’t give the maximum, i.e., stagnation temperature reached so it’s a little difficult to see if steel itself would be able to withstand the heating. It describes using layers of the Nextel thermal blankets so presumably this would also work for the Starship or other stages or capsules with the appropriate size conical shield for the reentry dry mass.

But we can make an estimate of what size wings for the Starship could get similar ballistic coefficient as the inflatable conical shell and therefore existing off-the-shelf Nextel thermal blankets would suffice for the thermal shield.

For the example considered in this report, the dry mass of the returning spacecraft is approx. 5,000 kg and the area on the inflatable is about 56 m2. Then the ratio of mass to area is about 100 kg/m2. But actually the ballistic coefficient also divides this by CD , the coefficient of drag. At hypersonic speeds the drag coefficient of a 55 degree half-angle cone is about 1.5, so the ballistic coefficient is of about 60 kg/m2.

For the expendable Starship at 40 tons, adding on the fairing at ca. 20 tons brings the total mass to ca. 60 tons. At a diameter of 9 meters and length of 50 meters, the cross sectional area is 450 m2. To calculate the ballistic coefficient also need the hypersonic drag coefficient. For a cylinder entering broadside that is about 2. Then the ballistic coefficient is 60,000/(2*450) = 66 kg/m2.

This is close enough for the Starship itself without wings only using existing Nextel thermal blankets to survive reentry for reuse as long as SpaceX starts with the lightweight value of the expendable version.

Another method for lightweight thermal shielding via low ballistic coefficient would use a foldable heat shield. This is the approach investigated by Dr. David Akin, of the University of Maryland, he calls it a ‘parashield’. He described it as used for a lightweight manned space capsule here:

Phoenix: A Low-Cost Commercial Approach to the Crew Exploration Vehicle
Abstract: Since the announcement of President Bush’s Vision for Space Exploration (VSE) in early 2004, the architecture of Project Constellation has been selected. The system will be centered around the Crew Exploration Vehicle (CEV), which has been dubbed by NASA administrator Michael Griffin as “Apollo on steroids”. The CEV is to be launched on a new launch vehicle, derived from existing shuttle technology. The development of this new
spacecraft and launch vehicle is a very costly proposition. An alternate approach is proposed in this study. The Phoenix is a smaller spacecraft designed specifically to be launched on the Falcon 5 vehicle under development by SpaceX. Because the SpaceX vehicle will cost only a fraction of today’s launch costs, the Phoenix is estimated to cost less than half of the price of the CEV. This reusable three person capsule utilizes an innovative re-entry concept, which allows for a cylindrical spacecraft with greater interior volume. This extremely cost-effective spacecraft is an attractive option for fulfilling VSE requirements.




 Here’s a research article on it:

SpaceOps 2010 Conference
25-30 April 2010, Huntsville, Alabama AIAA 2010-1928
Applications of Ultra-Low Ballistic Coefficient Entry Vehicles to Existing and Future Space Missions
David L. Akin∗
Space Systems Laboratory, University of Maryland, College Park, MD 20742
https://spacecraft.ssl.umd.edu/publications/2010/SpaceOps2010ParaShieldx.pdf





The author here uses units of N/m2 which is Pascals instead of kg/m2, perhaps because he wants to use units of pressure and to make an analogy to aircraft design’s “wing loading” units of pounds per unit area. But it is easy to convert to the more common kg/m2 by dividing by 9.81, i.e., approximately by 10.

Here he takes the desired ballistic coefficient as 200 Pa, about 20 kg/m2. This article does give the max stagnation temperature so we can estimate the size of wings needed to reach that ballistic coefficient. Quite notably in this report the peak heating only reaches 800°C. The author notes this is within the temperature range of off-the-shelf Nextel blankets to withstand. But that’s what would be needed for a standard aluminum structure. Stainless steel has a melting point in the range of ca. 1,400°C. Then it maybe no additional thermal shielding would be needed at all as long as wings allow it to reach this low ballistic coefficient.

The ballistic coefficient calculated above is about 60 kg/m2. Then we need 3 times higher cross-sectional area to bring that down to ca. 20 kg/m2, or likely more if we take into account the added mass.

As before with the inflatable conical decelerator we need to know how the ‘parashield’ mass scales with size. This isn’t provided in the research report. It could be by the cube of the diameter or by the square.

I’ll make an estimate based on just the “wings” being a flat sheet of the needed size. The thickness of the Starship walls is about 4mm. But it’s been speculated in a weight optimized design they could be as low as 2mm thick. Then I’ll use stainless steel at 2mm thick.

The hypersonic drag coefficient of a flat sheet is similar to that of a cylinder at ca. 2. Take the added wing cross-section as 36m*50m, added on to the 9*50 = 450 m2 cross-section of the cylindrical Starship. Then with a density of stainless-steel of 7,800 kg/m2, the ballistic coefficient calculates out to be:

(60,000 + .002*36*50*7,800)/2*(450 + 36*50) = 19.6 kg/m2, below the desired 20 kg/m2 point.

According to the assumption the ballistic coefficient is the deciding factor, it could be horizontal wings, delta wing, or the parashields spherical section. Like in the parashield design, additional high-strength spars might need to added to withstand the applied dynamic pressure during the hypersonic/supersonic/subsonic regimes.

But the ‘wing’ is only intended to support the structure on return when the tanks are nearly empty. They might not be able to support it when fully fueled. So the Starship would have to insure to fly a non-lifting trajectory during ascent. It might further be required for the ‘wing’ to be folded away during ascent, only deploying on return.

That the wing only supports the nearly empty weight of the structure during return suggests it could be made even thinner. For instance the Centaur V upper stage at a gross weight of ca. 60 tons has stainless-steel tanks walls only 1mm thick:



Using now a smaller wing cross-section of 18*50, the ballistic coefficient would be:
(60,000 + .001*18*50*7,800)/2*(450 + 18*50) = 24.8 kg/m2.

Given the leeway between the 800°C max temperature at 20 kg/m^2 and the 1,400°C melting point of steel this would likely still be sufficient for the stainless-steel structure not needing further thermal protection.

If the added wing could be made this thin then the added weight would only be .001*18*50*7,800 = 7,020 kg, compared to the 60,000 kg of the Starship dry mass+fairing weight.

The importance of such lightweight orbital decelerators has now increased importance now that the Air Force wants rocket cargo point-to-point delivery:

Air Force picks remote Pacific atoll as site for cargo rocket trials
By SETH ROBSON STARS AND STRIPES • March 4, 2025
https://www.stripes.com/theaters/asia_pacific/2025-03-04/cargo-rocket-pacific-johnston-atoll-air-force-17026030.html

The plan is for fully reusable launchers but note these decelerators could still be used to send the cargo back down to their delivery points even with expendable launchers or partially reusable launchers where the only the first stage is reused and the upper stage is expendable. This means they can be used to delivery cargo now with the Falcon 9, and soon with the Rocket Labs Neutron and Blue Origin’s New Glenn, also planned to be partially reusable.

Sierra Space has also already contracted with the Air Force to deliver supplies that were already preloaded and stored in space to distant locations:

Sierra Space Ghost: Revolutionizing Global Logistics
OCTOBER 3, 2024


https://www.sierraspace.com/press-releases/sierra-space-ghost-revolutionizing-global-logistics/


But the very same method can be used as the orbital decelerator for a rocket cargo point-to-point delivery system. Notably, the Sierra Space method is quite analogous to the Akin’s parashield method.

High Hypersonic Lift/Drag Ratio Used for Return From Orbit.

The above discussed methods are useful for just drag decelerators. But the discussion is incomplete for winged reentry because it does not include the effects of lift. For instance if wings with high lift/drag ratio at hypersonic speeds were used the descent rate would be decreased even further, thus further decreasing the heating rate, and thereby allowing a lighter reentry system. The hypersonic aerodynamics of the Space Shuttle have been described as falling “like a brick” with a quite low hypersonic L/D ratio of about 1, thus necessitating it’s heavy thermal protection. Then wings with high hypersonic L/D ratio could greatly improve on this.

This possibility is discussed here:

Clamshell wings for hypersonic reentry of rocket stages. UPDATED, May 4, 2023.


https://exoscientist.blogspot.com/2023/02/clamshell-wings-for-hypersonic-reentry.html

In this approach there would be no extra added weight for the decelerator at all for a returning rocket stage, just the fairing or propellant tank itself as the wings.




    Robert Clark

Thursday, March 27, 2025

Why SpaceX Needs a TRUE Chief Engineer.

                                    Copyright 2025 Robert Clark 

The post below was written back in August last year. Back then any criticism of the approach Elon Musk was taking to develop the Superheavy/Starship was verbotten. Now with two successive failures of Starship upper stages for the very same reason, people are starting to ask tough questions about the development of the Starship:

SpaceX Needs A New Mini-Starship To Land Humans On The Moon And Mars.
By Kevin Holden Platt, Contributor. Kevin Holden Platt writes on space defense…
Mar 17, 2025 at 11:33pm EDT

“Our approach today has a very low probability to match the ‘before 2030’ milestone for landing humans on the Moon,” Daniel Dumbacher, who formerly served as Deputy Associate Administrator of NASA’s Human Exploration and Operations Mission Directorate, in charge of the Artemis lunar landings, testified at the hearing.

While he didn’t mention the fiery breakup of SpaceX’s Starship during its January flight demo, Dumbacher, now a professor in aeronautical engineering at Purdue University, said that the ship’s need to be refueled with super-cooled liquid oxygen and methane in low Earth orbit via multiple dockings with still-to-be-developed tankers - a complicated operation that has never been tested - before each flight to the Moon involves an assemblage of complex technologies that might not be perfected within the next five years.

“We might have to build a lander - we might have to scale down the current lander,” Dumbacher told the House, “so that we get to that 2030 landing.”

To avert potentially spiraling problems with testing the colossal Starships during the countdown to this new Moon quest, he said, “I’d get myself a simplified lander - so that I can get to the Moon - that does not require multiple launches.”

https://www.forbes.com/sites/kevinholdenplatt/2025/03/17/spacex-needs-a-new-mini-starship-to-land-humans-on-the-moon-and-mars/


__________________________________________

Why SpaceX Needs a True Chief Engineer.

Copyright 2024 Robert Clark 

 

 Elon Musk has said that early on when there was still uncertainty if SpaceX would be viable they tried to get a Chief Engineer, but nobody good would come. Musk then designated himself as Chief Engineer. 

 

 Now they could get anyone they wanted as a Chief Engineer. My opinion, SpaceX should have as a priority to get a good Chief Engineer. 

 

 SpaceX seems to want it make a point of ignoring the lessons of Apollo. When they were building their first launch tower for the SuperHeavy/Starship they were told they needed a flame trench All large launchers use a flame trench. But SpaceX, and more specifically, Musk thought they could do without it: 

 

For some reason, Musk became convinced early on that he did not want the launch tower to have: 

 

*A flame-diverter or flame trench to redirect the blast from the boosters engines 

 

*A water deluge system to dump a massive amount of water around the launch tower during liftoff 

 

The launch facilities at Kennedy have both of these. Even the launch pads used for the much smaller Falcon 9 have both a flame trench and a water deluge. They help to protect not just the launch pad, and the surrounding area, they also help to reduce the noise. Which sounds trivial, but that noise is energy. Thats what broke up the concrete under the Starship Stage Zero, not the fire. Thats what sent car-sized chunks flying in all directions. 

 

A flame diverter and a water deluge would have greatly reduced, or even eliminated, the damage to the area around the pad. They would have prevented the blow back of debris that damaged Starship before it even left the ground. It might have headed off the whole cascade of events that resulted in that button being pressed 4 minutes into the flight. 

 

We dont have to guess about whose decision it was not to implement these systems, because Musk already said he decided to skip these systems over the recommendations of his engineers. Musk even had a preview of what was going to happen, as past test flights of the upper stage also resulted in significant spalling of concrete structures and damage to at least one of the ships. He just made them try different kinds of concrete. 

 

The parts for a water deluge were actually on site, ready to install, but Musk decided to forego that installation—likely so he could enjoy the pun of launching his super-joint on 4/20. Which was something Musk had joked about doing months ago.[1] 

 

 We know now the result of that poor engineering choice with the launch pad being essentially destroyed, with concrete blocks being thrown hundreds of meters away. 

 

 Then, on top of that SpaceX made another inexplicable architecture choice from the beginning. The Apollo program and every other large launch system always constructed a full-up test stand to test all the engines of a stage at once. Instead of taking that approach, SpaceX chose to take the approach of the ill-fated Soviet N-1 rocket of only testing all the engines together during an actual flight. The N-1 became famous in the industry for its explosive failures. Instead of following the approach of the Apollo program of spectacular successes, they chose instead to follow the approach of the N-1 of spectacular failures. 

 

 This has important consequences. It might be hard to believe but we still do not know if all the Raptors together on the SuperHeavy can fire at full thrust for the full length of time of an actual mission.  

 

 The first test flight resulted in 8 of the 33 engines failing, some in actual explosions. A failure rate of 25%. Observers noted that all the concrete debris being thrown up could have damaged the engines. Elon in an interview however said there was no evidence the concrete being thrown up could have damaged the engines in a way to result in the failures. 

 

 SpaceX then was in a bad position. Either the poor engineering choice of not using a flame diverter caused the engine failures, or the engine themselves had such poor reliability that they failed all on their own. 

 

 SpaceX in defense of the Raptor reliability might argue there were no failures on the SuperHeavy engines during the ascent for test flights 2 and 3. However, taking note of the slow acceleration of the booster during ascent for these flights, there is very good reason to believe they achieved this reliability by throttling down the Raptors, perhaps to only 75%, [2]. 

 

 This puts the lack of full-up, full thrust, full duration test burns in sharp relief. This last, of “full duration”, is another way SpaceX deviates from standard industry practice and even terminology. In preflight test burns of the SuperHeavy SpaceX runs these burns for perhaps 5 to 10 seconds, then refers to these burns as “full duration”. In the industry “full duration” is used to mean “full mission duration”. They are burns of the full flight length and full flight thrust and are meant to give confidence to the launch company and importantly to potential customers as well that the engines can run reliably on an actual flight. 

 

 Then because SpaceX has not done this with the SuperHeavy, SpaceX’s most important customer NASA has no idea if the Superheavy’s full complement of Raptors can be run reliably at full thrust and full duration of an actual flight. I’m asserting that SpaceX by calling their short burns of only a few second length “full duration” is obscuring this fact. 

 

 This again goes to my point of why SpaceX needs a true Chief Engineer. A Chief Engineer should have the persona of a scientist. A scientist, at least a good one, should be scrupulously forthright even on their own research. Instead of Elon Musk proudly boasting how great are the thrust levels of the Raptor engine and how much greater it will be in future versions, a true Chief Engineer would give a more realistic and accurate appraisal. A true Chief Engineer would say something of the nature of,  

 

“The Raptor has reached very high maximum thrust and chamber pressure levels. However, we are working to improve its reliability when run at those levels. Right now when run at 75%, we are at the desired levels of reliability. We are confident though we can reach the needed reliability when run at 100% power and full mission duration.” 

 

 Instead of that, Elon Musk as Chief Engineer displays the persona of a PR maven. 

 

NASA Must Know What the True Specifications Are. 
 

 My assertion has been SpaceX was intentionally throttling down the Raptors on the booster after the first test flight to improve reliability, [2]. This fact can be regarded as confirmed by the fact the SuperHeavy/Starship has drastically reduced payload capacity than first planned. Elon has stated the payload is only in the 40 to 50 ton range at full reusability when the initial estimate was 100 to 150 tons. If you run the numbers for calculating delta-v it is mathematically impossible for the SH/SS to have a payload that low with the dry mass and engine specifications SpaceX has publicly released. This means either the dry mass numbers or engine numbers or more likely both are significantly worse than what has been released by SpaceX. 

 

 NASA must know this. The kinds of calculations known in the industry as delta-v calculations are standard methods of estimating a launch vehicles payload capacity. NASA might be of the opinion that the specifications of a company’s launch vehicle are proprietary and should not be released by them publicly, but NASA has a $4 billion contract with this company to provide an essential component of a multi-billion dollar project being funded by the public, the lunar lander.  

 

 It’s a debatable point if NASA should require SpaceX to reveal the true numbers for a project funded by billions of tax-payers dollars. But I don’t think it unreasonable for the public to require NASA to answer the question of whether the low payload capabilities of the SH/SS are what they were expecting at this point in the program, since it is the public that is providing that funding. 

 

Multiple Architecture Mistakes in the SuperHeavy/Starship. 

 

 It is irritating for those of us as observers of the space program for decades for SpaceX to simply dismiss the successes of the Apollo program, like Apollo was just some blip in the history of spaceflight. This dismissal is not just of Apollo but of standard industry knowledge. So SpaceX didn’t want to use a flame diverter, and didn’t, and still will not, construct a full-up, all engine test stand for full thrust, full mission duration tests. 

 

 But some of the mistakes SpaceX has made in the SH/SS development are just weird. It is standard industry knowledge that you have to have a physical mechanism for separating stages during staging. But SpaceX wanted to do it simply by flinging the upper stage away from the lower stage. Fortunately, they rectified that poor engineering decision with the hot-staging method now used, a method long known to be effective. 

 

 On the second test flight they vented oxygen on the second stage while the engines were still firing. Sometimes, you’ll vent propellant from the second stage once it has reached orbit to prevent the possibility of explosion, possibly harming other spacecraft already in orbit. But venting propellant while the engines are firing is a big no-no because of the possibility that itself will cause an explosion, as did indeed happen. 

 

 Pressurization gas taken directly from exhaust gases from the pre-burners??? The method used to pressurize the tanks is known as autogenous pressurization. This means the propellant itself is used to pressure the tanks rather than using separate gas such as helium for the purpose. This has been used successfully before with other engines such as the SSME’s. But the other times it was used heat exchangers were used to heat the propellant to pressurize the tanks. Placing exhaust gases directly into the tanks is a very poor engineering approach. Aside from the risk of causing an explosion, there is also the fact the exhaust products contain water and CO2. When these contact directly the cryogenic propellant directly they will tend to freeze. This is bad because the frozen ice or CO2 can then clog the engine inlet valves, as did indeed happen. 

 

SpaceX Taking The Wrong Approach to Reusability. 

 

 SpaceX’s approach to reusability is ill-conceived. SpaceX was spectacularly successful in first getting an expendable Falcon 9 then gradually working towards a reusable booster. But instead of taking that successful approach, SpaceX wants the entire SH/SS reusable from the start. 

 

 SpaceX has the spectacular success of the Falcon 9’s reusability approach right in front of them but they are ignoring it. First, it is known reusability is most importantly done for first stages because they make up the greatest bulk of the cost, plus the fact in going much lower speed they are more easily made reusable and don’t need thermal protection. 

 

 But first just get the rocket to orbit successfully as an expendable. The F9 was able to do that and make a profit as an expendable, with SpaceX all the while working towards reusability. 

 

 It might be understandable that SpaceX wanted to take the approach they're taking with the SH/SS if their cost for the launches of the SH/SS were like those of the SLS of ca. $2 billion per launch, since they couldn't get customers at that high launch cost. But Elon has said it is only in the range of $100 million per launch 

 

Then, if you make the first launches expendable, with the much higher payload without the reusability systems, then SpaceX could be making profit on these launches all-the-while working towards reusability like with the F9.  

 

 Another reason why you want to get an expendable launcher first is that extra mass on the upper stage for reusability subtracts directly from payload. For that reason, dry mass on the upper stage is treated like gold. Or said another way extra mass added to an upper stage is like throwing away the equivalent mass in gold. 

 

 Elon has said an expendable Starship might have a dry mass of only 40 tons: 

_________________________________________________ 

Elon Musk@elonmusk Mar 29, 2019 
Replying to 
@Erdayastronautand@DiscoverMag 
Probably no fairing either & just 3 Raptor Vacuum engines. Mass ratio of ~30 (1200 tons full, 40 tons empty) with Isp of 380. Then drop a few dozen modified Starlink satellites from empty engine bays with ~1600 Isp, MR 2. Spread out, see whats there. Not impossible. 
_____________________________________________________ 

 

 But the current reusable version has been cited as weighting 120 tons, tripling the dry mass. An extra 80 tons as added to the dry mass of an upper stage is huge in regards to reducing its capabilities. 

 

 To put this in perspective the dry mass of the Falcon 9 upper stage is about 4 tons. If this was tripled for reusability it would be 12 tons dry mass, i.e., an additional 8 tons. The LEO payload for reusable booster F9 missions would shrink from 15.8 tons to 7.8 tons. And quite importantly the payload for GEO missions would shrink to 0. 

 

 When you take into account the much lower expendable dry mass of the Starship and the fact you don’t wastefully leave propellant on the first stage unused on ascent, for return to launch site, the expendable SH/SS probably could get ca. 200 tons to LEO.  

 

 But remember those launches would still be $100 million per launch. That would be a cost of only $500 per kilo even as an expendable. That’s well less than even the reusable Falcon 9. At such low cost SpaceX would definitely be able to find customers just for the expendable SH/SS. 

 

 Again, SpaceX needs a true Chief Engineer. I simply cannot believe that the SpaceX leadership is aware of these numbers. A major impetus of Elon Musk in wanting to build the SH/SS is for manned interplanetary missions. A 200 ton payload capability is huge. With payload this high every SH/SS launch would have a capability of doing single launch missions to the Moon or to Mars, no multiple refueling flights, nor SLS required. With two launch towers and each tower accommodating a launch every month, this means every other week the public would be witnessing launches capable of doing manned launches to the Moon or Mars. 

 

 Keep in mind this is a capability we could have literally, like, tomorrow, if SpaceX went for the approach of first getting the expendable rocket, proven so spectacularly to work for the Falcon 9. 

 

 For those familiar with doing delta-v calculations this is based on the delta-v’s for doing missions to the Moon or Mars, [3]. But keep in mind this would require giving the SH/SS a 3rd stage/lander. 

 

 Again, SpaceX needs a true Chief Engineer. It’s basic spaceflight engineering that to do beyond LEO missions, requiring high delta-v’s, it’s most efficiently done by adding additional stages. But instead of doing that, SpaceX wants to take the approach of doing 10, 15 or perhaps even more refuelings for a two-stage launcher. 

 

 Proponents of this approach quote Elon’s dictum, “The best part is no part” in arguing against adding an additional stage. But they forget the second part of Elon’s saying. The full saying is, “The best part is no part. The best process is no process.” Rather than this additional, complicated process of multiple refuelings, it would be far cheaper, safer, and faster simply using that 3rd stage. 

 

 And even the complaint of having to construct an entire new 3rd stage is incorrect. It turns out a stage capable of filling the role already exists: the Falcon 9 upper stage. This is already a fully human-rated stage. A 200-ton to LEO capacity is so large it could launch the F9 upper stage to LEO fully-fueled and with additional extra capacity so that the F9 upper stage could perform all the additional burns needed for a round trip to the Moon and back. 

 

 For the crew capsule don’t use the overbloated in size and cost Orion capsule. Use the Dragon capsule. It was already designed to have a heat shield capable of withstanding the greater heating for return from the Moon compared to return from LEO. The only extra piece of equipment it would need is stronger communications equipment for communicating from the longer distance from the Moon compared to LEO. 

 

 And for the mission to Mars? Again, SpaceX needs a true Chief Engineer. Not only is SpaceX ignoring basic principles of spaceflight, it’s ignoring basic principles period.  

 

 For a first flight to Mars that might take years for a round trip, you don’t send 100 potential colonists who’ve never been in space before in accommodations akin to a cruise ship. You send a small crew of professional astronauts who have already experienced months long periods in space.  

 

 Imagine if for the first Apollo flights the architecture was to send 100 lunar colonists consisting of people who had never been in space before. Apollo would have never taken place under that design. 

 

 Then for a first flight to Mars, also add on a 3rd stage akin to the Falcon 9 upper stage, and a small habitat of ca. 10 tons size for a crew of 3 to 4 astronauts for the 6 to 8 month flight to Mars. For the return trip you follow the Mars Direct approach of generating the return propellant on Mars, and have air, food, water, and supplies for the stay on Mars and the return flight already in place on Mars beforehand. 

 

 Article In Nature Concludes Starship Missions To Mars Not Feasible. 

 

 The SpaceX plan is to send 100 colonists to Mars per mission. The authors of this paper conclude this is not feasible: 

 

About feasibility of SpaceX's human exploration Mars mission scenario with Starship. 

Scientific Reports 

volume 14, Article number: 11804 (2024) 

 

 A major issue the paper discusses is the power requirements for producing the propellant on Mars by ISRU. Robert Zubrin has also discussed this problem and estimated it would take 10 football fields worth of solar panels or a nuclear power plant sent to Mars to generate the needed power: 

 

 

 

NRPLUS 

SCIENCE & TECH 

Elon Musk’s Plan to Settle Mars 

By ROBERT ZUBRIN 

February 22, 2020 4:30 AM 

 

  Note that simply using a small habitat for 3 - 4 astronauts and small third stage a la the Falcon 9 upper stage, makes the power requirements drastically lower and makes the mission doable in a single flight. 

 

Robert Clark 

Dept. of Mathematics 

Widener University 

Chester, PA 19013 

 

 

 

2.)Did SpaceX throttle down the booster engines on the IFT-2 test launch to prevent engine failures? 

 

 3.)

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Lightweight thermal protection for reentry of upper stages.

 Copyright 2025 Robert Clark   In the blog post “Reentry of orbital stages without thermal protection, Page 2”,  http://exoscientist.blogspo...