Now that a Falcon 9 first stage has successfully landed after a launch mission, I want to know how the first stage can avoid burning up when coming back down to earth.

There doesn't appear to be any heat shield on the bottom of the rocket, and I assume the first stage would be well above the atmosphere, meaning that it would have to re-enter.

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    $\begingroup$ I also noticed during the latest decent video, that the first stage engines were firing in pairs at a very low thrust for about 5 seconds per cycle, then switching to another pair. This is most likely to assist in shielding the vehicle using the exhaust gases during the most critical part of re-entry. $\endgroup$
    – svrima
    May 1 '17 at 19:43
  • $\begingroup$ @svrima I am quite sure they do not switch the engine pairs.. only 3 engines are restartable. $\endgroup$
    – jkavalik
    Feb 15 '18 at 13:39

The heat of re-entry is highly dependent on speed. The second stage of the rocket is responsible for providing most of the speed needed for orbit, after the first stage lifts it out of dense atmosphere.

Falcon 9 separates its first and second stages at relatively low speed, so its reentry starts off drastically slower than a reentry from orbit -- about 1650 m/s for the return-to-launch-site flight in December 2015, compared to orbital speed of 7700 m/s. Stage separation can be quite a bit faster in their downrange, barge landing flights, but the first stage is still moving much slower than orbital velocity.

That's still up around Mach 5 or 6, though, which produces a lot of heat. So the rocket fires three of its engines to slow down further before entering the thicker part of the atmosphere. The exhaust plume from that burn, as well, forces the atmospheric compression that creates reentry heat to occur well away from the rocket.

The end result is that the heat load is light enough that the body of the rocket can survive it.

There's a protective shell on the underside of the rocket, rather than a heavyweight ablative heat shield. The engine bells themselves are bearing the brunt of what reentry heat there is, and they are obviously able to cope with very high temperatures.

  • $\begingroup$ Has SpaceX released any explanation/data on the first stage return? $\endgroup$ Feb 5 '16 at 18:40
  • $\begingroup$ What do you mean particularly? They've given out a lot of information. $\endgroup$ Feb 5 '16 at 18:40
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    $\begingroup$ Confimred! Physicist Mark Adler stated that the original first stage(s) DID burn up, at which point SpaceX added the refiring of the main engines to slow the rocket down enough to avaoid burning up. quora.com/… $\endgroup$ Feb 5 '16 at 18:57
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    $\begingroup$ Aerodynamic heating is related to the speed cubed! $\endgroup$ Feb 6 '16 at 0:42
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    $\begingroup$ That's right @BrianLynch! I always forget - the drag force is speed squared, but work is force times distance, so power is force times speed, or speed cubed. $\endgroup$
    – uhoh
    Feb 6 '16 at 1:52

Here's an image of the bottom of the stage before launch.

F9 first stage

As you can see, the entire bottom is covered in white panels. I suspect those panels are a heat shield.

This SpaceX press release on the introduction of the Falcon 9 v1.1 refers to a heat shield. The reference is a bit oblique, but I think this refers to the first stage.

Here's the same area after a successful landing:

after landing

The panels are now charred black, but are still intact.

Here's an infrared video that shows the rocket gets pretty hot - at one point it glows red-hot, and that's before the engines are started for the reentry burn.

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    $\begingroup$ WOW! These photos add a lot of perspective of just what the bottom of the rock goes through. Thanks for the addition! $\endgroup$ Feb 5 '16 at 19:03
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    $\begingroup$ Hobbes, you may be overstating your case a bit about the panels not needing to be there for ascent. As you can see in this image nasa.gov/sites/default/files/images/… STS had a lot of heat shielding there as well. There is a tremendous amount of exhaust recirculation on the blunt aft ends of these launch vehicles when they get into the thin atmosphere. Also see how burnt the aft end of the ET got. upload.wikimedia.org/wikipedia/commons/2/22/External_Tank.jpg None of this insulation was for entry. $\endgroup$ Feb 5 '16 at 19:51
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    $\begingroup$ @Hobbes I've now looked at the scale with a better pair of glasses, the regular numbers are constantly changing, still a puzzle to me. I agree its of value, its just the creators haven't passed on as much as they could to us. To me, an IR camera can only measure thermal power. One would have to calibrate for emissivity (maybe = 1.0, though its not obvious that bare metal = soot = plume in that regard) and also absorption to the distant camera. All this is a distraction though: its "glowing" after MECO, during its manoeuvre to get out of the 2nd stage plume and afterwards. $\endgroup$
    – Puffin
    Feb 5 '16 at 21:01
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    $\begingroup$ @Puffin in this screen shot of the beginning of this video it's stated "color scale: MWIR sensor counts". Counts refers to ADC counts (search here for the word "count") or read the answers to this question. Converting a MWIR signal to absolute temperature reliably would be more than a little tricky. $\endgroup$
    – uhoh
    Feb 6 '16 at 1:22
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    $\begingroup$ "Charred black" - couldn't this just be the same soot buildup we saw on the sides of the landed stage? $\endgroup$ Feb 6 '16 at 7:32

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