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Mark:

I looked at the link.  That's the absorption-degas analog of the dry ice confined-heating self compression I had thought about.  Very clever.  I never knew adsorption had reached storage volumes that large.  That's a good technique.  Once it's near 17 psia,  then ordinary compressors could take it to 2000 psi if need be. 

The fuel-maker sounds intriguing,  too.  I've recently become a fan of methane-LOX here as a cleaner alternative to kerosene-LOX. 

These items are the sort of gear that needs to get scaled up and taken along on the first mission or two,  to get thoroughly checked-out and wrung-out of any hidden "gotchas".  After that,  it's ready for prime time,  and the very thing we need. 

You must be younger than I am,  with more recent industry experiences and connections,  to know of such things.

GW

Rune:

I've seen a lot of re-entering satellites,  and I watched Columbia re-enter in pieces,  although I didn't know it was Columbia until about 10 minutes later.  Thinking back on what I saw,  and watching the video footage others took over-and-over,  I pretty well figured out what I saw. 

The ship lost its wing to the foam impact damage at about M12 over the Texas-New Mexico border.  (It was photographed over New Mexico at M15 intact but streaming debris from an obviously-failing wing.)  It tumbled and immediately lost its other wing,  vertical fin,  and bay doors to the hypersonic wind blast. 

2-3 seconds later the windshield caved in,  ripping the top off the flight deck,  and the 4 astronauts there were ripped out from under their seat belts in pieces.  3000-5000 psf q does that.  No time to burn,  just blunt wind blast pressure forces.  Those 4 torn-apart astronauts were the body parts that rained down just east of Dallas,  a little cooked,  but not burnt. 

We knew about the vulnerability of the windscreen to direct hypersonic stream impingement when I was a grad student in 1973.  Found it in wind tunnel tests,  and found the narrow range of AOA where the stream safely jumps over the cockpit,  as a separated flow.  Lose attitude control,  you're dead. 

When it was over Dallas at about M6 or 7,  that's when I saw it from outside Waco,  Texas,  to my north about 100 miles slant range.  The heavy engine thrust structure had already separated.  It and the fuselage (cabin still attached) led the debris stream.  The wings were fluttering along behind,  along with the chunks of bay doors and the fin,  and a whole cloud of smaller pieces,  maybe 2 dozen or so.  The fuselage and thrust structure were tumbling.  I could not see them tumble,  but they were leaving characteristically-braided contrails. 

I watched it go eastward until the contrails dimmed as the hypersonics faded into "mere" supersonics.  Between Dallas and Tyler,  I saw the fuselage break up as a fan of pieces,  leaving the cabin tumbling alone and still mostly intact,  except for the lost flight deck roof.  A contact at NASA confirmed to me that the three on the mid deck were still alive at that point,  although I hope the gee-force pounding had beaten them unconscious.  That's the last I saw of it,  visually.

Seconds later the cabin decelerated to about M1/20kft,  and was crushed by the rapidly-rising wind pressures again.  My contact at NASA said that's when the 3 mid deck astronauts died by blunt force trauma,  not upon impact with the ground seconds later.  If stabilized so as not to tumble,  it would not have crushed like that. 

Clearly,  lots of the structures survived the re-entry in recognizable condition.  This includes uniform patches and plastic parts from the interior.  No,  this stuff doesn't burn up on re-entry the way all the "experts" always said it did all these years.  There isn't time to burn,  it decelerates quite rapidly.  The pieces literally heat-sink their way through reentry on a transient. 

As for crew survival,  you separate the cabin from the cargo bay with a shaped charge,  and stream an inflated drogue from the nose to take the spin off the cabin.  If there’s enough warning time,  the flight deck crew can evacuate down to the middeck.  Otherwise,  windshield failure and flight deck roof loss is very likely before the drogue can stabilize it.  As it slows to “mere” supersonic speed,  you blow the hatch.  All survivors on the mid deck have but seconds to jump before impact,  but that’s better than no chance at all. 

It was the same with Skylab in 1979.  Fragile thin-shell aluminum remained intact as one single radar return down to 40 nautical mile altitude,  about halfway through reentry (around M12,  just like Columbia).  Minutes later,  although the solar wings and telescope mount were gone,  the main body was still in one piece when it completed reentry just off the western Australian coast. 

It finally broke up over land at about M1/20kft,  while ballistically falling into rapidly rising q at low altitudes as the path angle quickly steepened downward.  Of 85-90 tons at reentry,  they picked up 75 tons of debris in Australia.  Nope,  these things most definitely do not "burn up". 

GW

Just singing like a canary,  I guess.

Do y'all really think they'll find things like platinum in ore bodies rich enough to process in these NEO's?  That's the sort of product with value down here.  The volatiles would have value in LEO,  not down here.  At least to my way of thinking. 

What about the stony minerals?  Any use for them that anyone can see?

I'm not sure about the nickel-iron.  Whether there's any value down here is questionable,  I suppose,  since we have so much recyclable steel.  But for steel construction on the moon,  Mars,  and elsewhere,  it could be quite valuable,  once there's folks there on those places who need it.  Not yet,  but "soon". 

GW

I'm thinking electric lights just because Earth plants need visible light centered at green wavelength,  plus a snit of UV,  to survive well. 

Steam is a very good way to transmit heat,  though. 

GW

Louis:

Both shuttle accidents showed pressure cabin separation from the rest of the debris (I witnessed this with my own eyes during Columbia's destruction,  right from my front yard).  Structurally,  the weak point was the cabin to cargo bay joint,  where the structure went from a closed tube to an open tube (no strength in the bay doors). 

If you take the spin off the pressure cabin (pressurized or not,  the crew should be in suits,  who cares if it is punctured in some way),  you can use the compartment between cockpit (two levels) and cargo bay as a sacrificial "heat shield",  with nothing more than a stabilizing drogue from the nose. 

Once the noisy hypersonics quiet down,  you are are low-supersonic decelerating toward M1/20kft max q,  and only dozens of seconds from impact.  You quickly blow the hatch,  and jump out on personnel chutes with an oxygen bottle.  No wings,  so we don't need the silly pole and tractor rocket motors. 

We have known since WW2 that crews were unable to bail out from spinning airplanes due to centrifugal forces.  In fact,  that problem was the original rationale behind ejection seats. 

But for a shuttle pressure cabin,  a de-spin drogue is simply more practical. 

We have also known since WW2 that bailout from a non-spinning airplane is easy.  Just don't do it above about M1 or thereabouts,  because of the nonsurvivable wind blast (known since the early 50's).  Which transonic point is some 20kft on the typical ballistic re-entry trajectory,  even for debris. 

GW

A part of what y'all are debating here (costs of ground control) is something I have written posts about before.  The result you get depends upon whether PRI uses the NASA model,  the ULA model,  or the Spacex model.  If it takes the population of a major American city to support your launches and flights,  when you add up all the contractors and vendors too,  that's the NASA model,  and it is precisely why a shuttle launch was $1.5 B.  At 25 metric tons max payload,  that's $27,000/lb. 

On the other hand,  there's Spacex,  who for the first time in history uses the population of only a small Texas country town to support launches and missions.  This is why Spacex is charging about $2500/lb for a 10.1-max metric ton payload on Falcon-9.  Factor-ten better is no mean feat!  Three cheers for visionary-led private enterprise!

There is a launch vehicle scale effect that applies here:  bigger rockets should lead to lower per-lb payload costs when delivering max payload.  Now,  ULA's Atlas V,  in the -551 and -552 configurations,  is priced at 2400/lb at a max 25 metric ton payload size.  (All of this is LEO from Canaveral.) 

But,  Falcon-Heavy is projected at 53 metric tons for $800-1000/lb on Spacex's website.  Conclusion:  ULA is too high for the payload size,  they ought to be nearer $1500-1700/lb.  Boeing and Lockheed-Martin are gigantic corporations,  while Spacex is not.  Does anybody else see the advantage of a small, lean company here?  (Or the advantage of any for-profit company over a government agency?)

If you think and act like a Spacex,  asteroid mining could actually be profitable.  If you think and act like a ULA,  maybe not.  If you think and act like NASA,  never.  That's the real lesson of what we have seen for the last 50 years or so.  It's hard to argue with numbers interpreted in the light of actual history. 

Comments?

GW

Actually,  on the buried glacier,  you start the pond construction by nothing more than pumping heat down a well drilled into the glacier.  The bulldozer is for simply smoothing and adjusting the regolith cover.  Melt out a cavity you can get into,  then "hot fire hose" it to the shape and size you want.  Add habitat with airlocks into the water and on the surface.  Rig the lights.  Add organic matter and transplanted Earth water plants.  Voila:  operating farmland on Mars. 

GW

Well,  passenger safety with a launch rocket such as Falcon-9 or Falcon-Heavy depends upon a good escape system.  I think Spacex's use of the capsule itself fully powered as the escape vehicle,  is a better idea than the old escape tower we used on Mercury and Apollo.  You have coverage from ignition all the way to orbit.  The tower didn't work after jettison. 

With an airliner-like vehicle (such as Skylon),  you have to make the craft "utterly reliable" so that no escape system is needed (sounds hauntingly familiar,  like "make the ship unsinkable",  right?  Well,  that's exactly what you have to do). 

That's what we tried to do with shuttle,  and failed.  A fragile heatshield,  exposed to debris impact in a side-mounted cluster,  is two strikes against you right there.  Add foam insulation that peels off,  and you kill a crew.  We did. 

That's why Skylon is proposed as an unmanned cargo vehicle.  Flying it like that for a while will uncover all the "gotchas",  which can be fixed in a follow-on design that could be manned.  That's actually the smart way to do it.  Because of its unique engines,  Skylon is really a feasibility demonstration vehicle.  Until we've flown it for a while. 

Any high-energy vehicle,  be it a vertical launch rocket or some kind of spaceplane,  will be risky.  That is just plain unavoidable.  But it can be managed and designed-for.

Feasibility of spaceflight itself is no longer in doubt.  For passenger service,  we need to get the safety-of-flight engineers in on the ground floor of all vehicle designs from now on.  After 50+ years,  we're finally doing that.  They did it at Spacex,  and I'm proud of them for it. 

Actually,  there was a way to have saved both shuttle crews,  and it was not what they implemented.  My idea was hindsight-only for Challenger,  but afterward it was never done,  which is why Columbia's crew died.  I couldn't get NASA to listen to me.  Outsider,  "not invented here",  and all that jazz.  But to this day I still show spaceflight crew escape concepts on my resume as something I consult in. 

GW

Please don't misunderstand ... I'm not against ISRU on the first mission.  I'm against betting lives on unproven equipment needlessly.

Nothing never-before-done-in-situ can be considered proven.  We can't really do "real ISRU" till we land on Mars.  Simulations can be quite good sometimes,  but it just ain't the real thing.  Because our estimates of site conditions are only estimates. 

It is essential to thoroughly try out everything we can dream up for ISRU from mission-1 on.  I just don't think it'll work as good as folks wish.  More than 50% of our early rocket shots in the 50's were failures.  This is no different:  it takes real trials to find and fix all the "gotchas",  and believe me,  there will be "gotchas". 

I do have some qualms about using a nearly-pure CO2 atmosphere to make stuff like fuel.  The density is so low.  And how do you compress in any practical equipment from 7 mbar to 10,000 mbar or more?  We have never built compressors like that before,  recip or turbine,  other than near-zero throughput lab devices.  Not very many of them,  either. 

One "out" for compression might be to refrigerate a large volume of atmospheric CO2 to solidify it,  pack it into a much smaller volume sealed container with no free volume,  then re-heat it.  Re-gasification confined like that is automatic compression of the product gas.  Energetically,  that's not a very efficient process because of the refrigeration,  but it might be more practical to do.  I just don't know. 

We might be better off just mining solid dry ice near the poles,  and doing confined-heating compression that way to get CO2 gas bottled at pressures we can really use.  But that's not viable ISRU unless you land near one of the poles.  See what I mean? 

GW

Well,  you try to rig the rocket so that if one engine explodes,  the rest don't.  That's the kind of suspenders-and-belt (and armored codpiece!!) design that is needed to take on the challenge of a Mars mission. 

GW

There's already a light gas gun launching small (around 5 pound) payloads at M17 for USAF for hire.  It's a private venture.  I saw their paper at the 14th annual Mars Society convention in Dallas last summer,  same advanced technology session as my Mars mission design paper. 

Bigger diameter,  higher launch angle (more than anything else),  a bit more fuel-oxidizer combustion power,  and you reach orbital altitudes at almost-orbital speed.  From there it's a very small rocket burn to circularize in LEO.  Almost nothing but an old standard Mark 25 solid JATO motor,  for a pretty substantial payload (hundreds to thousands of pounds).  I don't remember the specific numbers,  but it looked pretty good to me.  Perfect for refueling an already-existing vehicle,  especially if what you shoot up there is water,  as tougher-than-an-old-boot ice.  The real problem is launch gees.  Thousands of them.  Just like an artillery shell.  Something we already know know to handle,  just not with fragile stuff.  Gun launch cost looked like about $100-200/pound,  compared to Falcon-Heavy at $800-1000/pound. 

As for ISRU on the first mission or two to Mars,  by all means send such gear for trials,  but absolutely don't count on it working right!  Chances are,  it will not work right,  perhaps not at all,  especially on the first mission.  Probably not even the second.

Accordingly,  it would be entirely stupid to count on ISRU for crew survival and return on the first mission.  Nothing is more expensive than a dead crew.  Ask NASA.  They've seen it 3 times now (Apollo-1,  Challenger,  and Columbia).  Nearly saw it on Gemini-8,  Gemini-7,  and Apollo-13. 

It takes on the average 1.5 to 2 full scale,  all-up trials of new equipment before it comes close to working "right",  and that's with some very talented,  artful people working the problem.  That's nearly 20 years' aerospace engineering experience talking.  Rocket science ain't science,  it's about 50% art never written down.  It's about 40% science actually written down somewhere.  And,  it's about 10% blind dumb luck,  and you have to plan for that. 

It's no different in any of the other disciplines,  either.  That's why the non-flight engineering disciplines use such whopping huge safety factors.  Those of us designing things that fly could not afford that luxury.  Fundamentally,  that's why flying things are more expensive. 

GW

Louis:

No,  the real problem is one of making heat transfer occur as fast as the other propulsion processes,  when it truly and fundamentally does not want to be that fast.  Skylon's engine is basically a liquid air cycle engine.  No one else has ever made liquid air that fast,  ever.  But,  Reaction Engines just might.  I'm rootin' for 'em. 

GW

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