Its like its 1916 and you are building something called an aircraft carrier. It will not be an very good one but it was unlikely to get into carrier vs carriers fights.
Quote from: Greg Hullender on 10/26/2024 07:59 pmQuote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Gee, it's only 131 pages over the past five years--read faster! :-)Seriously, the things that soured me on all rotational approaches in the foreseeable future were:a) You only need maybe 50 micro-g of acceleration to settle the tanks, so even a very long ullage burn (e.g. hours) won't waste very much fuel.b) Cryogenic plumbing is the very devil to make work, so anything that needs <i>new</i> plumbing is probably off the table for a long time. Any practical system needs to work with Starships more-or-less as they are today--no new pipes and/or outlets. You <i>definitely</i> want to avoid anything that would add extra mass to each and every tanker Starship--adding mass just to the depot is probably okay.c) No one has even tried to make a rotating system work in space, much less one that would potentially involve huge changes in moment of inertia from docking, fuel transfer, and sloshing. You could imagine it taking many years to get the kinks worked out.The ullage-burn approach is so easy and so cheap it's just impossible to beat. Or so it seems, anyway. We'll know more when they start actually trying to do it.This, and as its just over pressure in tanker pushing liquid gas so gas voids is not an issue, just pump gas back to tanker. Most of ullage is probably boil off anyway and you can simply burn some methane and oxygen gas for more trust once you nailed it. Not needed for the prototype version however, none has done this before. Its like its 1916 and you are building something called an aircraft carrier. It will not be an very good one but it was unlikely to get into carrier vs carriers fights.
Quote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Gee, it's only 131 pages over the past five years--read faster! :-)Seriously, the things that soured me on all rotational approaches in the foreseeable future were:a) You only need maybe 50 micro-g of acceleration to settle the tanks, so even a very long ullage burn (e.g. hours) won't waste very much fuel.b) Cryogenic plumbing is the very devil to make work, so anything that needs <i>new</i> plumbing is probably off the table for a long time. Any practical system needs to work with Starships more-or-less as they are today--no new pipes and/or outlets. You <i>definitely</i> want to avoid anything that would add extra mass to each and every tanker Starship--adding mass just to the depot is probably okay.c) No one has even tried to make a rotating system work in space, much less one that would potentially involve huge changes in moment of inertia from docking, fuel transfer, and sloshing. You could imagine it taking many years to get the kinks worked out.The ullage-burn approach is so easy and so cheap it's just impossible to beat. Or so it seems, anyway. We'll know more when they start actually trying to do it.
I have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.
Quote from: magnemoe on 10/26/2024 08:34 pmQuote from: Greg Hullender on 10/26/2024 07:59 pmQuote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Gee, it's only 131 pages over the past five years--read faster! :-)Seriously, the things that soured me on all rotational approaches in the foreseeable future were:a) You only need maybe 50 micro-g of acceleration to settle the tanks, so even a very long ullage burn (e.g. hours) won't waste very much fuel.b) Cryogenic plumbing is the very devil to make work, so anything that needs <i>new</i> plumbing is probably off the table for a long time. Any practical system needs to work with Starships more-or-less as they are today--no new pipes and/or outlets. You <i>definitely</i> want to avoid anything that would add extra mass to each and every tanker Starship--adding mass just to the depot is probably okay.c) No one has even tried to make a rotating system work in space, much less one that would potentially involve huge changes in moment of inertia from docking, fuel transfer, and sloshing. You could imagine it taking many years to get the kinks worked out.The ullage-burn approach is so easy and so cheap it's just impossible to beat. Or so it seems, anyway. We'll know more when they start actually trying to do it.This, and as its just over pressure in tanker pushing liquid gas so gas voids is not an issue, just pump gas back to tanker. Most of ullage is probably boil off anyway and you can simply burn some methane and oxygen gas for more trust once you nailed it. Not needed for the prototype version however, none has done this before. Its like its 1916 and you are building something called an aircraft carrier. It will not be an very good one but it was unlikely to get into carrier vs carriers fights.I'm with you on all this, and I'll reemphasize the topic of docking.We're not used to docking spacecraft where over half the mass is loose in the tanks. That's not slosh, that's a couple of independent tsunamis in there.The only predictable way to do this is get the ships on your fractional-g recipe ahead of time, never going into drift. Align courses, and dock sideways, without ever dropping the acceleration. And at that point, start moving fuel until done.So the entire operation from before docking to after separation, is under this slight baseline acceleration (and the docking accelerations are lower)Otherwise the effects of 100 ton propellant blobs hitting the sidewalls at random delays, off center, will be insane.
Ive got a rich suite of background processes working on orbital refueling and two concerns have popped out of the que. The current discussion on propellant temperature needs is one. QD sealing is another.Cryogenic seals are a tough problem. Adding in multiple sealing cycles can only make it tougher. Our discussion has focused on using either the current QD layout or something similar. This puts the oxidizer and fuel seals in close proximity. If both start leaking liquid, local conditions determine the possibility of vaporization. If vapor is present only the lack of an ignition source prevents ignition.I suspect the current state of material science is inadequate for perfecting the seals. I will gladly defer to wiser minds on this.AIUI, the flow of the propellants themselves will build up triboelectric potential differences. This isn't insurmountable but it has to be dealt with. Up until now I've been a strong advocate of working with current QD layout but I'm having second thoughts. Might it be best to keep the LOX connection where it is and having a second QD plate up by the methane tank? This would keep leakage separated and make an ignition source a non problem. It's a PITA but so is unintended consequences. Could this arrangement be worked to ease some of the temperature concerns?Or am I just pissing in a tea pot and creating a tempest? (Did I get that right? )
Quote from: Twark_Main on 10/24/2024 07:28 amQuote from: Greg Hullender on 10/23/2024 11:21 pmThat is, it looked as though an HLS fully refueled in LEO, sent to Gateway and then down to the moon would be unable to return to Gateway even with zero payload.I thought the consensus was that such a mission plan would require fully fueling in HEEO, not LEO.I thought that was just with the V1 Starship. I still have your "spreadsheet of doom," by the way; I just don't have the numbers to put into it.
Quote from: Greg Hullender on 10/23/2024 11:21 pmThat is, it looked as though an HLS fully refueled in LEO, sent to Gateway and then down to the moon would be unable to return to Gateway even with zero payload.I thought the consensus was that such a mission plan would require fully fueling in HEEO, not LEO.
That is, it looked as though an HLS fully refueled in LEO, sent to Gateway and then down to the moon would be unable to return to Gateway even with zero payload.
Quote from: Herbie on 10/25/2024 07:45 pmQuote from: eriblo on 10/25/2024 04:24 pmQuote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Depots and propellant supply ships would both have internal ribcage-like manifold in each tank. Outbound ships would not need the manifold.Ships dock back-to-back. Flywheel on both ships, spin axis parallel to the long axis of each ship, spin up, imparting a very slow spin to the joined ships, settling propellant along the belly of each ship.Increase supply-side tank pressure above that of other vessel, and open valves. Slow rotation keeps pressure head of the fluids low, so tank pressure should dominate. Propellant enters manifold on the supply vessel from ventral side, and leave from the dorsal side on the receiving ship. Center of mass, rotational axis, and moment of inertia will all shift during transfer, but perhaps flywheels can compensate.After transfer, flywheels cancel out spin of the vessels, and vessels unlock.It may be possible to so something similar using only thrusters instead of flywheels.Interesting concept, the problem is that any axis not aligned with the maximum moment of inertia is unstable. The two ships will start tumbling until they are rotating in the only stable configuration which should be around an axis perpendicular to the symmetry plane going through both ships long axis (and that plane will want to be parallell to the orbital plane).That configuration might work with your suggestion instead as most of the propellant would pool on the dorsal top and bottom corners of their respective tanks.I was wondering about the rotational stability, but the tennis racket theorem suggests that rotation is stable about the principal axis associated with the minimum moment of inertia. Of course, that result assumes fixed moments of inertia, which wouldnot apply given the dynamic nature of the mass distribution in the system.Indeed, it does specifically not hold for any object that is able to dissipate some rotational energy, the classic example of which is tanks with mixed fluids in them. This experiment can be done at home (perhaps outside) with a half full water bottle.
Quote from: eriblo on 10/25/2024 04:24 pmQuote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Depots and propellant supply ships would both have internal ribcage-like manifold in each tank. Outbound ships would not need the manifold.Ships dock back-to-back. Flywheel on both ships, spin axis parallel to the long axis of each ship, spin up, imparting a very slow spin to the joined ships, settling propellant along the belly of each ship.Increase supply-side tank pressure above that of other vessel, and open valves. Slow rotation keeps pressure head of the fluids low, so tank pressure should dominate. Propellant enters manifold on the supply vessel from ventral side, and leave from the dorsal side on the receiving ship. Center of mass, rotational axis, and moment of inertia will all shift during transfer, but perhaps flywheels can compensate.After transfer, flywheels cancel out spin of the vessels, and vessels unlock.It may be possible to so something similar using only thrusters instead of flywheels.Interesting concept, the problem is that any axis not aligned with the maximum moment of inertia is unstable. The two ships will start tumbling until they are rotating in the only stable configuration which should be around an axis perpendicular to the symmetry plane going through both ships long axis (and that plane will want to be parallell to the orbital plane).That configuration might work with your suggestion instead as most of the propellant would pool on the dorsal top and bottom corners of their respective tanks.I was wondering about the rotational stability, but the tennis racket theorem suggests that rotation is stable about the principal axis associated with the minimum moment of inertia. Of course, that result assumes fixed moments of inertia, which wouldnot apply given the dynamic nature of the mass distribution in the system.
Quote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Depots and propellant supply ships would both have internal ribcage-like manifold in each tank. Outbound ships would not need the manifold.Ships dock back-to-back. Flywheel on both ships, spin axis parallel to the long axis of each ship, spin up, imparting a very slow spin to the joined ships, settling propellant along the belly of each ship.Increase supply-side tank pressure above that of other vessel, and open valves. Slow rotation keeps pressure head of the fluids low, so tank pressure should dominate. Propellant enters manifold on the supply vessel from ventral side, and leave from the dorsal side on the receiving ship. Center of mass, rotational axis, and moment of inertia will all shift during transfer, but perhaps flywheels can compensate.After transfer, flywheels cancel out spin of the vessels, and vessels unlock.It may be possible to so something similar using only thrusters instead of flywheels.Interesting concept, the problem is that any axis not aligned with the maximum moment of inertia is unstable. The two ships will start tumbling until they are rotating in the only stable configuration which should be around an axis perpendicular to the symmetry plane going through both ships long axis (and that plane will want to be parallell to the orbital plane).That configuration might work with your suggestion instead as most of the propellant would pool on the dorsal top and bottom corners of their respective tanks.
I have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Depots and propellant supply ships would both have internal ribcage-like manifold in each tank. Outbound ships would not need the manifold.Ships dock back-to-back. Flywheel on both ships, spin axis parallel to the long axis of each ship, spin up, imparting a very slow spin to the joined ships, settling propellant along the belly of each ship.Increase supply-side tank pressure above that of other vessel, and open valves. Slow rotation keeps pressure head of the fluids low, so tank pressure should dominate. Propellant enters manifold on the supply vessel from ventral side, and leave from the dorsal side on the receiving ship. Center of mass, rotational axis, and moment of inertia will all shift during transfer, but perhaps flywheels can compensate.After transfer, flywheels cancel out spin of the vessels, and vessels unlock.It may be possible to so something similar using only thrusters instead of flywheels.
Quote from: meekGee on 10/26/2024 08:56 pmQuote from: magnemoe on 10/26/2024 08:34 pmQuote from: Greg Hullender on 10/26/2024 07:59 pmQuote from: Herbie on 10/25/2024 03:34 pmI have been following this thread for a while, but have not seen this refueling method discussed. I apologize if I missed the discussion.Gee, it's only 131 pages over the past five years--read faster! :-)Seriously, the things that soured me on all rotational approaches in the foreseeable future were:a) You only need maybe 50 micro-g of acceleration to settle the tanks, so even a very long ullage burn (e.g. hours) won't waste very much fuel.b) Cryogenic plumbing is the very devil to make work, so anything that needs <i>new</i> plumbing is probably off the table for a long time. Any practical system needs to work with Starships more-or-less as they are today--no new pipes and/or outlets. You <i>definitely</i> want to avoid anything that would add extra mass to each and every tanker Starship--adding mass just to the depot is probably okay.c) No one has even tried to make a rotating system work in space, much less one that would potentially involve huge changes in moment of inertia from docking, fuel transfer, and sloshing. You could imagine it taking many years to get the kinks worked out.The ullage-burn approach is so easy and so cheap it's just impossible to beat. Or so it seems, anyway. We'll know more when they start actually trying to do it.This, and as its just over pressure in tanker pushing liquid gas so gas voids is not an issue, just pump gas back to tanker. Most of ullage is probably boil off anyway and you can simply burn some methane and oxygen gas for more trust once you nailed it. Not needed for the prototype version however, none has done this before. Its like its 1916 and you are building something called an aircraft carrier. It will not be an very good one but it was unlikely to get into carrier vs carriers fights.I'm with you on all this, and I'll reemphasize the topic of docking.We're not used to docking spacecraft where over half the mass is loose in the tanks. That's not slosh, that's a couple of independent tsunamis in there.The only predictable way to do this is get the ships on your fractional-g recipe ahead of time, never going into drift. Align courses, and dock sideways, without ever dropping the acceleration. And at that point, start moving fuel until done.So the entire operation from before docking to after separation, is under this slight baseline acceleration (and the docking accelerations are lower)Otherwise the effects of 100 ton propellant blobs hitting the sidewalls at random delays, off center, will be insane.What if they use the slosh to move the propellant?
begin the ship-to-ship prop transfer campaign by March 2025
Quote from: StevenOBrien on 10/31/2024 10:38 pmbegin the ship-to-ship prop transfer campaign by March 2025Does "begin the campaign" mean flights, or just starting construction of ships with docking hardware?I don't think it can mean flights, unless that hardware is already around somewhere waiting to go on S34, at least the passive side.
Quote from: Brigantine on 11/01/2024 01:44 amQuote from: StevenOBrien on 10/31/2024 10:38 pmbegin the ship-to-ship prop transfer campaign by March 2025Does "begin the campaign" mean flights, or just starting construction of ships with docking hardware?I don't think it can mean flights, unless that hardware is already around somewhere waiting to go on S34, at least the passive side.These are program managers. It probably is the starting mark for "moar meetings"
Quote from: InterestedEngineer on 11/01/2024 02:38 pmQuote from: Brigantine on 11/01/2024 01:44 amQuote from: StevenOBrien on 10/31/2024 10:38 pmbegin the ship-to-ship prop transfer campaign by March 2025Does "begin the campaign" mean flights, or just starting construction of ships with docking hardware?I don't think it can mean flights, unless that hardware is already around somewhere waiting to go on S34, at least the passive side.These are program managers. It probably is the starting mark for "moar meetings"You're confusing SpaceX for Boeing. "Begin the campaign" means flights. There will no doubt be some delays, but they mean flights.
Quote from: Twark_Main on 11/01/2024 03:47 pmQuote from: InterestedEngineer on 11/01/2024 02:38 pmQuote from: Brigantine on 11/01/2024 01:44 amQuote from: StevenOBrien on 10/31/2024 10:38 pmbegin the ship-to-ship prop transfer campaign by March 2025Does "begin the campaign" mean flights, or just starting construction of ships with docking hardware?I don't think it can mean flights, unless that hardware is already around somewhere waiting to go on S34, at least the passive side.These are program managers. It probably is the starting mark for "moar meetings"You're confusing SpaceX for Boeing. "Begin the campaign" means flights. There will no doubt be some delays, but they mean flights.It was a NASA project manager speaking. They'll have lots of meetings. SpaceX probably has someone whose job it is to make the PMs happy, but has no authority inside SpaceX.At least, that's how I'd run it.
Ive been noodling all the refueling schemes and one point keeps popping up. All depots have a lot of engine dry mass they don't need. It's based on StarShip and it launches like StarShip. Starship has 6 or nine engines so the depot has 6/9 engines.
In no particular orderAtlas demonstrated disconnecting engines in-flight.Why should we expect connecting engines will be easier than disconnecting them?Why separate engines and tankage vs using on-orbit refilling?