TL;DR - hot gas thrusters don't have any advantage over ullage thrusters as long as acceleration is low.
Hmm dint dude from Masten space joined SpaceX?If yes then then they got small nozzle ISP solutions at their hands already.
Quote from: BT52 on 01/09/2023 08:28 pmHmm dint dude from Masten space joined SpaceX?If yes then then they got small nozzle ISP solutions at their hands already. Unless he and SpaceX are willing to get sued by Astrobotic for theft of intellectual property, they don't.
Quote from: TheRadicalModerate on 01/09/2023 09:16 pmQuote from: BT52 on 01/09/2023 08:28 pmHmm dint dude from Masten space joined SpaceX?If yes then then they got small nozzle ISP solutions at their hands already. Unless he and SpaceX are willing to get sued by Astrobotic for theft of intellectual property, they don't.Well they cant get sueed by knowledge of building small nozzle engine. Ahh i see. I was under impression they bought also some designs with him. But i guess not.
But there's no reason to assume they'd do an long ullage burn in a stupid way for no good reason.
Quote from: Paul451 on 01/09/2023 10:43 pmBut there's no reason to assume they'd do an long ullage burn in a stupid way for no good reason.Agreed. My point was that it doesn't look like the mass of CH4 in ullage space will be adequate for the ullage impulse. (I didn't do the computation including the O2 ullage, but things were bad enough that roughly doubling the mass wouldn't be adequate either.)
Quote from: TheRadicalModerate on 01/10/2023 06:58 amQuote from: Paul451 on 01/09/2023 10:43 pmBut there's no reason to assume they'd do an long ullage burn in a stupid way for no good reason.Agreed. My point was that it doesn't look like the mass of CH4 in ullage space will be adequate for the ullage impulse. (I didn't do the computation including the O2 ullage, but things were bad enough that roughly doubling the mass wouldn't be adequate either.)If you add the O2 ullage the total available mass is a factor of 4X for mass over that of the CH4 alone.
Through improved understanding of low-g fluid behavior Centaur has reduced the standard parking orbit settling from 10-3 g to 10-4 g realizing a significant performance enhancement while maintaining adequate propellant control. In the quest for even more performance and longer mission duration, Centaur has demonstrated effective propellant control at accelerations down to 10-5 g...
Quote from: oldAtlas_Eguy on 01/10/2023 02:47 pmQuote from: TheRadicalModerate on 01/10/2023 06:58 amQuote from: Paul451 on 01/09/2023 10:43 pmBut there's no reason to assume they'd do an long ullage burn in a stupid way for no good reason.Agreed. My point was that it doesn't look like the mass of CH4 in ullage space will be adequate for the ullage impulse. (I didn't do the computation including the O2 ullage, but things were bad enough that roughly doubling the mass wouldn't be adequate either.)If you add the O2 ullage the total available mass is a factor of 4X for mass over that of the CH4 alone.But not the impulse. [Second Update: My first cut at this was completely wrong, with massive confusion of extensive and intensive properties. Just to save space (and, yeah, a little bit of embarrassment), I'm just deleting it. Here's the new version:]Since O2 has exactly double the molecular weight of CH4, O2 cold gas exit speed vs. CH4 speed should be sqrt(1/2)vch4 = 0.71 of the CH4 cold gas speed.The LOX tank should have 29% more volume than the LCH4 tank, and the same pressure. So the O2 ullage mass should be 2*1.29 = 2.6x that of the CH4 mass.Therefore, the total impulse of the LOX ullage (mo2*vo2) should be 1.8x that of the CH4 ullage, and the total impulse of both tanks is 2.8x what I calculated up-thread, which means that the acceleration should go from 57 microgee to 159 microgee. Note that I'm assuming that the cold gas thrusters can accept two different mass flows at different times during the ullage acceleration. Shouldn't be a problem.159 microgee might be close to a viable ullage acceleration, but it's still a really small acceleration. Still seems to me that cold gas ullage thrust is pretty iffy.Update #3: From the 2008 Kutter-Zegler paper on turning Centaur into a prop depot:QuoteThrough improved understanding of low-g fluid behavior Centaur has reduced the standard parking orbit settling from 10-3 g to 10-4 g realizing a significant performance enhancement while maintaining adequate propellant control. In the quest for even more performance and longer mission duration, Centaur has demonstrated effective propellant control at accelerations down to 10-5 g...Now, these numbers are for settling during storage, for the purpose of ensuring that they'd only vent gas instead of gas/liquid. I can't think of a reason why prop transfer would have different properties, as long as vibration in the system is minimal. If that's the case, then >10 microgee should be fine, and cold gas ullage acceleration will work.
Conclusion: bottom fill works best and whatever provides the transfer pressure needs to be variable.
One other problem, which is sort of related to your "don't splash" problem: Prop will "geyser" into the receiving tank, even if it's pumped from the bottom. At microgee accelerations, that geysering effect is going to cause all kinds of sloshing. That may be OK, because uncovering the pump outlet on the receiving tank shouldn't be a problem. But if you get blobs of prop bouncing off the receiving tank wallsı, they may mess up microgee ullage accelerations enough to cause sloshing on the sending side, which could uncover the inlet.
Quote from: TheRadicalModerate on 01/11/2023 10:33 pmOne other problem, which is sort of related to your "don't splash" problem: Prop will "geyser" into the receiving tank, even if it's pumped from the bottom. At microgee accelerations, that geysering effect is going to cause all kinds of sloshing. That may be OK, because uncovering the pump outlet on the receiving tank shouldn't be a problem. But if you get blobs of prop bouncing off the receiving tank wallsı, they may mess up microgee ullage accelerations enough to cause sloshing on the sending side, which could uncover the inlet.If this is the only use for the fill pipe, they can put diverter such as a mushroom cap over the outlet.
If you intend to fill a depot for a specific mission, then number of tankers is really the right metric, and overall prop efficiency isn't very important. But if you're continuously filling and partially drawing down a depot, as you would in very high cadence ops, then the efficiency becomes more important. Note also that increasing the power of the transfer pumps, and thereby shortening the transfer time, can also change things. As usual, it's a pretty rich trade space.So, to answer your question: In high cadence, there's probably a number where rotational settling makes more sense than ullage thrust. But it doesn't make any sense early on, when low cadence will almost certainly boil the depot dry between missions. And even at high cadence, you'll have to show your work on why the extra complexity is worth it.
Quote from: DanClemmensen on 01/11/2023 11:01 pmQuote from: TheRadicalModerate on 01/11/2023 10:33 pmOne other problem, which is sort of related to your "don't splash" problem: Prop will "geyser" into the receiving tank, even if it's pumped from the bottom. At microgee accelerations, that geysering effect is going to cause all kinds of sloshing. That may be OK, because uncovering the pump outlet on the receiving tank shouldn't be a problem. But if you get blobs of prop bouncing off the receiving tank wallsı, they may mess up microgee ullage accelerations enough to cause sloshing on the sending side, which could uncover the inlet.If this is the only use for the fill pipe, they can put diverter such as a mushroom cap over the outlet.At the kind of accelerations and head pressures we're talking about, even turbulence after the diversion is likely to cause some slosh. But it might be enough to prevent blobs of prop from slamming into stuff with enough force to cause slosh in the sending tank. And a mushroom cap would probably help for the "nearly full" case, too.
The tolerances would have to be pretty tight for something like this to work, but it is completely different than standard pumping in gravity or spinning ships around
Quote from: skyflyer81 on 01/12/2023 02:10 pmThe tolerances would have to be pretty tight for something like this to work, but it is completely different than standard pumping in gravity or spinning ships aroundThe image looks cool, but I can't quite make sense of it. Can you elaborate a little? :-)