The RS-58 is a 'dead engine walking'. When Delta IV-Heavy goes, so will the engine. It's unlikely to be used on another booster ever again. Yes, it's relatively cheap, yes it's relatively powerful for a LH2 fueled engine. But it can't be air-started and it weighs more than 14,000 pounds (6.3 metric tons) so it would make a lousy upper stage engine. It weighs so much because of it's huge ablative nozzle.The only real use I could see for it again would be if funding were allocated to turn that nozzle into a regeneratively cooled one like the Shuttle/SLS's RS-25 engines. The specific impulse would increase and there would be no problem clustering them closely together as was first proposed in Constellation. The Isp increase on a big thrusting engine like RS-68 would give the SLS Corestage a modest payload increase to orbit. Five, maybe 7 metric tons.But such an upgrade to RS-68 would not come cheap and the SLS would not have a high enough flight rate to justify the multi-billion dollar upgrade so...
This would actually make the first stage much lighter than hydrocarbon riding rockets.
So you are saying that if you use a different cycle, with 80s technology, for a different use, for a not needed requirement, hitting never achieved specs on an hydrolox engine, and without doing the numbers, you wish it to be amazing?
Quote from: Aeneas on 06/02/2020 10:25 pmThis would actually make the first stage much lighter than hydrocarbon riding rockets....and why does this matter? Kerosene isn't exactly expensive, methane is even cheaper and, combined with lox (also very low cost), either would comprise the vast majority of the stage's mass.You're effectively suggesting a very expensive redesign, to end up producing expensive* engines, just so you could save the cost of a bunch of cheap fuel and maybe a barrel section or two of tankage?*When your competition is mass producing hydrocarbon engines for well under $1M (and has a target under $250K for its twice-as-powerful replacement), any hydrolox engine is more than likely going to be expensive.**$14M for an RS-68, you say? Consider that if Raptor only gets down to $500K, you could outfit a Superheavy with engines for about the same cost as powering a Delta IV Medium. If Raptors were $1M each, then a Superheavy would still cost less to power than a Delta IV Heavy.While the disadvantage of an expensive first stage might be mitigated via reusability, that just ends up driving the cost per flight down to the cost of your propellant, and LH2 would remain expensive (and a pain to work with). And you'll less easily be able to expend an expensive booster stage if you happen to need more performance on a given mission.Overall, I'd say admiring the RS-68 (and, even more so, the RS-25) is like admiring a fine Maserati, with its wonderful craftsmanship and marvelous engineering. Except if you just care about getting the job done, then a basic Ford F-150 pickup truck will do just as well. And if we want to truly expand into space, a hundred F-150 equivalents will serve us a hell of a lot better than a few showpieces, no matter how pretty and fast the showpieces might be.So, no, there's nothing shameful about the RS-68 -- it just belongs in the past. The world has moved on, and before any redesign of old technology is warranted, there needs to be sufficient justification of the result against the current state-of-the-art -- and not in terms of ISP, but rather in terms of cost effectiveness.** And if you really want to stick with hydrolox, I'd ignore the RS-68 and take a closer look at the LE-9. If JAXA and Mitsubishi can hit the H3's price targets, then its a hydrolox booster engine that might actually be cost effective, at least vis-a-vis the Merlin (absent F9 reusability, at any rate).
Quote from: MATTBLAK on 06/01/2020 09:51 amThe RS-58 is a 'dead engine walking'. When Delta IV-Heavy goes, so will the engine. It's unlikely to be used on another booster ever again. Yes, it's relatively cheap, yes it's relatively powerful for a LH2 fueled engine. But it can't be air-started and it weighs more than 14,000 pounds (6.3 metric tons) so it would make a lousy upper stage engine. It weighs so much because of it's huge ablative nozzle.The only real use I could see for it again would be if funding were allocated to turn that nozzle into a regeneratively cooled one like the Shuttle/SLS's RS-25 engines. The specific impulse would increase and there would be no problem clustering them closely together as was first proposed in Constellation. The Isp increase on a big thrusting engine like RS-68 would give the SLS Corestage a modest payload increase to orbit. Five, maybe 7 metric tons.But such an upgrade to RS-68 would not come cheap and the SLS would not have a high enough flight rate to justify the multi-billion dollar upgrade so...True, true... But maybe it should not go through a re-design but new approach using Hydrolox for the 1. stage. RS-68 has about 120ish bar. Apparently there are alloys allowing for more than doubling this value. Going beyond 250 bar would drastically reduce size, probably increasing the TWR and adding FFSC probably would add some amazing SL Isp. I played around with RPA and adjusting SSME to 262 bar chamber pressure and an expansion ratio of ~35, it'll generate >404 s of SL Isp, going >430 s in vacuum. This would actually make the first stage much lighter than hydrocarbon riding rockets.
Quote from: Aeneas on 06/02/2020 10:25 pmQuote from: MATTBLAK on 06/01/2020 09:51 amThe RS-58 is a 'dead engine walking'. When Delta IV-Heavy goes, so will the engine. It's unlikely to be used on another booster ever again. Yes, it's relatively cheap, yes it's relatively powerful for a LH2 fueled engine. But it can't be air-started and it weighs more than 14,000 pounds (6.3 metric tons) so it would make a lousy upper stage engine. It weighs so much because of it's huge ablative nozzle.The only real use I could see for it again would be if funding were allocated to turn that nozzle into a regeneratively cooled one like the Shuttle/SLS's RS-25 engines. The specific impulse would increase and there would be no problem clustering them closely together as was first proposed in Constellation. The Isp increase on a big thrusting engine like RS-68 would give the SLS Corestage a modest payload increase to orbit. Five, maybe 7 metric tons.But such an upgrade to RS-68 would not come cheap and the SLS would not have a high enough flight rate to justify the multi-billion dollar upgrade so...True, true... But maybe it should not go through a re-design but new approach using Hydrolox for the 1. stage. RS-68 has about 120ish bar. Apparently there are alloys allowing for more than doubling this value. Going beyond 250 bar would drastically reduce size, probably increasing the TWR and adding FFSC probably would add some amazing SL Isp. I played around with RPA and adjusting SSME to 262 bar chamber pressure and an expansion ratio of ~35, it'll generate >404 s of SL Isp, going >430 s in vacuum. This would actually make the first stage much lighter than hydrocarbon riding rockets.SSME is 4 or 5 times as expensive, mostly because of the complexity required to get that high pressure. For a vertically launched main stage, it's more cost-effective to use hydrocarbons and pursue better mass fractions than to use hydrolox and chase ISP, because there is effectively no limit on liftoff mass. The only place I can see LH2 main stages being optimal is for a horizontally launched or air-dropped stage, where gross liftoff mass is a hard constraint.
[...]Is Delta-IV H the only launcher with a pure HydroLOx booster/first stage?
Quote from: Hog on 06/03/2020 03:51 pm[...]Is Delta-IV H the only launcher with a pure HydroLOx booster/first stage?Only one I can think of. And personally think that's a good thing.
Is someone out there actually ashamed for the RS-68? TWR of ~ 50vacuum Isp of ~412 sand still ~ 14 m USD?
Quote from: Aeneas on 06/01/2020 09:05 amIs someone out there actually ashamed for the RS-68? TWR of ~ 50vacuum Isp of ~412 sand still ~ 14 m USD?Ashamed? Not in the least. Just three of these are needed to lift what is still the heaviest-hauling operational launch vehicle, carrying important DoD payloads. The world's most powerful LH2/LOX engine. Lots of thrust and decent ISP given the simple, reliable gas generator cycle. No solids or kerosene to stain the atmosphere on ascent. No failures in flight. Good luck to those planning on replacing Delta 4 Heavy during NSSL. It won't be trivial. - Ed Kyle
The Isp isn't decent, it's rather poor compared to RS-25.
$14 million? Try $60 million. You're repeating stuff they were saying about the engine before it got into operation which they quickly found out they could not do; it's like asking why the space shuttle got retired when it could fly weekly.
Delta IV is already replaceable by Falcon Heavy, isn't it?
Quote from: Aeneas on 06/04/2020 10:02 amDelta IV is already replaceable by Falcon Heavy, isn't it?It could be in theory, but not the way that SpaceX has flown it so far. Delta 4 Heavy can lift almost 14 tonnes to GTO. Falcon Heavy with recovery of all three boosters as flown to date can lift 8 tonnes.
Falcon Heavy could beat Delta 4 Heavy payload to GTO only by expending the center core, I think.