Don't all modern US silo-based missiles use solids to get round all this?
Quote from: Bob Shaw on 05/17/2019 10:48 pmDon't all modern US silo-based missiles use solids to get round all this?The US used plenty of hypergolic-engine-powered ICBM before it figured out how to do solids.
Quote from: fl1034 on 05/17/2019 10:58 pmQuote from: Bob Shaw on 05/17/2019 10:48 pmDon't all modern US silo-based missiles use solids to get round all this?The US used plenty of hypergolic-engine-powered ICBM before it figured out how to do solids.Er, yes - and they abandoned nightmare degradeable plumbing as soon as possible! How many Titan ICBMs are in service?
Quote from: Bob Shaw on 05/17/2019 11:09 pmQuote from: fl1034 on 05/17/2019 10:58 pmQuote from: Bob Shaw on 05/17/2019 10:48 pmDon't all modern US silo-based missiles use solids to get round all this?The US used plenty of hypergolic-engine-powered ICBM before it figured out how to do solids.Er, yes - and they abandoned nightmare degradeable plumbing as soon as possible! How many Titan ICBMs are in service?Then how does the RD-180 intermediate seal work? The Russians are (and have been a while) using even more insane design - an engine submerged inside out in N2O4 or UDMH in SLBMs.
However, this seems to work only on engines running on two cryo fuels. Barring an FFSC design, how then is inter-propellant seal achieved when 1.only one propellant is cryo, e.g. RD-180 which runs on kerosene/LOX and powers the Atlas V,and 2. both propellants are non-cryo, e.g. the UDMH/NTO-fueled RD-275Ms on the Proton?
Quote from: fl1034 on 05/17/2019 10:43 pm However, this seems to work only on engines running on two cryo fuels. Barring an FFSC design, how then is inter-propellant seal achieved when 1.only one propellant is cryo, e.g. RD-180 which runs on kerosene/LOX and powers the Atlas V,and 2. both propellants are non-cryo, e.g. the UDMH/NTO-fueled RD-275Ms on the Proton?The mechanism is very similar with non cryo fuels, instead of boiling though you cascade your seals so there is minimal leakage, which drops the pressure, and eventually the leak rate is countered by surface tension and the He2 purge gas. It's generally easier when its the hypergols because although its really bad if they come in contact you then don't have LOX compatibility and cryogenic thermal contraction to deal with in the design.
Then what about UDMH/NTO engines for fast reaction launches? How do they contain leakage when inactive in silos? Can the mechanical valves achieve perfect seal indefinitely when turned off or there need to be wax seals?
You hit upon the right word when you used 'insane'. Hypergolics may have a place, but so did high-test hydrogen peroxide - and that place is mostly in the past. Even the Dr Strangelove brigade realise that these things are bad news. The ex-USSR military-industrial complex are another matter and are prone to outrageous environmental acts which make solids look like health foods!