The first line of the first link says:" The combustion chamber is nominally 2,500 psi,"
There are mentions of higher pressures further down, but that just leads to the question of which is correct.
Chamber pressure isn't nearly as important as other metrics: thrust and Isp.
The link claims an Isp of 300 s
Raptor expects to reach 380 s in vacuum once they build a vacuum nozzle. Of course fuel plays into this with propane being an unusual choice.
I can't find any clear explanation on the site about how the fuel and oxidizer are supposed to be pumped.
So let me see if I understand this correctly.This is a 20 year old patent that's just about expired for this concept
that presumably has never been built before.
Once I'd realized the exhaust nozzles are at the top of the drawing I think I've got it.
This is basically a staged combustion cycle without the staging. IOW there is no preburner (or no after burner if you follow Russian terminology and your PoV).
But the drive turbine is also acting as the pump impeller.
So you've got multiple fluid connections
and multiple bearings inside the main combustion chamber.
While these are conceptually simple their implementation in this environment is going to be challenging. Likewise the extreme thermal environment using a single rigid drive shaft/fluid connector guarantees lots of interesting design problems.
Personally I'm not that impressed by high chamber pressures, although they look great on study contract proposals.
It looks like it could give better T/W than even an SC engine but there's lots of engineering in there and stuff working ways that are pretty far outside the known range.
Gas dynamics inside a conventional thrust chamber is fairly complex, but this has the injection system at right angles to the flow direction you want to ultimately achieve.
If the material properties of Aluminum alloys are as good as you think building a low(ish) pressure version of the design should present few problems. That would put many of the doubts about its complexity to rest.
Quote from: meberbs on 02/20/2019 01:56 amThe first line of the first link says:" The combustion chamber is nominally 2,500 psi,"That is for the first of two proposed prototypes. The first is 2000lbf thrust and runs a very conservative set of parameters in order to avoid catastrophic failure given the crude numeric modeling.
Even so, it is still running very rich, so as to assure adequate cooling flow.
Quote from: meberbs on 02/20/2019 01:56 amChamber pressure isn't nearly as important as other metrics: thrust and Isp. The thrust scales favorably.
Much above 300 bar main chamber pressure means extreme oxygen preburner pressure of 700 to 800+ bar. Definitely pushing the limit of known physics.
Quote from: meberbs on 02/20/2019 01:56 amI can't find any clear explanation on the site about how the fuel and oxidizer are supposed to be pumped. It is simply an axial feed for both fuel and oxidizer, going to radial cooling channels that are spinning about the axis and acting as a centrifugal pump.The patent description may help, although the calculations linked in the original post indicate the number of cooling channels needed to be increased -- particularly if a lower conductivity metal than aluminum is used.
From reading that site, I had no idea that it was referring to 2 different prototypes, that at least clarifies some of the apparent contradictions.
You mention this a couple times, but you left out an important word: fuel rich or oxygen rich? I assume fuel rich
Quote from: jabowery on 02/20/2019 05:57 amQuote from: meberbs on 02/20/2019 01:56 amChamber pressure isn't nearly as important as other metrics: thrust and Isp. The thrust scales favorably. Scales favorably with what? I know chamber pressure is generally proportional to thrust, but multiple other factors also come into play, so it really isn't comparable across engines expect to describe how far you are pushing the limits to make your engine work.
Also for a comparison with staged combustion engines, the main chamber wouldn't necessarily be the highest pressure location, Elon Musk recently said about Raptor's design:QuoteMuch above 300 bar main chamber pressure means extreme oxygen preburner pressure of 700 to 800+ bar. Definitely pushing the limit of known physics.
...I understood that you are using centrifugal pumping, but not where the power was being derived from. It seems that you are getting the power from exhausting at an angle.
It seems to me this leaves you with a massive control problem, since changing the angle of the multiple exhaust nozzles would probably be complex
but maintaining a controlled spin rate matched correctly with engine throttle settings seems like it would severely limit something
and possibly make startup or shutdown a challenge.
...Timing wise, it seems like developing your engine 5 years ago, or a bit earlier would have been good...Today seems too late for this concept to go anywhere. The market is over-saturated with vehicle developers, and any that have a chance at becoming real players would already have engine designs.