OK, semi-seriously, has anyone heard of any interest in Skylon from Richard Branson/Virgin Galactic? For a few hundred million, I bet Bond and company might be willing to rename Skylon 'SpaceShipFour'...And how would such an investment work, assuming that at a later date the project is likely to be lead by a consortium of industry giants?
I haven't been keeping up with the mass and volume details of Skylon, but a point I've made off-and-on for the past few years is that the propellant mass fraction of the vehicle is highly ambitious, and I say this as a long-time advocate of SSTO. Using the data above, I note that if we replaced the 1100m³ of propellant volume with low-average density LOX-LH2, we're looking at a PMF of 0.94.
Quote from: HMXHMX on 09/16/2012 04:47 pmI haven't been keeping up with the mass and volume details of Skylon, but a point I've made off-and-on for the past few years is that the propellant mass fraction of the vehicle is highly ambitious, and I say this as a long-time advocate of SSTO. Using the data above, I note that if we replaced the 1100m³ of propellant volume with low-average density LOX-LH2, we're looking at a PMF of 0.94. .. And here is where you make your critical mistake.Skylon has much more hydgogen (which is lighter than oxygen) and much less oxygen, so the total weight of the fuel + propellant is much smaller than in your calculations.And this affects all the later conclusions that you make, making them false.
Reaction Engine's Skylon technical page lists an unladen mass of 41 mT, and a fuel load of 220 mT, with 12 mT payload adding up to basically the cited 273 mT maximum takeoff mass. That's more like 81% fuel at takeoff if you count the payload in with the dry mass, or 85% if you don't.
I'm strongly tempted to add that I have a marvelous proof of this thesis, but neither the time nor room to write it down...
No, no mistake. I am not showing the PMF of Skylon at the air-breather mix ratio, but at the pure rocket LOX-LH2 mix ratio, nominally 6:1. Mine is a perfectly valid means by which to compare the relative difficulty of building Skylon's tanks, say compared with the ET of the Space Shuttle. And the message is those tanks will be very hard to build, indeed. And even harder to make reusable. Not impossible: but if they can be built at all, I can show fairly easily that a pure rocket vehicle with the same PMF assumptions, deleting the low t/w air-breather engines and substituting conventional pure rocket engines, will place a 2x or greater payload into LEO for the same physical vehicle size (volume).I've only been doing these calculations for the past 43 years, so I think I may have it right... Just keep saying to yourself, the metric by which one measures the feasibility of a vehicle's PMF is based on tank volume, irrespective of propellant type. I'm strongly tempted to add that I have a marvelous proof of this thesis, but neither the time nor room to write it down...
Quote from: HMXHMX on 09/17/2012 06:54 amNo, no mistake. I am not showing the PMF of Skylon at the air-breather mix ratio, but at the pure rocket LOX-LH2 mix ratio, nominally 6:1. Mine is a perfectly valid means by which to compare the relative difficulty of building Skylon's tanks, say compared with the ET of the Space Shuttle. And the message is those tanks will be very hard to build, indeed. And even harder to make reusable. Not impossible: but if they can be built at all, I can show fairly easily that a pure rocket vehicle with the same PMF assumptions, deleting the low t/w air-breather engines and substituting conventional pure rocket engines, will place a 2x or greater payload into LEO for the same physical vehicle size (volume).I've only been doing these calculations for the past 43 years, so I think I may have it right... Just keep saying to yourself, the metric by which one measures the feasibility of a vehicle's PMF is based on tank volume, irrespective of propellant type. I'm strongly tempted to add that I have a marvelous proof of this thesis, but neither the time nor room to write it down...There are a few things yo may not have factored in.REL seem to have started to quote propellant mass as a single figure. IIRC the split is 70/150 but I can't recall if that's O2/H2 or vice versa. I'll note SABRE is designed specifically to reduce LO2 consumption and has substantial excess LH2, which it dumps to the "spill ramjet," however in the film Alan Bond states this amount was halved compared to the original RR design and for the SABRE 4 iteration has been halved again, which required a re-think on how the CG shift was handled in the D1 re-design as not enough LH2 was being used to counteract the CP shift (this issue has been resolved according to the IAF paper). REL have stated they plan to use sub cooled propellants in unvented tanks. I recall 18k rather than the usual 20k for LH2 (although NASA seem to have looked at 16K) and I think 82k for LO2. This would definitely reduce tank size over NBP designsThey have also stated they have an interest in low ullage pressure tanks to lower the amount of either He or vaporized propellants needed to pressurize them. The shift in propellant mass ratios alone would seem to make a big difference.
Quote from: HMXHMX on 09/17/2012 06:54 amI'm strongly tempted to add that I have a marvelous proof of this thesis, but neither the time nor room to write it down...You'd write it in if only you could find a way to put it in the margin of the page? cheers, Martin
And I maintain it still would be superior to go pure rocket, rather than rely on air-breather technology.
I blogged a year ago:Sunday, June 12, 2011I'm a bit skeptical about Skylon.After running through the mass numbers for Skylon that Reaction Engines offers, I'm left believing that they've got an engine that will theoretically get them to orbit in one stage, but only by them making unrealistic assumptions about the structural weight of the rest of the vehicle, total dry mass 53 tonnes, engine thrust 270 tonnes, engine T/W 14 therefore mass of engines ~19 tonnes, therefore mass of the rest of the vehicle ~34 tonnes. 34 tonnes for a winged vehicle that's 83 meters long, carries all its landing gear to orbit, it has a propellant volume around 1400^3 meters, it uses cryogenic propellants and it has to endure re-entry. I know they're promoting Skylon as having revolutionary construction materials and methods, but it seems to me they've had to make some excessively optimistic assumptions about the structural weight to get the numbers to come together so they can continue with their pet project - the engines.Looking at it another way: The combined propellant tank volume by my math (with a few assumptions on the current LH2:LOX ratio) would have enough volume to hold 500 tonnes of LH2/LOX at a 1:6 ratio, lets allow structural weight growth of 20% for the heavier take-off weight making structural wt 40.8 tonnes, 2 SSME's (or easily maintained equivalent) is + 6.4 tonnes, so total unladen weight is 47.2 tonnes, add a P/L of 15 tonnes and also the 500 tonnes LOX/LH2 and you get a take-off weight of 562.2 tonnes, at engine shut off weight is 62.2. Mo/M1 is 9.03, delta V at Ve 4500 m/s is 9907m/s.9.2 km/s is about all you need to get into orbit.
Quote from: HMXHMX on 09/17/2012 07:07 amAnd I maintain it still would be superior to go pure rocket, rather than rely on air-breather technology.Do you feel the same way about the utility of airbreathing on a reusable first stage? And what if you only look at it from a "deliberately sunk" cost perspective?
And if you use denser propellants than LOX-LH2, you can do even better. Making a few very BOE assumptions I conclude that – based on volume alone without adjusting engine mass – a VTHL LOX-kerosene equivalent vehicle would carry about 28 tons to LEO
Quote from: HMXHMX on 09/17/2012 03:56 pmAnd if you use denser propellants than LOX-LH2, you can do even better. Making a few very BOE assumptions I conclude that – based on volume alone without adjusting engine mass – a VTHL LOX-kerosene equivalent vehicle would carry about 28 tons to LEO Except it would not *be* an equivalent vehicle. A true equivalent would be a HTHL winged LOX/Kero system, which might an interesting vehicle in its own right, but is OT for this thread. I've long been a fan of your proposals and the results you have achieved and it's only recently I've come to realize one of Skylon's hidden strengths is it's aimed to give a TSTO payload fraction in an SSTO vehicle. AFAIK previous SSTO attempts have countered this by either saying (basically) "Build it 4x bigger" or "launch 4x more frequently." Both are viable *engineering* solutions but (I think) hit major issues with the people who would write the checks for development. There are many possible solutions to the problem "Get X Kg of payload to orbit Y Km in altitude at Z degrees inclination." REL have chosen their approach and have stuck with it for nearly 25 years. I cannot say if Skylon is the best (depending on what metric you're using) but I can say it's the one that seems to be getting funded, *despite* the fact that any US investors would face potential criminal charges if they invested in REL (Mark Hempsell, Space Show interview IIRC) and hence are not an option to them. I'd still be interested in finding out how changing to a 70/150 mt O:F ratio (or vice versa) affects your calculations. I'd consider the tank reduction caused by sub cooling H2 (I think 5% but I'm using m1v1/t1=m2v2/t2, not exactly cutting edge math) should be substantial.
It seems to me that you are neglecting the effect of increased weight loading on structural requirements.A Skylon loaded with LOX/LH2 at 6:1 would collapse its landing gear. Strengthen the landing gear and the spaceframe would fail. Strengthen the spaceframe and the wings would either tear off or be inadequate to get the thing off the runway at all.You could switch to vertical takeoff, but then your thrust has to increase significantly (requiring extra engine mass - doubling the vehicle mass and increasing T/W by 50% means triple the thrust, which means that an engine T/W of 60 gives you 70% of the mass of the SABRE engines on the original vehicle), and the increase in axial loading will at least partially offset the (likely) reduction in design bending moment vs. the horizontal takeoff configuration.Either way you're dealing with close to twice the total weight of the original Skylon. A 20% increase in structural mass (cf. Andrew_W) is not going to cover this.Also, 4500 N·s/kg mission-average (ibid.) is rather ambitious for something ground-launched...
Also, putting the engines on the back is what took down HOTOL and VentureStar. Admittedly a conventional rocket engine cluster would be lighter than either an RB545 or an RS-2200...
In addition, I'm neglecting much lighter main and nose gear mass that come from using the gear only for landing empty.