One thing I'm curious about (one thing amongst many) is the potential problem of particulates clogging the fine mesh of the heat exchangers. Do airborne particulates pose a different challenge than the icing problem? We saw all the airlines being grounded over Europe when the Icelandic volcanoes erupted a few years ago. Does the heat exchanger on the sabre engine make it more sensitive to such challenges than a conventional jet engine?
?? if you agree we can predict the thrust of course we can predict the Isp. One determines the other. We have had no problems with Isp modelling in the past.
I have not found any reference to these kinds of problems/solutions on the REL website. This could be a show-stopper for the reusability of the SABRE engine. Mark Hempsell, if you're reading this, has REL a plan for dealing with this problem?
Someone has to be wrong. I'm no rocket engineer, but I'll try a very basic calculation.
Skylon can go to Mach 5 while breathing air:Mach 5 = 340 m/s * 5 = 1700 m/s.Let's say the target speed for orbiting is 10 km/s (I have no idea of the exact value but it's probably about this speed).
That's a speed ratio of 10e3/1700 = 100/17 ~ 5.9In terms of energy, that's a ratio of 5.9**2 = 34. So, the kinetic energy in the air-breathing phase is about 34 times smaller than the energy for orbiting.
Quote from: grondilu on 12/03/2012 08:20 amThat's a speed ratio of 10e3/1700 = 100/17 ~ 5.9In terms of energy, that's a ratio of 5.9**2 = 34. So, the kinetic energy in the air-breathing phase is about 34 times smaller than the energy for orbiting.Yes, exactly. The kinetic energy to achieve 1e4 m/s is 1e8 J. The kinetic energy to achieve 1.7e3 is 2.89e6 J. That's a difference of 9.711e7 J. In other words, 97.11% of the required energy to get to orbit happens after Mach 5.
Quote from: QuantumG on 12/03/2012 08:45 amQuote from: grondilu on 12/03/2012 08:20 amThat's a speed ratio of 10e3/1700 = 100/17 ~ 5.9In terms of energy, that's a ratio of 5.9**2 = 34. So, the kinetic energy in the air-breathing phase is about 34 times smaller than the energy for orbiting.Yes, exactly. The kinetic energy to achieve 1e4 m/s is 1e8 J. The kinetic energy to achieve 1.7e3 is 2.89e6 J. That's a difference of 9.711e7 J. In other words, 97.11% of the required energy to get to orbit happens after Mach 5.Wrong! Kinetic energy is 1/2 m v^2 The mass at the end of the air breathing stage is not the mass when Skylon reaches orbit.
Wrong! Kinetic energy is 1/2 m v^2 The mass at the end of the air breathing stage is not the mass when Skylon reaches orbit.
Let's say the target speed for orbiting is 10 km/s (I have no idea of the exact value but it's probably about this speed).
The kinetic energy to achieve 1e4 m/s is 1e8 J. The kinetic energy to achieve 1.7e3 is 2.89e6 J. That's a difference of 9.711e7 J. In other words, 97.11% of the required energy to get to orbit happens after Mach 5.
The mass at the end of the air breathing stage is not the mass when Skylon reaches orbit.
Let's say we need 9.5 km/s total delta-v, nad that our LOX/LH2 engine has a 4.5 km/s exhaust velocity. With air-breathing propulsion to Mach 5 (burning very light hydrogen) the LOX/LH2 delta-v is reduced to 7.8 km/s.
Let's say we need 9.5 km/s total delta-v, nad that our LOX/LH2 engine has a 4.5 km/s exhaust velocity. With air-breathing propulsion to Mach 5 (burning very light hydrogen) the LOX/LH2 delta-v is reduced to 7.8 km/s. the corresponding engine+structure+payload mass fraction is 17.7%. Starting LOX/LH2 propulsion from the ground gives you only 12.1% E+S+P.
So, what is the main point of air-breathing? Is it about saving weight or is it about horizontal take-off and landing?
Quote from: tlesinsk on 12/03/2012 09:23 amLet's say we need 9.5 km/s total delta-v, nad that our LOX/LH2 engine has a 4.5 km/s exhaust velocity. With air-breathing propulsion to Mach 5 (burning very light hydrogen) the LOX/LH2 delta-v is reduced to 7.8 km/s.Nope. Read my post above. You've lumped all the losses into the rocket phase, when they mostly belong in the airbreathing phase.
Or you could just have two stages...