The Dragon capsule will have a propellant load capable of 300 Delta-V at a minimum. The flight control of the Dragon capsule's trajectory after engine-out (last minute of powered flight about 900 nm downrange) should adjust the reentry angle such that Dragon will finish in the Atlantic.
1. If the Demo's go as well as us "enthused SpaceX fans" their manifest is expected to explode.2. The costs will likely go up a bit but they will not be "similar" to other launch providers.
Jim, I'm pretty sure that Dragon, whatever is actually inside, counts as a real spacecraft.
It's processes and systems engineering that guarantee success. Read The Secret of Apollo. Elon has given speeches on his belief that systems engineering is an artifact of the DoD. Until they adopt that or tell me they have some other "secret" I won't risk my DNA or my irreplaceable payload with them.I'm enjoying this debate, though. As they say, where you stand depends on where you sit.
Quote from: llo2015 on 12/08/2010 02:01 amThe Dragon capsule will have a propellant load capable of 300 Delta-V at a minimum. The flight control of the Dragon capsule's trajectory after engine-out (last minute of powered flight about 900 nm downrange) should adjust the reentry angle such that Dragon will finish in the Atlantic. What says the Dragon is active during ascent, most spacecraft aren't.
What's going here? Not all of the pictures (different days, different times of day?) show this umbilical like this, but what gives?
Quote from: corrodedNut on 12/08/2010 12:30 amWhat's going here? Not all of the pictures (different days, different times of day?) show this umbilical like this, but what gives? Nobody is running with this? Something is disconnected.http://forum.nasaspaceflight.com/index.php?topic=22041.msg667684#msg667684
Quote from: Malderi on 12/08/2010 02:02 amJim, I'm pretty sure that Dragon, whatever is actually inside, counts as a real spacecraft. No, it is not the paying customer
Quote from: Jim on 12/08/2010 03:34 amQuote from: corrodedNut on 12/08/2010 12:30 amWhat's going here? Not all of the pictures (different days, different times of day?) show this umbilical like this, but what gives? Nobody is running with this? Something is disconnected.http://forum.nasaspaceflight.com/index.php?topic=22041.msg667684#msg667684Had to go seaching through the NASA gallery, seems the photos when its disconnected are from the 3rd Dec (Abort day) but on the 4th Dec photos it's connected just fine. (Successful 2sec test day)
Once again, not opposed to Systems Engineering, just tend to cringe whenever I hear that some NASA or DoD contractor lists "Systems Engineering" as their key area of core competence...
Going back to the nozzle...Since thermal concerns were mentioned, remember that radiative heating was implicated in the failure of the roll control actuator on flight one. SpaceX says they've fixed the issue, but increased radiative heating could affect the fix.However, the heat transfer analysis is not simple. The nozzle extension clearly (from past launch videos) gets very hot. It gains heat from the plume via both radiation and convection. It then radiates all of that heat with a high emissivity.The unconstrained plume has only radiation to heat the rocket by, and while the angle of view effectively subtends infinity, it does not maintain its temperature that far. It also, as a diffuse gas rather than a sheet of metal, does not have the same emissivity.So between the plume being exposed closer or there being less nozzle to radiate, I don't know where the total heating of the 2nd stage ends up.And as for SpaceX's analysis - I suspect they analyzed resulting ISP and delta-V, but didn't go as far as heat transfer.
You have no proof of the #1 and you are wrong about #2, their costs are getting close
Going back to the nozzle...Since thermal concerns were mentioned, remember that radiative heating was implicated in the failure of the roll control actuator on flight one. SpaceX says they've fixed the issue, but increased radiative heating could affect the fix.However, the heat transfer analysis is not simple. The nozzle extension clearly (from past launch videos) gets very hot. It gains heat from the plume via both radiation and convection. It then radiates all of that heat with a high emissivity.The unconstrained plume has only radiation to heat the rocket by, and while the angle of view effectively subtends infinity, it does not maintain its temperature that far. It also, as a diffuse gas rather than a sheet of metal, does not have the same emissivity.So between the plume being exposed closer or there being less nozzle to radiate, I don't know where the total heating of the 2nd stage ends up.And as for SpaceX's analysis - I suspect they analyzed resulting ISP and delta-V, but didn't go as far as heat transfer.Anyways - shortened nozzle should be noticeable in the 2nd stage firing video.
Going back to the nozzle...[...]I suspect they analyzed resulting ISP and delta-V, but didn't go as far as heat transfer.
It's processes and systems engineering that guarantee success. [...] Until they adopt that or tell me they have some other "secret" I won't risk my DNA or my irreplaceable payload with them.
I suspect SpaceX has computer models and sufficient computational resources to run -- as many times as they like with as many variations as they can imagine -- complete simulations of an entire flight. For the first stage that includes atmospheric, mechanical, thermal, and vibro-acoustic dynamics. For the second stage, it includes all of those that still apply outside the atmosphere, plus solar effects and anything else known to be of importance in that flight regime. If they had that, then they could try out design variations (in the simulator) whenever they thought of them and quickly determine if they're broken. Do you believe heavy reliance on simulation like that could be the "secret" that lets them avoid endless up-front systems engineering cycles? Would it make their current behavior as regards the "short extension" mvac appear rational?