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Space Science

Spaceship One Test Flight Anomolies 28

Marc Newman writes "Aviation Week reported that Scaled Composites had some unexpected flight anomolies on it's 23-Sept-2003 flight test. The test was conducted with an aft Center of Gravity (CG) and produced some unexpected nose up pitching. They were able to maneuver out of the stall with lateral motions. They also had much higher than expected drag from the newly installed gear doors. They described the pitch up motion as serious, as some abort scenarios leave the vehicle in an even worse aft CG situation than this flight (they can dump oxidizer but not fuel, and the fuel is located aft). They indicated that this lack of pitch control would 'require changes'. It's not expected that they will be able to meet their goal of a flight into space by the end of the year. There is a flight log and there is an article in this week's Aviation Week and Space Technology but it's not showing up on their web site yet."
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Spaceship One Test Flight Anomolies

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  • Assuming that they are hosed, and will miss the all important December 17th date, they are still gonna beat NASA as the next manned flight from this continent :)

    I'm not a fair weather fan, I bet they still have a shot at the 17th.
  • by LWATCDR ( 28044 ) on Tuesday October 07, 2003 @04:53PM (#7157388) Homepage Journal
    This could have killed someone. This shows the value of a well thought out test program. I wonder if any other X-Prize teams are testing abort situations and CG limits?
  • by dougmc ( 70836 ) <dougmc+slashdot@frenzied.us> on Tuesday October 07, 2003 @05:42PM (#7157838) Homepage
    All planes become very difficult to fly when the center of gravity gets too far back. (On the other hand, if the center of gravity goes too far forward, the plane becomes extremely stable, but loses maneuverability and efficiency. If it goes *too* far forward, you may not be able to even keep the nose up. But as a rule of thumb, too far forward is much better than too far back.)

    If the center of gravity goes far back enough, the plane becomes unflyable. Not quite so far back, the plane may be very difficult to fly (requiring that the pilot `stay on top of it', and if it gets into a spin it may not be possible to recover from it.

    Aerobatic planes and planes that are trying to make very long trips on limited fuel (like the Spirit of St. Louis) will keep the center of gravity a further back than most -- but not too far. In a trainer, you usually keep it a bit further forward than usual to enhance the stability of the plane.

    How is this different than any other plane? They intentionally set the center of gravity too far back, and it flew poorly. They should have anticipated this (and I suspect they did, and this isn't as big a setback as expected.)

    • I am surprised that a poster with such a low ID number would resort to using logic to analyse a linked to article. I commend thee. </sarcasm>

      And it happens to be that you are nearly 100% correct.

      I was intrigued by the lack of understanding with respect to drag and gear door (seams I presume). Wasn't this sufficiently studied in the 1950's? *sigh* Geeks just love to learn it again for the first time I suppose... ;-)

      One would hope that these new aero aids that are going to be implemented to keep the
    • I am not an aerospace engineer, but even I know that all the simulation, wind tunnel tests and design experience is not enough to guarantee that you can get a plane right first time. This is why they build prototypes and put them through rigorous flight trials before deciding that they are ready to fly.

      They obviously have a requirement for how far back the centre of gravity can be, flew a test flight to check this requirement and it failed, so they fix the problem and build a new prototype. This is no d

  • I bet they're regreting going with the hybrid engine. A pressure-fed liquid engine would have
    enabled them to dump all propellant in an abort.
    • Not really. You would still have to pump the fuel and oxidizer through the engine, and in order for the turbopumps to pump the engine would have to be running (both systems are interconnected). So in short, no purge for you! Depending on the design of their hybrid, position of the nitrous tank will be key, as the nitrous oxide tank will deplete, mass-wise, quicker than the HTBP (rubber), resulting in a CG shift to the rear of the spacecraft. -philski aerospace engineer in the making
  • by Zachary Kessin ( 1372 ) <zkessin@gmail.com> on Wednesday October 08, 2003 @01:45AM (#7160844) Homepage Journal
    If there were no problems at all in testing I would be worried. Burt Rutan is pushing the limit here. When you do that you should hit a few snags. Its not a bit deal that is why you do a lot of flight testing. If you look at the test logs it is very clear that Rutan et al have a well thought out flight test program. And they are running it. From everything I know they have people who really know their stuff.

    They will fix this problem, and I'm sure they will find a bunch of other ones and then they will fix them too. If i were a betting man (and I'm not) I would be putting my money on scaled to win the X-prize.
  • The flight tests at this point are comparable to the ALT (approach and landing test) program that was flown from about 1977 until 1979 using an unpowered glider-only version of the Space Shuttle -- it had fake engine nozzles, no real tiles, and had fake tile patterns to make it look mostly like the real thing (presumably this is painted on; I haven't seen Enterprise in person yet, but will late this year or early next). (The imagery of it in the introduction to the TV series of the same name is incorrect --

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