I thought the Orbcomm boost was scrapped due to safety concerns regarding the ISS, rather than a technical limitation of the SpaceX.Statistically, the answer is clear: Multiple engines are more reliable as long as the failure of one engine does not cause the failure of others, or the loss of mission. A 9 engine vehicle is 9 times more likely to have an engine failure than a 1 engine vehicle (see note), so the probability that the failure will effect other engines must be lower than 1 in 9. Note: One would also assume that a production run 9 times greater will result in more reliable engines. Whether it is more cost effective remains to be seen. If the engine is 100% reliable, then a single engine would be best. What is the most reliable engine to date? Would it be the space shuttle SRBs with 1 failure in over 200 launches? However, solids have unpleasant failure modes, so what is the most reliable liquid fuelled engine?
The 2nd burn was automatically canceled due to the fuel check after the release of dragon. There was not enough fuel to get it to the approved orbit.
Quote from: JohnFornaro on 10/08/2012 08:05 pmTo the OP: Good idea.Agree, on balance. Also the multiple engine set up has turned out fortuitous for the proposed reuseable first stage design. But of course SpaceX had to use multiple engines to get the performance they needed and made a virtue out of a necessity.
To the OP: Good idea.
Apples-to-oranges, Taurus failed because of a lack of payload fairing separation not engine failure.
At a 1 in 40 engine failure rate that means a statistical expectation of an engine failure in the Falcon Heavy on more than half the flights.
It was not a design requirement but a fallout
The size of the existing Merlin engine dictated that 9 would be needed to meet mission requirements.
They designed for redundancy. They designed in engine separation barriers. They designed in in-flight recovery. Sure sounds like they designed for loss of an engine.The distinction between an original specification point and the choice of meeting that specification with redundancy and engine-out ability is precisely what I was referring to as "philosophical wrangling".
Engine out capability is bug and not a designed in feature
It would be pointless to test all engines to destruction - you would have no engines left to actually fly.
It really all comes down to whether or not fratricide is common with your typical failure modes, and the jury is out on that one.
Quote from: FuseUpHereAlone on 10/10/2012 02:01 amWell if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement. Depends on what you mean by "it". The CRS-1 mission appears OK, and thus F9 met its nominal goals; the rest is up to Dragon and is TBD. The ORBCOMM mission was not OK and thus F9 did not meet its nominal goals.Queue interminable argument about "launch" vs. "flight" vs. "mission" vs. etc...
Well if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement.
Quote from: Lars_J on 10/10/2012 02:05 amQuote from: FuseUpHereAlone on 10/10/2012 02:01 amWell if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement.I'm choosing to believe that you wrote this as a joke, because the other alternative is too depressing. Alternatively, could you say that Falcon 9 has engine-out capability for one payload, but not two?
Quote from: FuseUpHereAlone on 10/10/2012 02:01 amWell if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement.I'm choosing to believe that you wrote this as a joke, because the other alternative is too depressing.
Quote from: Lars_J on 10/10/2012 02:05 amQuote from: FuseUpHereAlone on 10/10/2012 02:01 amWell if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement.I'm choosing to believe that you wrote this as a joke, because the other alternative is too depressing. This isn't a joke, just a simple exercise in determining design requirements, and validating them based on performance. Otherwise we’re just spinning the truth.
Well if it was actually designed with engine-out capability as a requirement, then the CRS-1 flight proves that Falcon 9 has not met this requirement. Proof: The CRS-1 flight profile called for Falcon 9 to separate from Dragon in one orbit, boost to another orbit, then separate from the Orbcomm satellite. The first stage suffered an engine-out event. Falcon 9 successfully releases Dragon, but lacks enough propellant to boost the Orbcomm satellite to its proper orbit (per the flight profile). If Falcon 9 could not execute the entire mission with an engine-out, then engine-out does not allow Falcon 9 to meet its rated performance. Therefore, Falcon 9’s rated performance cannot be attained with an engine-out.The point here is that you can’t just cluster a bunch of engines together and say that it has “engine-out” capability. If it does, then it better perform as planned when one or more of those engines cuts out. I suspect that a Falcon 9 with engine-out designed into it would really have performance numbers similar to a Falcon 8 (an imaginary Falcon 9 with one unused engine). Maybe a Falcon 7 if we wanted 2 engine-out capability.
And the main disadvantage is that the chance of an engine failure, especially during the first couple of launches, are much higher.
I've developed a new pet peeve since the launch. Am I the only that prefers the industry euphemism RUD not be used ever again? Has to be something better.
It isn't an industry euphemism, but a Spacex one
I totally agree with you FuseUpHereAlone, when the maneuver for the Orbcomm satellite wasn't performed because there wasn't enough propellant (margin) left to execute it. But it they didn't do it for ISS safety reasons, I disagree.
That said, I think using multiple engines on a stage has pros and cones. Others have given good points for this. I think the main benefit are cost savings, and increased reliability over time. And the main disadvantage is that the chance of an engine failure, especially during the first couple of launches, are much higher.
{snip}Quote from: A_M_Swallow on 10/09/2012 04:59 amAt a 1 in 40 engine failure rate that means a statistical expectation of an engine failure in the Falcon Heavy on more than half the flights. In other words, they cannot learn from their mistakes and improve the engine to reduce the failure rate?
Quote from: JohnFornaro on 10/10/2012 02:39 pm{snip}Quote from: A_M_Swallow on 10/09/2012 04:59 amAt a 1 in 40 engine failure rate that means a statistical expectation of an engine failure in the Falcon Heavy on more than half the flights. In other words, they cannot learn from their mistakes and improve the engine to reduce the failure rate?That is a different equation.My commentary. SpaceX (and FAA) had better learn from their mistakes.Engine rateLaunch anomaly Rate1:27 Every launch1:2701:101:27001:100