SpaceX has publicly indicated that the development cost for Falcon 9 launch vehicle was approximately $300 million. Additionally, approximately $90 million was spent developing the Falcon 1 launch vehicle which did contribute to some extent to the Falcon 9, for a total of $390 million. NASA has verified these costs.
Very interesting presentation. Thanks for posting it.Looking still at the price numbers in that screenshot, would it be safe to assume an F9 pad is an order of magnitude more, i.e. in the low hundreds of $M and that subsequent F9 integration hangars are at least half the price?
I just stumbled across this SpaceX Systems Engineering presentation and found it interesting as a former systems engineer myself.https://www.aiaa.org/uploadedFiles/Events/Conferences/2012_Conferences/2012-Complex-Aerospace-Systems-Exchange-Event/Detailed_Program/CASE2012_2-4_Muratore_presentation.pdfOne interesting bit is the chart that shows the flow of qual and acceptance testing. There's a box labeled "structures component acceptance testing." And a bullet on page 16 says "All hardware acceptance tested." But we know from the CRS-7 failure investigation that the helium tank struts were not acceptance (load) tested.And not acceptance testing the struts ran counter to their philosophy of extensive testing. So it's interesting that not adhering to their own philosophy in the case of the struts came back to bite them.
Quote from: Kabloona on 12/25/2015 11:17 amI just stumbled across this SpaceX Systems Engineering presentation and found it interesting as a former systems engineer myself.https://www.aiaa.org/uploadedFiles/Events/Conferences/2012_Conferences/2012-Complex-Aerospace-Systems-Exchange-Event/Detailed_Program/CASE2012_2-4_Muratore_presentation.pdfOne interesting bit is the chart that shows the flow of qual and acceptance testing. There's a box labeled "structures component acceptance testing." And a bullet on page 16 says "All hardware acceptance tested." But we know from the CRS-7 failure investigation that the helium tank struts were not acceptance (load) tested.And not acceptance testing the struts ran counter to their philosophy of extensive testing. So it's interesting that not adhering to their own philosophy in the case of the struts came back to bite them.Your experience with component testing must have been under an alternate definition. According to definitions for "acceptance testing" online, the general and most common usage, and probably the way SpaceX meant it, refers to testing by the manufacturer prior to delivery to the customer. Labautopaedia.org goes on to point out that a substantial portion of a customer's payment goes toward the manufacturer's testing, and that portion of the payment is not due & paid unless and until the testing is successful.
Quote from: CyndyC on 12/26/2015 07:55 pmQuote from: Kabloona on 12/25/2015 11:17 amOne interesting bit is the chart that shows the flow of qual and acceptance testing. There's a box labeled "structures component acceptance testing." And a bullet on page 16 says "All hardware acceptance tested." But we know from the CRS-7 failure investigation that the helium tank struts were not acceptance (load) tested.And not acceptance testing the struts ran counter to their philosophy of extensive testing. So it's interesting that not adhering to their own philosophy in the case of the struts came back to bite them.Your experience with component testing must have been under an alternate definition. According to definitions for "acceptance testing" online, the general and most common usage, and probably the way SpaceX meant it, refers to testing by the manufacturer prior to delivery to the customer. Labautopaedia.org goes on to point out that a substantial portion of a customer's payment goes toward the manufacturer's testing, and that portion of the payment is not due & paid unless and until the testing is successful.I'm quite familiar with common aerospace practice for component subcontracts and acceptance testing, and I'm trying but failing to understand why you think my post somehow contradicts what you wrote above.When I said "not adhering to their own philosophy," what I meant was that apparently they did not require load testing by the vendor as part of the acceptance criteria. It's up to to buyer to specify what their acceptance criteria are, not the vendor. So by not writing a load testing acceptance requirement into the procurement contract, SpaceX did not adhere to their "test what you fly" philosophy.So I think we are in agreement.
Quote from: Kabloona on 12/25/2015 11:17 amOne interesting bit is the chart that shows the flow of qual and acceptance testing. There's a box labeled "structures component acceptance testing." And a bullet on page 16 says "All hardware acceptance tested." But we know from the CRS-7 failure investigation that the helium tank struts were not acceptance (load) tested.And not acceptance testing the struts ran counter to their philosophy of extensive testing. So it's interesting that not adhering to their own philosophy in the case of the struts came back to bite them.Your experience with component testing must have been under an alternate definition. According to definitions for "acceptance testing" online, the general and most common usage, and probably the way SpaceX meant it, refers to testing by the manufacturer prior to delivery to the customer. Labautopaedia.org goes on to point out that a substantial portion of a customer's payment goes toward the manufacturer's testing, and that portion of the payment is not due & paid unless and until the testing is successful.
One interesting bit is the chart that shows the flow of qual and acceptance testing. There's a box labeled "structures component acceptance testing." And a bullet on page 16 says "All hardware acceptance tested." But we know from the CRS-7 failure investigation that the helium tank struts were not acceptance (load) tested.And not acceptance testing the struts ran counter to their philosophy of extensive testing. So it's interesting that not adhering to their own philosophy in the case of the struts came back to bite them.
That's enlightening that the buyer has to require and set the testing criteria, but by saying "apparently", it sounds like you are only assuming SpaceX didn't require any load testing at all. Someone in the prior discussions brought up "batch testing" in manufacturing, so although that person was only assuming too, at least that much testing might have been required by SX & then done by the manufacturer. Maybe not though.
That's enlightening that the buyer has to require and set the testing criteria, but by saying "apparently", it sounds like you are only assuming SpaceX didn't require any load testing at all.
BTW, isn't turning an argument around to convince the opposite gender has agreed with you supposed to be my line?
SpaceX, and Musk, have stated that the strut was supposed to be "certified" by the supplier.
Whether or not SpaceX required the vendor to do some random load testing from each batch is unknown and not really relevant anyway, because as they learned, one flaw in one casting can ruin your whole rocket. That's why you do 100% load testing of all structure. I'm quite surprised by this lapse in their QA criteria, but no doubt they won't make that mistake again.
I wouldn't have used the word Elon Musk did, "complacent", which at first seemed could be taken offensively by all the SpaceXers who had been bending over backwards to ensure quality control from their respective stations, but the word can also mean merely "contented".
QuoteThat's enlightening that the buyer has to require and set the testing criteria, but by saying "apparently", it sounds like you are only assuming SpaceX didn't require any load testing at all. We're having to read between the lines a bit. What Elon said was that (1) they did not load test *every* strut produced, and (2) they relied instead on materials certifications (ie from the raw materials supplier, not the strut manufacturer). He also said that they had designed the strut with a large safety factor (I don't remember the number, but it was something like a factor of 5, which on a rocket is a huge factor (for man-rated systems, it's usually 1.4)
In my experience, what that means is:...-As a result, SpaceX probably felt comfortable not requiring 100% acceptance load testing of every strut, but instead relied on a materials certification from the raw material supplier that showed the metallurgical content of each batch of steel along with ultimate tensile strength test samples from each batch.
Whether or not SpaceX required the vendor to do some random load testing from each batch is unknown and not really relevant anyway, because as they learned, one flaw in one casting can ruin your whole rocket.
That's why you do 100% load testing of all structure. I'm quite surprised by this lapse in their QA criteria, but no doubt they won't make that mistake again.
No, you misunderstand what a "materials certification" is. It's a piece of paper from the raw materials vendor that the strut maker bought the steel bar stock (or whatever) from. It gives traceability that shows where the raw steel came from, its metallurgical properties, ultimate strength, etc. its basically a "birth certificate" that shows where the raw materials came from and proves they have "good genes."...
That's why you do 100% load testing of all structure.
2. You are wrong about certifications, they can be for raw material, but also processed material, components, assemblies and finished products. One government contractor I worked for, every electronic system we shipped had to have a certain amount of testing and certification done. Component level inspection & certification for critical items is not unusual either.
we're going to move to individually testing each strut independent of any material certifications.
QuoteThat's why you do 100% load testing of all structure.That is not what is done in the aerospace industry (I think).
Quote from: Dante80 on 12/27/2015 07:01 amQuoteThat's why you do 100% load testing of all structure.That is not what is done in the aerospace industry (I think).100% testing is not that uncommon.Every ASME U stamp and/or PED certified pressure vessel has to be hydrostatically pressure tested.
(...)Sorry, don't know what I was smoking when I wrote that.
Quote from: Kabloona on 12/27/2015 12:52 pm(...)Sorry, don't know what I was smoking when I wrote that.Was it certified? I feel your QA process needs a review
Quote2. You are wrong about certifications, they can be for raw material, but also processed material, components, assemblies and finished products. One government contractor I worked for, every electronic system we shipped had to have a certain amount of testing and certification done. Component level inspection & certification for critical items is not unusual either.I never said there weren't other types of certification. But in this case we're taking about a "materials" certification, because this is what Elon actually said:Quotewe're going to move to individually testing each strut independent of any material certifications.
And this is important because if you assume that "Material Certification" only means the raw material portion of a finished purchased part, and not that the finished part itself meets ALL the specifications of the engineering documentation that it was designed to handle...
I have no insight into those numbers, but a post on parabolicarc says NASA has verified the Falcon 1 and Falcon 9 development cost numbers:QuoteSpaceX has publicly indicated that the development cost for Falcon 9 launch vehicle was approximately $300 million. Additionally, approximately $90 million was spent developing the Falcon 1 launch vehicle which did contribute to some extent to the Falcon 9, for a total of $390 million. NASA has verified these costs. http://www.parabolicarc.com/2011/05/31/nasa-analysis-falcon-9-cheaper-traditional-approach/And according to that same article, NASA's own analysis said it would have cost them between $1.7B and $4.0B to develop F9. So SpaceX beat the NASA development cost estimate by at least a factor of 5, and possibly a factor of 10+.Extremely impressive.
In looking at the design development process SpaceX uses it reminds me of the tremendous differences in the Spiral vs Waterfall software development methods. Spiral is design-implement-test-deploy-design-implement-test-deploy... where Waterfall is study-analyze-design-implement-test-deploy-maintain. If the design falls short it is very difficult to overcome these design faults in maintenance phase of the traditional Waterfall method where only the lowest levels are reworked to meet the higher level designs without starting all over, whereas in the Spiral methodology redesign at higher levels is part of the process of evolving the design to make it better and better.Also the time between design start and deploy is very short in the spiral vs the long time for the waterfall. Since time is money also each iteration in the Spiral is a lot cheaper than the waterfall to get to a deployed system. The drawback is that the Spiral method deploys the minimum system and increases it in each iteration where waterfall deploys the complete end post system.From the historical of SpaceX improving the F9 every 2.5 years v1.0->v1.1->FT they are definitely using the Spiral vs the design and done Waterfall that NASA and other LV developers use.
QuoteAnd this is important because if you assume that "Material Certification" only means the raw material portion of a finished purchased part, and not that the finished part itself meets ALL the specifications of the engineering documentation that it was designed to handle...That's what "materials certification" means within NASA...
...and I'd be very surprised if it meant anything different inside SpaceX given how many of their employees have prior experience with NASA standards and the close coordination SpaceX has with their customer...not to mention the requirements NASA is/will be levying on manned F9's.
The way the finished part is determined to meet ALL the specifications is by testing and/or inspection that verifies each spec requirement, and that isn't called "material certification," it's called "acceptance testing," ie verifying that the received part meets all specs before the buyer formally accepts the item.
But on all the programs I've worked (Pegasus, Taurus, Transfer Orbit Stage), the "materials certifications" from vendors were always certification only of raw materials properties and never implied verification of part functionality, etc. Those spec requirements were always verified by separate acceptance tests or inspections.
Yes, there's team spirit, but there's also individual accountability, and someone inside SX made the engineering/cost decision not to require 100% load testing of each strut as an acceptance criterion. And after the failure I'll bet there were a lot of SXer's breathing a quiet sigh of relief that they were not "that person."
You are trying to extrapolate how the private sector (and actually a unique sub-segment of it) works by applying government rules to it. That doesn't work.
The question you raise about "Material Certification" is whether the supplier does any inspection or validation for what they produce. You imply "NO", that all they would do is supply a raw material certification and leave it at that - if the part is wrong, then the customer has to catch it. I don't believe this is what happens.
Maybe the strut vendor did some random sample load testing in each batch of struts, but such testing should not be confused with "materials certification" because they are two completely different things, and someone like Elon would never use the very specific term "materials certification" to mean random sample load testing on a batch of finished struts.
Or is there an indication that someone at SpaceX once explicitly asserted that 100% load testing was not required for that strut?
Quote from: oldAtlas_Eguy on 12/27/2015 07:31 pmIn looking at the design development process SpaceX uses it reminds me of the tremendous differences in the Spiral vs Waterfall software development methods. Spiral is design-implement-test-deploy-design-implement-test-deploy... where Waterfall is study-analyze-design-implement-test-deploy-maintain. If the design falls short it is very difficult to overcome these design faults in maintenance phase of the traditional Waterfall method where only the lowest levels are reworked to meet the higher level designs without starting all over, whereas in the Spiral methodology redesign at higher levels is part of the process of evolving the design to make it better and better.Also the time between design start and deploy is very short in the spiral vs the long time for the waterfall. Since time is money also each iteration in the Spiral is a lot cheaper than the waterfall to get to a deployed system. The drawback is that the Spiral method deploys the minimum system and increases it in each iteration where waterfall deploys the complete end post system.From the historical of SpaceX improving the F9 every 2.5 years v1.0->v1.1->FT they are definitely using the Spiral vs the design and done Waterfall that NASA and other LV developers use.With Musk coming directly from a software background, this approach should be of no surprise. I'm guessing, but I would think Musk looked at the incumbents (mostly/all waterfall?), and thought they were beatable by a more agile company.Time will tell, but he's made a good start.
QuoteYou are trying to extrapolate how the private sector (and actually a unique sub-segment of it) works by applying government rules to it. That doesn't work.It does when SpaceX's main customer is NASA.
They have to speak the same language to some extent, and meet NASA requirements for man-rating F9.
What you're suggesting is that SpaceX doesn't understand what NASA means by a "materials certification" or has a different definition of it, when "materials certification" is going to be a huge paperwork requirement levied by NASA for manned F9 and crewed Dragon flights. In my view it's highly unlikely that SpaceX doesn't understand or has a different definition.
SpaceX provides a service, not a product. Why does SpaceX need to deliver any sort of "materials certification"?
Quote from: Coastal Ron on 12/28/2015 02:31 amSpaceX provides a service, not a product. Why does SpaceX need to deliver any sort of "materials certification"?We've already seen the in-depth review process that SpaceX had to go through with the Air Force to certify the F9 for DoD. There's no way they got the F9 certified without being able to show the Air Force they have basic QA processes like requiring materials certifications for the raw materials in critical components like tanks. That's just a basic part of a QA program, and if you can't even do a basic thing like verify the source, composition and strength of your various raw materials, there is simply no way the Air Force is going to trust you with a $1B payload.
Same thing for NASA. No way they are going to allow their astronauts on an F9 unless they can verify it meets all their man-rating requirements, including having materials certifications and traceability per the usual NASA standards for manned spaceflight.
QuoteOr is there an indication that someone at SpaceX once explicitly asserted that 100% load testing was not required for that strut?*snip* The point is that it's up to SpaceX to write the required acceptance criteria into the contract. Obviously they didn't require 100% load testing. That was either a conscious decision or an oversight by one or more people.
Quote from: Kabloona on 12/27/2015 09:14 pmQuoteOr is there an indication that someone at SpaceX once explicitly asserted that 100% load testing was not required for that strut?*snip* The point is that it's up to SpaceX to write the required acceptance criteria into the contract. Obviously they didn't require 100% load testing. That was either a conscious decision or an oversight by one or more people.Nor should they have. Batch testing should be more than sufficient to catch gross defects in lots of parts, since the part was over-designed by a factor of 3.
You seem to completely exclude the possibility that they would require component testing from a supplier...
But you keep only focusing on raw material.
NASA has no visibility into the component level parts of a Falcon 9 - it is a commercial service, not a product that NASA is buying.
The fact that SpaceX did not try to sue the strut supplier indicates they recognize their own responsibility for not requiring 100% load testing for acceptance. We can assume the provider fulfilled their obligation to deliver the product with specified testing.
Quote from: Jcc on 12/29/2015 02:46 pmThe fact that SpaceX did not try to sue the strut supplier indicates they recognize their own responsibility for not requiring 100% load testing for acceptance. We can assume the provider fulfilled their obligation to deliver the product with specified testing.Or they negotiated some compensation but agreed to keep fact that confidential. It's not safe to assume that we know about everything that occurs. A transfer of money is a lot easier to hide than a rocket.
Quote from: deltaV on 12/29/2015 04:19 pmQuote from: Jcc on 12/29/2015 02:46 pmThe fact that SpaceX did not try to sue the strut supplier indicates they recognize their own responsibility for not requiring 100% load testing for acceptance. We can assume the provider fulfilled their obligation to deliver the product with specified testing.Or they negotiated some compensation but agreed to keep fact that confidential. It's not safe to assume that we know about everything that occurs. A transfer of money is a lot easier to hide than a rocket.But how would or could a little strut manufacturer possibly compensate for the loss of a rocket & payload worth millions of dollars?
1. But you keep only focusing on raw material. You seem to completely exclude the possibility that they would require component testing from a supplier - and I think it's because you don't think "material certification" can mean something different than what you have experienced. That is a fragile line of reasoning...2. NASA has no visibility into the component level parts of a Falcon 9 - it is a commercial service, not a product that NASA is buying. Do think NASA inspectors are on the Falcon 9 production line?
Quote from: CyndyC on 12/29/2015 06:45 pmBut how would or could a little strut manufacturer possibly compensate for the loss of a rocket & payload worth millions of dollars?What's your source for the strut manufacturer being "little"?
But how would or could a little strut manufacturer possibly compensate for the loss of a rocket & payload worth millions of dollars?
Quote from: deltaV on 12/29/2015 07:42 pmQuote from: CyndyC on 12/29/2015 06:45 pmBut how would or could a little strut manufacturer possibly compensate for the loss of a rocket & payload worth millions of dollars?What's your source for the strut manufacturer being "little"?Albert Einstein, Theory of Relativity
Some new and interesting videos related to SpaceX's systems engineering approach. And Dan Rasky has a few other SpaceX- and Blue- Origin-related videos worth checking out on YouTube.