Ervin is quite right! Besides that, any design that required active cooling for reliable operation would be a very poor choice in a situation where reliability and safety are top priority. Just look at the Japanese nuclear plant failure as a verification of that concept!
In addition it is certain that the folks at Boeing had verified that the design had an adequate margin of safety. So that would put the cause of failure in the supplier quality area, which, as has been reported quite a few times in Design News over the years, has been one of the ongoing problems with the project. Unfortunately, just because we have provided detailed and adequate specifications for items to be provided by suppliers does not assure that those specifications will always be met.
Cabin altitude (internal cabin pressure at altitude) for the 787 is 6,000 feet maximum. Plane cabins are not usually pressurized to sea level at altitude because of the stress on the airframe, although there is a trend to increase cabin pressures. 8,000 feet cabin altitude is generally the minimum pressure.
I like how everyone is assuming that active cooling is needed (and they seem confident about this.) However nowhere in the article is there a statement of current input or current output. We do not know the amount of power going in or out and cannot make an educated guess if active cooling is needed. I am sure if they were drawing a few W's an hour out of that battery the sheer size alone will handle cooling. There is a sentence that states that current input and output is controlled which leads me to believe that the battery had sufficient cooling.
Any equipment that goes into a plane is tested for thermal cycles. Not saying this one was only reviews of the reports can prove that. But I will be surprised if it was an engineering flaw and it had anything to do with cooling. If I took a guess it would have to be the rest of the electrical system has a fault. it could be one item or multiple items.
However on a project of this scale and expense and complexity it would be wise to not guess and wait for the investigators to do their job and inform the rest of the world what the problem is.
Paul I am far more optimistic on this one! I simply cannot believe that Boeing who has lived by the DO 254 credo for the better part of its existence could ever opt for standard COTS without rigourous climatic testing to verify the specs were met or exceeded. This would constitute a watershed in unacceptably poor risk management and I am not prepared to take away the benefit of the doubt, at least not just yet. If you are correct then we can both share the same kleenex in a corner, but I simply cannot believe that scenario.
I've always assumed that large commercial aircraft capable of cruising at high altitudes had some way of boosting cabin pressure, and if so why not go to full atmospheric? But in my experience, pressure does noticeably increase during a descent (ear problems), so you may be right, it's allowed to drop well below atmospheric. Even so, vibration is still the logical culprit.
Yes, the analysis needs to examine undamaged batteries from the same manufacturer and date code. Preferably samples that have already seen some use. In my own experience with medical devices - yes they need to be highly reliable as well - battery manufacturers want to offer their standard processes even for custom batteries. The problem here is that they want you to take RoHS compliance and No-Clean solder systems. This leads to unreliable circuitry when exposed only to thermal and humidity cycling. Add stress associated with a high vibrational environment and the reliability slips even lower.
I'm certain that Boeing did a lot of testing and much of it done in parallel in an attempt to minimize schedule slip. Unfortunately, some problems only reveal themselves when certain of the stressors are tested in series - just as they are experienced in the real world and under electrical load.
The other aspect of testing that is critical here is the pass-fail criteria. Simply meeting operating specs isn't good enough at this point. The investigators need to gently disassemble the units and along with everything else examine the circuitry under 20x to 40X magnification looking for the beginnings of electrochemical issues such as surface salts, dendrites and the more difficult to detect, tin whiskers. You will be hard pressed to find a component these days that doesn't have pure tin on the leads.
A problem like this rarely has a single cause. To or more corner case conditions must come together in just the right way. This is why serial testing of multiple assemblies under operational load is necessary.
From My earlier comment on these Lithium batteries, I want to hear from Boeing that these batteries are not COTS purchased batteries from the CLINTON era for purchase COTS to save money... Off the shelf devices DO NOT WORK ANYWHERE except on earth in a typical building. Now I want to see evidence that these batteries went through some BOEING testing and was accepted as properly built components worth of aircraft flight for 20 years in service. I bet they dont have that information available and this gets settled out of court with Uncle Sam!!
I share your scary thought, Chuck. I will always give Scientists and Engineers the benefit of the doubt, but as we are remembering the 27th anniversary of the loss of the Challenger's Crew today, sometimes margins of risk get bundled together into an "acceptable flight risk". Not suspecting anything nefarious, but with such a complex system, sometimes it is only possible to rank relative risk in hindsight.
nelso7926, I agree completely. No injuries and certainly no fatalities. I'm sure Boeing has tested and retested this system so I would certainly hope the issue is inadequate cooling and not the lack of cooling. With that being the case, are all of the failures on the ground? Are any experienced in flight? Also, can anyone tell me if there are redundant systems for this device? I don't think so but do not know.
Researchers have been working on a number of alternative chemistries to lithium-ion for next-gen batteries, silicon-air among them. However, while the technology has been viewed as promising and cost-effective, to date researchers haven’t managed to develop a battery of this chemistry with a viable running time -- until now.
Norway-based additive manufacturing company Norsk Titanium is building what it says is the first industrial-scale 3D printing plant in the world for making aerospace-grade metal components. The New York state plant will produce 400 metric tons each year of aerospace-grade, structural titanium parts.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies.
You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived.
So if you can't attend live, attend at your convenience.