I agree with DrQuine. Yes, you are right. Every individual cell inside the battery compartment of Li-Ion pack must be individually monitored using the fuel gauge Li-Ion cell over charge/discharge algorithm embedded in the SOC (system on chip) to monitor the state of charge (SoC) of individual Li-Ion cell. If one of the cells over charged or discharged for some reason, one can't prevent the cell from deterioration as the over charged/discharged situation initiates electrolyte (aportic) decomposition which will result in the gas evolution and pressure being built up in every further charge/discharge cycles till it explodes. I think this must have been the issue in Dreamliner case. Battery chemistry must be associated with external electronic control system such as a charger with CC-CV protocol. Hence, Li-Ion cell, although possessing wondering high energy density with high working voltage, the danger comes from many different angle but with one particular issue (over charging)!! Moreover, Anode side (perhaps graphitic carbon or Si-Sn-C composite) should not be over lithiated due to over charging as it the anode in Li-Ion cell is limited (so-called anode limitation to avoid formation of metallic lithium. Hence, a variety of cell issues emanated pausibly from the cell itself. If the latter is ensured, SoC monitoring circuit must have the appropriate CC-CV (constant current-constant voltage) protol. Any comments?
PHW_#1 I disagree. http://en.wikipedia.org/wiki/Lithium_iron_phosphate_battery gives the reasons why I said LiFePO4 is the safer chemistry. It would be my guess that there is a heater circuit in this battery, because very cold batteries perform poorly.
DrQuine - in a multi-series-cell battery, then it is usual to monitor the individual cell voltages. The Dreamliner battery is comprised of 8 series cells and I think you can see pairs of wires connected to each cell that I guess are for monitoring cell voltages. See slide 9 and zoom in http://www.ntsb.gov/investigations/2013/boeing_787/JAL_B-787_1-24-13.pdf
Please stop thinking Lithium Iron Phosphate won't have same issues. Byd and Volts cases are all Lithium Iron phosphate batteries. They can cause fires even the "trigger points" might be different. It is not clear to me how to prevent it re-ocurrung for BYD or Volt cases yet. And GM has a burnt battery lab. All Li batteries need to be very careful about electronics-charge/discharge/BMS design and very good thermal dissipation design.
I will assume the batteries used for airplane power start, the cranking current is quite high. Only a few chemsitry left for such application and at low temperature environment LiFexOy is not a good choice. If it is charger or thermal design issues, same thing will happen in any chemistry. A great engineering challenge for us to fix this problem. I am more concerned that Li-battery might be dumped in Boeing design before they figure out the reasons.
Is there any mechanism to monitor voltages in individual cells rather than just the series sum of all the cells? If one or two cells are faulty (or shorted out), the standard charging voltage across the entire battery could produce an over voltage condition in the remaining functional cells.
The Japan airlines fire started when the plane was on the ground and being cleaned. What event happened during that time I would like to know. Is this when the charger kicked in? I don't know. Also wonder how cold the batteries get when the plane is in the air, or if there is a battery heater function in the design.
It seems that no one suspects the effects of flight. Batteries and charging systems were probably tested extensively on the ground - at sea level, but possibly not at altitude. Also, the comment about lightning strikes seems particularly relevant.
The NTSB site linked to in the article has some interesting info - it shows a report that has a photo of a battery cell with a "damaged electrode - internal s/c."
The battery chemistry used is Lithium Cobalt Oxide. I would have expected the safter Lithium Iron Phosphate to be used instead (or another, safer-chemistry type available) in this safety critical application. For my money, this is one of the key factors that I would expect to see them change in future designs.
I tried to see from the photos what (if any) power conversion electronics were in the battery box, but couldn't see any high-power, only two low power, circuit boards. Where is the battery charger located? Is it underneath the cells? The bus bars disappear to the underside of the housing and it is difficult to see what is down there. The battery charger power electronics is of course another suspect in the picture I am sure.
Igor1327 is right - normally LiIon cells have integrated OV, UV and Over-Current protection, per cell. External OV protection per cell and external over current protection is also added. I believe you can see the OV protection in the photo of the undamaged unit - it is the loom of small gauge wires connected to each cell's bus bar. Also, integrating a thermistor per cell is standard practice to prevent over-heating. Electrically this should protect it. What I wonder if the fault was in the electrochemistry of the battery + electrodes, then maybe the protection electronics is out of the picture because it cannot protect against a chemical reaction that has started, only against volts, amps. Looking at the picture of the fire damaged battery box, then the cell top-right corner, second one down, looks more damaged than the others.
"...the APU battery did not exceed its designed voltage of 32 volts. " do not guaranteed each cells inside the APU battery have not been overcharged.
It is dangerous ,if the charger over charge protection were controlled by voltage of the APU battery , instead of voltage of each cells.
What are the engineering and design challenges in creating successful IoT devices? These devices are usually small, resource-constrained electronics designed to sense, collect, send, and/or interpret data. Some of the devices need to be smart enough to act upon data in real time, 24/7. Specifically the guests will discuss sensors, security, and lessons from IoT deployments.