Quoting mham001 (Reply 122):

Fantastic, thanks. My batteries have somewhat different properties. Mine actually have a higher rated voltage as well as nominal voltage, though the charge - cutoff range is similar 12volts v. 11volts.

I'm a bit confused about what numbers are used to specify the rated voltage of the 787 battery...I assume since they use 8 cells for 32v, they're using what I assume is the charge voltage of 4.0v/cell. If that's how they are rating these batteries, it would take 8 of my cells, (I use 'my' for convenience's sake...I'm not taking credit for the cells themselves), in series to give 33.6v. 6 of these 8 cell sets, (in parallel), would make a 60 A/hr battery pack...7 sets would make a 70 A/hr pack, effectively straddling the current 787 pack...(from what I assume...).

The setup I have is very conservative. I charge at 0.2c (2 Amps) and have a maximum continuous discharge of 1.5c (15 Amps). The motor, controllers and chargers I use are safe for other li-ion types so vaIues are set at a safe level for the least robust battery chemistries. I assume the maximum charge/discharge rates are similar to yours.

So a configuration of 6 packs of 8 cells each, (without any containment), would be, (in one configuration);

H - 11.1" (284mm)
w - 5.9" (152mm)
L - 4.8" (123mm)

Seven cell sets would be larger but probably still fit into a 1 cubic foot box.

The weight of a 60 A/hr pack would be 24kg...a 70kg pack would be 28kg. These are just cell weights; containment not included. 8 x lvp65 cells weigh 22kg.

The LVP65 data is from the link rcair1 provided. There is a very good chance some of my figures are off or just wrong. Feel free, (if one feels so inclined), to double check. I'd rather know the facts than pretend to be right. I have fat fingers and am easily distracted by shiny things.

Hopefully this is somewhat interesting, (it was to me). All are invited to edit to their heart's content.



JoeCanuck's LiFePo4's

Dimensions inches(mm)

Measured

Case size - 18.5(470) x 3.0(76) x 3.25(82.5)
Battery pack length (inside case) - 14.0(356)
Cell size - 2.8(71) x 1.5(38) x 1.6(41)
Cell weight - 0.5kg
Cell voltage - 3.6 (4.2-3.0)
Charge voltage - 42 @ 2amps.
Discharge cutoff - 3.0v
Cell capacity (Ah)- 10

Calculated

Specific energy wh/kg - 72
Energy density wh/l - 324


LVP65

Voltage 3.7 (assumed range, 4.0 charge voltage - 3.4v drain cutoff)

Capacity rated 65 Amp/hr
nominal 75 Amp/hr

width 132
thickness 50
height 178
weight 2.75 kg

specific energy wh/kg 2.75
energy density wh/l 232

Max charge rate (ca) 1.0
max discharge rate (ca) 5.0

[Edited 2013-01-30 17:17:13]

It seems that B is having at least one path that may work and not require the long lead times of a new battery and changes to the electronics, also the way Cessna and Airbus seems to have taken:

http://www.king5.com/video/featured-...87-battery-problems-189115821.html

"Sources say that Boeing is seriously considering a better containment system that solves both the collateral damage to other sensitive equipment and deals with the smoke better. The plan is to build a stronger and larger containment box or dome around the battery, and vent smoke and potential debris overboard through a hose or other channel. "

This ideas was also discussed here upthread.

Hello
Thank you all, JoeCanuck, mham001

Cessna had a 18 months homework for its not new (same technology) reinforced battery. In these 18 months, how much can be induced by the fact that is was novelty for FAA ? How long will it take today for the same task ? It might be quicker.

The new containment will be larger. Where will boieng put it ? Is there any pictures of the forward Avionic bay ?
Changing venting routing, separating air flow from batteries from the avionic air flow suppose an new outlet I think? And suppose to reconfigure the air flow management system.
Nothing trivial in fact.

By the way LiPo seems to be a good compromise and a cheap one (price vs Li-ion technology is lower I think) but that's another subject.

In the end, Boeing's statement on the 2012 earning conference seems to have been written before the grounding...

Have a good day

Regarding the choice of Tesla to use thousands of smaller cells: quite some time ago I went to a talk hosted by a guy from Tesla for a group of mostly solar car nerds. Since we use various forms of Li-ion cells in our packs this topic was of interest and the question of why so many small cells was raised. The answer was that it was an economic decision since smaller cells were mass produced already for a large number of devices so it was a far cheaper way of building such a high capacity battery.

The ability to separate cells may have been a secondary factor, but it also brings with it many more opportunities for failure and that many more cells for the BMS to look after.

Quoting ferpe (Reply 124): It seems that B is having at least one path that may work and not require the long lead times of a new battery and changes to the electronics,

Same article I just discovered on Leehamnet.
The interesting excerpt : " Boeing CEO Jim McNerney did not talk about solutions, but said the company planned to stick with the controversial lithium ion batteries as the best option for the plane."
Doesn' t that mean that in fact, "they" think the incidents were due to manuifacturing defects / quality control and that doesn't change the validity of the Lion technology ?

Thank you all for all the infos you give to this thread : I'm learning a lot, and it's humbling as I thought I was on top of aircraft technology. Now I really understand that there was a lot more to the 787 than the over-hyped CRFP construction.

Quoting Aviaponcho (Reply 125): The new containment will be larger. Where will boieng put it ? Is there any pictures of the forward Avionic bay? Changing venting routing, separating air flow from batteries from the avionic air flow suppose an new outlet I think? And suppose to reconfigure the air flow management system. Nothing trivial in fact.

As I understand it, the containment vessels for the four Li-Ion batteries on the A350XWB are directly vented to the outside so leaking electrolyte and smoke/fumes do not escape into the EE bay (at least in any serious amount).

Such a system would mean Boeing would not need to significantly enlarge the containment vessel of the 787 batteries because they would no longer need to hold the material - it would be vented to the outside.

And I don't see how it would materially impact airflow in the EE bay. During normal operation the internal venting would be closed (so it would operate like the current system does) and when it does open, it's not going to be some giant vacuum pump.

Quoting Stitch (Reply 128): And I don't see how it would materially impact airflow in the EE bay. During normal operation the internal venting would be closed (so it would operate like the current system does) and when it does open, it's not going to be some giant vacuum pump.

Ok, but I am just not sure you can just bore a couple holes for the two battery vents in CRFP.

Quoting tdscanuck (Reply 106): -Transformer/rectifiers change this to 28VDC to power the DC loads, including the battery chargers

Doable but would seem unusual to charge a battery needing a charge voltage of 32vdc off a 28vdc buss. Just do not know the architecture.

Okie

Quoting okie (Reply 129): Ok, but I am just not sure you can just bore a couple holes for the two battery vents in CRFP.

Sure you can. The plane has plenty of holes drilled into it for other things (potable water, fuel, sewage, air flow, etc.).

Quoting Stitch (Reply 130): Quoting okie (Reply 129): Ok, but I am just not sure you can just bore a couple holes for the two battery vents in CRFP. Sure you can. The plane has plenty of holes drilled into it for other things (potable water, fuel, sewage, air flow, etc.).

I'd think the most you would need is a thick spot where you made the vent. Maybe nothing but the fitting if it's a low load spot. We use liquid acid batteries on our ships that have a very simple vent to keep air constantly flowing around and out.

Thanks for the photo Stationblue. But, isn't the 787 battery only about 2 kwh? My comparison was poorly worded. I should have said a Tesla type battery of 787 battery capacity. The numbers I see around the internet come in at Tesla batteries being about 50% heavier than 787 batteries per kwh.

[Edited 2013-01-31 09:25:47]

Quoting Stitch (Reply 128): And I don't see how it would materially impact airflow in the EE bay. During normal operation the internal venting would be closed (so it would operate like the current system does) and when it does open, it's not going to be some giant vacuum pump.

Hello Stitch
The piping work will certainly be easy.
But you must be sure that you won't vent smoke from the forward Avionic bay in air conditioning air-scoop, or other air-scoop
You must be sure that you're not venting electrolyte in the same airscoop
You must monitor this system, and make sure you won't go at FL35 with the vent open ?
You must set up maintenance guidance
And so on
Isnt'it ?

A simple and robust solution for sure, but not so trivial I think if not build in

Thank you

[Edited 2013-01-31 13:24:11]

Boeing seems to be standing by the Lithium Ion battery for now but I think it's a lost cause. that battery is not ready for Commercial Airline use and unless they come with a miracle for Boeing and the airlines are in a position to Lose ETOPS authority completely! Then the 787 will be nothing more than a carbon Fiber 757. They can come up with a retrofit to install 2 Nicad's fwd and 2 nicads aft. The weight penalty is negligible. They KNOW what they can do, What they want and what they Will do is the Story.

Quoting Aviaponcho (Reply 132): A simple and robust solution for sure, but not so trivial I think if not build in.

The front EE bay already has an outflow vent for smoke and a drain plug for electrolyte and other liquids and they don't put material into the Pack Scoop, so I would just route the plumbing to vent right next to them and problem solved.

If they can mess with the container without screwing up certification, I wonder if they might be able to make it a few inches bigger in order to put barriers between cells and prevent fratricide.

Quoting Stitch (Reply 134): The front EE bay already has an outflow vent for smoke and a drain plug for electrolyte and other liquids and they don't put material into the Pack Scoop, so I would just route the plumbing to vent right next to them and problem solved.

Agreed, and I think they just file an for an expedited STC or being the OEM, do they need to file an STC or just amend the type certificate?

Quoting okie (Reply 129): Ok, but I am just not sure you can just bore a couple holes for the two battery vents in CRFP.

You can. And the lord said...let there be titanium doubler plates...

Quoting strfyr51 (Reply 133): that battery is not ready for Commercial Airline use

If you mean *that* battery, the evidence seems to point that way. The evidence for lithium-ion, in general, for commercial airplane use is well established though, so it's not the technology that's particularly the problem.

Quoting strfyr51 (Reply 133): and unless they come with a miracle for Boeing and the airlines are in a position to Lose ETOPS authority completely!

I don't think ETOPS is really an issue...nothing about the battery is particularly tied in to ETOPS (the battery can't power the airplane for ETOPS durations). The plane will either not fly at all, or it will fly as designed. There's no reason to end up in the middle.

Quoting Humanitarian (Reply 136): Agreed, and I think they just file an for an expedited STC or being the OEM, do they need to file an STC or just amend the type certificate?

It can be either, but normally it's an amended TC.

Tom.

Quoting tdscanuck (Reply 137): If you mean *that* battery, the evidence seems to point that way. The evidence for lithium-ion, in general, for commercial airplane use is well established though, so it's not the technology that's particularly the problem.

The crumbs seem to be leading a trail back to the cell manufacturer from what I can see with the public information available.
Whether it is a QC issue with materials or manufacturing process issue I would not know.

The question I would have if Thales went to another cell manufacturer what would be the time frame of the approval process.
or
Could Boeing use another supplier other than Thales with another cell manufacturer and get approval quickly.
Would FAA just consider a Li-ion battery is the same regardless of manufacturer?

You are correct about the Lithium-ion technology, it is here to stay.

Okie

probably another unanswerable question, however the other 48 planes out there, have the batteries been removed, are they being monitored.?.. will some cleaning person leave a lavatory light on and drain them ?

Quoting Stitch (Reply 134):

Thank you Stitch

All right, but then can this vent still be use for venting the avionic bay ? You still need to vent the forward EE bay don't you
?

Quoting okie (Reply 138): The crumbs seem to be leading a trail back to the cell manufacturer from what I can see with the public information available. Whether it is a QC issue with materials or manufacturing process issue I would not know.

The cell inside a battery itself is a relatively simple chemical process, however it is integrated into a part that probably includes a housing, and some electronics. A perfect cell will misbehave if it is put outside of its design tolerances, this include voltages, currents, and temperatures. Monitoring temperature in a Li-ion cell is critical, and may require physical barrier between cells within the battery assembly to prevent and absorb excessive heat.

Quoting okie (Reply 138):

Thales didn't build or design that particular Lithium Ion Battery, the Company is GS Yuasa out of Japan. They designed it for light weight and ease of Maintenance (they Claim) I believe Boeing should have second sourced the Lithium Ion Battery or resort to 4 Ni-Cads and go beyond the 32VDC as an Overkill until a new Battery can be found that Doesn't seem to lose it's cool, 4 v.DC from a cell is a pretty tall order Most Ni-Cad Batteries carry 1.4v.DC reliably so 2 ea. 18v.DC with
36-40 Amp Hrs in the fwd and aft compartments should do nicely.

Quoting strfyr51 (Reply 142): 4 v.DC from a cell is a pretty tall order Most Ni-Cad Batteries carry 1.4v.DC reliably

The voltage per-cell is a function of chemistry. Something near 3.7V is normal for most of the Lithium Ion variations, just like 1.2V is normal for a NiCd cell. You design your battery with the right combination of cell sizes and array layout (number of parallel and series lines) to meet your desired output voltage, output current and capacity, and those tradeoffs are different for different chemistries.

So if the battery were redesigned with half-sized cells, for example, you'd end up with 16 cells arranged in a two-parallel/eight-in-series array, with each cell still putting out ~3.7V, but only half the current.

I'm wondering about using the APU battery for ground power and whether anything is different about battery monitoring and lockouts/shutdowns/safety procedures than it is in the air. I don't believe anyone has addressed this in either thread, though it's a lot of posts!

Does using the APU battery for ground power activate any of the aircraft's safety systems for the battery? Do any computer functions power up besides monitoring refueling/fuel door or activating position lights that have relevance to battery safety? Does the aircraft monitor voltage and imbalances and shut the battery down automatically if it has a risk of runaway or other problem? What would happen if it did -- any risk of spilled fuel or damage?

If so I don't understand how one can use the APU battery on the ground for "too long". Isn't there a battery shutoff if the charge becomes too depleted? How could simply using the battery for what it was designed cause multiple battery failures, and lead people to think that misuse of the APU battery on the ground may be implicated in battery problems? Again, I'm not involved in aircraft certification at all, just a private pilot, but I can't imagine Boeing would simply say to its customers "don't use this battery for more than x minutes at a time or it will cost you $16,000".

I'm no expert, and I'm not trained in using fault trees, just trying to use some logic here. Thanks.

Quoting bradmovie (Reply 144): I'm wondering about using the APU battery for ground power and whether anything is different about battery monitoring and lockouts/shutdowns/safety procedures than it is in the air. I don't believe anyone has addressed this in either thread, though it's a lot of posts!

I don't believe the APU battery is used to power anything other than the APU start.

The Ship's Battery (the main battery under the flight deck) is the one that can provide ground power to some systems if no other ground power source is available.

Quoting Stitch (Reply 145): I don't believe the APU battery is used to power anything other than the APU start. The Ship's Battery (the main battery under the flight deck) is the one that can provide ground power to some systems if no other ground power source is available.

I also think this is true. Every other Boeing works this way. It is a redundancy factor. If you kill the ship battery you can still attempt to start the APU and get it's generator running. Starting the APU really cycles the APU battery. I don't know how many start attempts you get just of the battery without recharge, but I would bet three maybe four.

Quoting dalmd88 (Reply 146): Every other Boeing works this way.

Not every!
The B737-200 and 300 have a single battery that does both functions.
The B737-400 had the option of a second battery. This was usually dedicated to APU start, but was located in the fwd EE bay. But in the emergency case where the battery was supplying standby power, both batteries were paralleled together. The APU battery is not on the MEL, both must be serviceable for dispatch.
Seemed strange to me. The second battery was an option, not fitted to all B734, but was not on MEL.

Quoting strfyr51 (Reply 133): Boeing seems to be standing by the Lithium Ion battery for now but I think it's a lost cause. that battery is not ready for Commercial Airline use and unless they come with a miracle for Boeing and the airlines are in a position to Lose ETOPS authority completely! Then the 787 will be nothing more than a carbon Fiber 757. They can come up with a retrofit to install 2 Nicad's fwd and 2 nicads aft. The weight penalty is negligible. They KNOW what they can do, What they want and what they Will do is the Story.

Cessna and Airbus are going to keep the Li batteries as well... its going to be fine.

Quoting tdscanuck (Reply 137): I don't think ETOPS is really an issue...nothing about the battery is particularly tied in to ETOPS (the battery can't power the airplane for ETOPS durations). The plane will either not fly at all, or it will fly as designed. There's no reason to end up in the middle.

Its the fire and containment issue that's going to cause the ETOPS issue - if one runs away while over the South Pacific between AKL and SCL, the only way to make it stop right now is to land in the ocean.

I think its solveable, but there has been definite rumbling of ETOPS issues.

NS

Quoting strfyr51 (Reply 142): Thales didn't build or design that particular Lithium Ion Battery, the Company is GS Yuasa out of Japan

I am aware that Thales out sourced the battery to GS Yuasa.
The battery carries a Thales part number on every picture Okie has seen.

I am back to the original question can Thales move to a different cell manufacturer and not have to go back through a major certification process.

I guessing you can change batteries in other aircraft from different manufactures without a whole lot of hoops to jump through.

Okie