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That makes sense, but I don't see any zero current lines on any of Aquion's discharge curves for the S20 stack. I guess one could try to estimate it by examining current discharges at 2,4,6,8, & 10 amps.At first guess, I would say that the internal resistance should be pretty symmetric between charge and discharge (not all chemistries do this, of course. Non-rechargeable batteries in particular
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That means that you can just take the difference in voltage between the zero current line and the current you are interested in and add that difference to the zero current line instead of subtracting.
In the case of flooded lead acid cells, this method is reasonably accurate as long as the terminal voltage does not go above the gassing voltage. At that point another parallel current path becomes available which is not present during discharge.
It would also be interesting to see how the charge acceptance tapers off as the stack approaches full charge, and to see what the recommended "absorb" voltage is.Leave a comment:
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At first guess, I would say that the internal resistance should be pretty symmetric between charge and discharge (not all chemistries do this, of course. Non-rechargeable batteries in particular).
That means that you can just take the difference in voltage between the zero current line and the current you are interested in and add that difference to the zero current line instead of subtracting.
In the case of flooded lead acid cells, this method is reasonably accurate as long as the terminal voltage does not go above the gassing voltage. At that point another parallel current path becomes available which is not present during discharge.Leave a comment:
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I am concerned with more than predicted cost. Inhaling fumes from my backup generator and listening to it and maintaining it, for starters. I wouldn't be using solar electricity AT ALL if my decision was based solely on cost - I would find a location on grid.
Their specs have been a moving target. If you find the internal resistance published, please let us know. There was an Aquion person lurking here - maybe they would be kind enough to post it.Leave a comment:
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The belief that it will work for me is based solely on specs that Aquion has released about their batteries. I have yet to see real feed back from users of this battery.
However, if all the specs they post hold true, especially considering cycle life and predicted cost reductions, then they may just be the best option. That is yet to be seen.
The best option is the one that costs less in the long run! At the same time the AHI batteries are environmentally friendly and require no maintenance.Leave a comment:
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I am a newbie, but I think you are on the right track. northerner believes firmly that the AHI will fit his off-grid application. Just as firmly, I believe it will not fit mine.
I find the flat charge curve of LFP very attractive, but others don't. There isn't a lot to think about, other than staying away from the two ends. I need the fast charge time for my location. I like the low weight. The cost, as long as it isn't way out of whack, isn't so much a criteria for me. I agree totally with your statement of "understanding and wanting particular battery characteristics," and it applies across the board for all chemistries, from what I have seen so far. Of course, there is another route of just going out and buying large batteries at WalMart, if you like to fly by the seat of your pants.Leave a comment:
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But for grid stabilization you really need to be able to deliver a significant portion of the battery energy in a few hours, at most 12 hours, and recharge on that same time scale.
Unless the battery bank is so massive that you are only ever using 1/40 of its capacity per cycle, I do not see the point.
On the other hand, if you do not care much about cyclic energy efficiency, you could choose to pull higher current from the battery bank and accept as much as a 50% voltage drop provided you care most about short term stabilization and have output conversion equipment that can tolerate a wide range of input voltages.
That is, if you are willing to accept a voltage sag of 40% instead of 2%, you would be able to use a C/2 discharge rate. That is probably good enough for a voltage stabilization application. For the charging process you could limit it to C/12 or even C/20 and have a useful recharge in the stabilization application.
For comparison, I have seen statements that pumped water storage has a cyclic efficiency of 50% or lower, so there may be a place for a storage system that can be deployed anywhere, with the option of a relatively small and inexpensive system size.
Maybe.....Last edited by inetdog; 01-15-2015, 04:05 AM.Leave a comment:
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Good to have a definite answer. The AQ in aquion is basically water as the electrolyte, so no SEI growth like there is with LFP. Makes sense since Prof J. Whitacre moved beyond LFP, where the organic solvent is a highly guarded corporate secret in most other LFP batteries. Note that GBS says that their LFP electrolyte is the least toxic of all, what little there is of it in the cells.
Back to Aquion - from the start they never intended these batteries to be EV or even general purpose replacements. The major market seems to be grid-stabilization, and perhaps we are shoe-horning it into our application.
I think it is pretty neat - but like LFP, you've got to really understand and want those battery characteristics to fit your application.Leave a comment:
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Based on Sunking's post, and the discussions elsewhere here of my consideration of AHI, then FLA and finally LFP batteries for my off grid design, I decided to create a chart comparing the key statistics of these chemistries. Some of the data is estimated, some is a range for that particular chemistry if the spec was not available, etc, as noted. If you see errors, please comment. Personally, the data in this chart helped drive my decision to go with LFP from these three options for my needs. Your application may vary.Leave a comment:
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