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SAE DC fast charge retrofit?

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I'm not very knowledgeable in this area technically, so here goes:

Would it be possible to retrofit an earlier SAE J1772-equppied car to accept the new SAE DC fast charge coupler?

Supposing you could source the vehicle end connector, would using DC fast charging on a vehicle which was not originally designed for it, fry the battery?

For just one example, if you had the right connector, could you DC fast charge a Think City, without any harmful effects? Or does the battery pack have to be "set up" for it?

Or would it not matter?
 
What would happen? Would it cook the battery?

From my understanding, the SAE DC fast charge standard is simply the J1772 with an extra connector. This way a car set up for SAE DC fast charge (like the new Spark) can still accept a level 2 J1772 connector at the same port.

My thinking was that one could just get a DC fast charge port and hook it up where the existing port is, and there you go, a 5 minute recharge for a Volt.

From your answer I take it that the onboard charger is the issue? If you could explain the "square peg round hole" thing for me on a technical level, I'd appreciate it.
 
From your answer I take it that the onboard charger is the issue? If you could explain the "square peg round hole" thing for me on a technical level, I'd appreciate it.

Any DC charging system bypasses the on-board charger(s) (which convert AC from the EVSE to DC) so the on-board chargers don't enter into the picture. DC charging requires special circuitry to connect directly to the battery. An adapter would have to mimic the Supercharger on the car side and the J1772 DC charger on the EVSE side and might require bulky (and heavy) parts to do so.
 
Jerry, you've confused me (an easy thing to do) with your mention of the Supercharger, which is a proprietary Tesla technology.

I'm speaking of the new SAE DC fast charge hookup, which incorporates a J1772 connector in one unit which can do both Level 2 J1772 charging as well as DC fast charge. I think there's a few extra contacts, and a specific socket?

In any case, if DC fast charge does indeed bypass the car's onboard chargers, then couldn't a sufficiently talented person simply rewire a vehicle-side SAE DC fast charge socket in the place of the J1772 socket of a vehicle so equipped? Since the SAE DC fast charge socket also incorporates J1772, no capability would be lost. From what you say a direct circuit to the battery would be required, if I understand correctly. As I'm theorizing, I wouldn't be needing any adapter at all.

Forgetting for a moment the method in which you would hook up -- Could the batteries in the current generation of EVs on the road handle the current without problems?

If SAE DC fast charge stations take off, you could imagine a cottage industry of retrofitting charge sockets to take advantage.
 
I'm not very knowledgeable in this area technically, so here goes:

Would it be possible to retrofit an earlier SAE J1772-equppied car to accept the new SAE DC fast charge coupler?

Supposing you could source the vehicle end connector, would using DC fast charging on a vehicle which was not originally designed for it, fry the battery?

For just one example, if you had the right connector, could you DC fast charge a Think City, without any harmful effects? Or does the battery pack have to be "set up" for it?

Or would it not matter?
If you want an "easy" SAE DC charging retrofit, the car must have DC charging equipment in the first place! As others have said, the DC charger bypasses the AC charging circuit. The major difference between the two is that a DC capable EV at minimum has high power contactor(s) that can connect and disconnect the battery from the DC port, the onboard charger, and other power electronics. In addition, the car will have beefed up wiring between the DC port and the battery.

For this reason, it'll be much easier to convert a car with a different DC charging standard (for example a Leaf with Chademo port) to SAE J1772 DC, than it is to convert a car without any DC charging.

And having a normal J1772 port isn't going to help you much, because even though the J1772 DC port is backwards compatible in regards to AC (a car with a new J1772-DC port can use existing older J1772 chargers), J1772 is not necessarily forwards compatible (aka upgradeable) esp. with respect to DC. And you WILL have to upgrade the software/charging protocol in the car to handle the new DC protocol (which was just finalized recently). There may also be new hardware necessary to handle the PLC (power line communication) that the DC protocol uses.

Any DC charging system bypasses the on-board charger(s) (which convert AC from the EVSE to DC) so the on-board chargers don't enter into the picture. DC charging requires special circuitry to connect directly to the battery. An adapter would have to mimic the Supercharger on the car side and the J1772 DC charger on the EVSE side and might require bulky (and heavy) parts to do so.
This is very OT, but Tesla is pin-to-pin compatible with J1772-DC because J1772-DC doesn't use the two AC pins when charging in DC. So all Tesla needs for the Model S is a simple physical adapter to work with J1772-DC (just like the small one it has for regular J1772). The only difference is the extra two large DC pins in J1772 DC will connect to the power pin of the Tesla connector (rather than the AC pins), plus you probably can't use the same adapter to charge in AC mode.
 
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... This is very OT, but Tesla is pin-to-pin compatible with J1772-DC because J1772-DC doesn't use the two AC pins when charging in DC. So all Tesla needs for the Model S is a simple physical adapter to work with J1772-DC (just like the small one it has for regular J1772). The only difference is the extra two large DC pins in J1772 DC will connect to the power pin of the Tesla connector (rather than the AC pins), plus you probably can't use the same adapter to charge in AC mode.
Interesting! So a J1772-DC to Tesla-SC adapter sounds could be on the drawing boards already!
 
I'll try and make this simple. The bottom line is that a car can't handle SAE DC fast charging unless it was designed to do so.

Why?

The prior SAE standard was about "level 1" and "level 2" charging which is all AC, not DC. To use fast DC charging, the car needs:

1) to know what to tell the DC charger to tell it how fast to charge, when to slow down, etc. This is a "control protocol". Without this, the charger will burn out something in the car. Essentially the car and charger need to understand a common language. The language for SAE level 1 and 2 charging is different from the language used to control SAE DC charging. DC charging needs a richer control language so the car can tell the charger what to do and when to keep the charger charging fast but so fast that it burns out the car's battery or charging circuitry.

2) to be able to talk to the charger (electrically) in the first place. The car and charger need the moral equivalent of a phone line so they can talk to each other. I don't know if this is the same or not for SAE AC and DC charging. But it doesn't really matter because of #1 and #3.

3) the proper charging circuitry so the car can safely swallow the power sent by the charger. SAE level 2 charging is electrically different from SAE DC fast charging so the car needs different power paths from the charging port to the battery to handle both.

So if the car isn't designed ahead of time to support SAE level 1 and 2 charging and SAE DC charging, the odds are essentially zero that you can practically and safely retrofit the car to do so. The car manufacturer might be able to develop and produce a retrofit kit but the cost to do so would be high enough that it's simply not worth it. The cost to the consumer for the kit+installation would likely be so high that it wouldn't make financial sense.

About "Supercharging":

Tesla's proprietary fast DC charging (aka Supercharging) is supposedly compatible enough with SAE DC charging that Tesla should be able to provide a reasonably priced adapter. But that's because Tesla knew enough about the SAE standard in advance (and probably influenced it) and designed their charging circuitry and control protocol to be compatible. But Tesla has a nicer plug :).

I believe that SAE and Chademo (a competing DC fast charging technology used by the Nissan Leaf) isn't compatible even though both are DC. #3 is probably (close enough to) the same for both. As I understand it, the challenge is #1 and probably #2 -- the control protocols are different enough as is the communication connection that a car can't handle both unless it was explicitly designed to do so. To my knowledge, no car in existence has been.
 
I believe that SAE and Chademo (a competing DC fast charging technology used by the Nissan Leaf) isn't compatible even though both are DC. #3 is probably (close enough to) the same for both. As I understand it, the challenge is #1 and probably #2 -- the control protocols are different enough as is the communication connection that a car can't handle both unless it was explicitly designed to do so. To my knowledge, no car in existence has been.
#3 is going to be virtually the same for all DC charging protocols, since DC charging is basically just a connection from the battery and external charger (with a high power contactor in between for safety and heavy wiring to handle the current).

#1 is not that big a challenge if the charging logic is programmable, plus you can always add a micro-controller to do some "translating" if it isn't.

#2 is the definite big issue with SAE vs CHAdeMO. CHAdeMO uses a CAN bus and some analog control pins for charger control. SAE just uses PLC for charger control. The number of pins (and function of them) are completely different between the two, so a direct physical adapter is impossible.
 
Thank you StopCrazyPP and RCC for explaining that to me, in terms even I could understand!

Based on the size of the battery, how long do you guys think it would take to charge a Volt battery at DC fast charge? I wonder if there are any plans to outfit it for that type of charge?

Now that the SAE DC standard is out, and the Spark is the first to take advantage, I can't think of any reason for any plug-in vehicle made for the U.S. market to not be built to handle this technology. Especially when one can still use the J1772 already in many places.
 
Based on the size of the battery, how long do you guys think it would take to charge a Volt battery at DC fast charge? I wonder if there are any plans to outfit it for that type of charge?
There's two limits you have to consider. One is at the battery and the other is at the charger.

Battery
Almost all lithium batteries can charge at 1C (fully charged from empty in 1 hour). Some can handle a lot faster, I think the fastest I have seen is ~6C (equivalent to 1/6 hours = 10 minutes to charge fully). The "C" number is called the "C"-rating and is the standard way to rate charging and discharging speeds in batteries. You just divide 1 by the C-rating to get the hours it takes to charge or discharge a battery.

The caveut is that the top 80%-100% SOC takes longer to charge in order to avoid overcharging the battery (a good analogy is filling up a bucket with water; you turn the hose down as you get near full to avoid spilling water). That's why almost all companies quote a figure of charging from x% to 80% in 30 minutes (for the Model S, x% is 30%, equivalent to 50% of capacity in 0.5 hour, which is the same "speed" as 100% capacity in 1 hour), rather than x% to 100% in 1 hour. These numbers will generally apply regardless of how large the battery size is.

However, for the Volt battery specifically, the cells inside can probably handle a faster charge than just 1C. The iMIEV with the same size battery (16kWh) can charge from 0%-80% SOC in 30 minutes. The Volt uses only ~10kWh (62.5%) of it's capacity and doesn't let you use anything above 80-90% and anything below ~30%, so it'll probably take a bit less than 25 minutes to charge the Volt with a DC charger.

Charger/Protocol
Every charger/protocol has a set power limit also. For CHAdeMO this limit is ~50kW, SAE is about ~100kW. You just multiply the charge "C"-rating with the capacity to get the power the battery requires to charge at that speed. For example, an iMIEV charging at 2C would take 16kWh*2C = 32kW. A Model S at 1C would take 85kWh*1C = 85kW. As long as the power the battery requires is lower than the limit of the charger/protocol, it'll charge at the fastest speed the battery allows. Otherwise, it'll be limited by the charger.
 
Now that the SAE DC standard is out, and the Spark is the first to take advantage, I can't think of any reason for any plug-in vehicle made for the U.S. market to not be built to handle this technology. Especially when one can still use the J1772 already in many places.
There are many reasons.
The are no cars in production right now that use the standard. As far as I know, there aren't any DC J1772 public charging stations, while there quite a few Chademo stations. Spark is a compliance car, built for California only. The only other manufacturer that has any plans for QC EV' that is to use the DC J1772 in the near future is BMW, and that is scheduled for 2014.

You can have all of the standards you want, but the one that is going to win out, is the one that has the biggest headstart and vehicles on the road.
 
The fact that the J1772 combo connector was a $700. option on the BMWi3 proves that it is not only possible but also not too expensive. We have been working on such a retrofit and should be available soon. I will keep the group posted.
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