Multiple Rapid Charging / Charging concerns & why I wouldn't buy a 39kWh Kona Electric

Hi Nigel, rapid charging of a cold battery will be severely limited. In my Tesla 90D on a cold morning I can only get 29kW rather than 94kW until the battery is thoroughly warmed up. Regen braking is reduced for the same reason. David

Hi Nigel
I haven't done multiple charges on my 40KW leaf but on a normal fast charge it does about 43KW while below 50% state of charge and after that it starts to vary
As a rule of thumb if you took the state of charge% number and add it to the KW/h charge rate they will total 100
So at 60% charged you will be getting 40KW/h -- (add together 60+40 =100)
and at 70% charged it will be getting around 30KW/h
at 80% charged you get around 20KW/h
at 90% around 10KW/h
You get the picture. So you would need the patience of a saint to get to 100% on the rapid charger
I always push off somewhere North of 80% :)

If a 39Kwh capacity battery is charged at the same rate as a 64Kwh capacity battery, it will be being charged at nearly twice the energy/battery cell as the larger battery. This is why the 39KWh battery will have lower KWh charge rates. When the 39Kwh battery is charging at 46KWh that's 1.1xC/Kwh. When the 64Kwh battery is charging at 46KWh that's only 0.7xC/Kwh. (C is the batteries Capacity) As both size batteries have the same 54 mins charge to 80% figure then the Charge rate for the smaller battery has to be less than that for the larger.
I think the slower rates are the BMS doing its job and protecting the battery cells from charging too fast.
I wonder if this demo cars battery has ever been charge to 100 percent (and given time balance cell voltages)

This is very good to know. Thanks for delving into this. I am planning to buy a Kona Electric when they are released in Australia later this year and was wondering about which one to buy.

So, you discovered coldgate on the Kona! Well, relative to the battery capacity, 40kW is a faster charging rate in the 39kWh than in the 64kWh. Charging batteries in cold weather can be damaging. It all makes sense, except we expected the Kona to turn on the battery heater and perform well as the Ioniq does, with an even smaller battery. Thanks for the honest videos.

So much for CCS. Think I'll stick with my Zoe Q90 as I got 24.8 kWh in 45 mins at Southwaite Southbound on October 16th. Admittedly, this was after driving 110 miles limiting myself to 60 mph. And there was me thinking my poor 43kw AC charging car was inferior. At 15k miles thus far I find driving it a long distance first helps that charge rate massively.
Thanks for that video as it was really informative.

I think you’re right here that not knowing fully what the car is doing and not knowing fully what the charger is doing is unhelpful. I recently got 46kW at high 60% SOC on our IONIQ then 30-ish at 40% on the same charger a day later. Lots of variables and not a very transparent end user experience for us, all in all, as you say :)

Great work you're doing look forward to every blog thanks. I'm getting a better understanding of owing and running an EV now and that on average that the Kona will travel 4 miles per one kilowatt of storage so the range is approx 4 X 64 = 256 miles. So another consideration has become evident ( for the potential buyers) using the Kona as a bench mark if I may, say the cost to purchase is approx £30000 for the 64kwh divided by the range then that figure works out to be £117 per mile, so that's the purchase price bench mark I'm using here, now compare that against say the Jaguar Ipace of £64000 and a range of 234 miles then the figure is £274 per mile. Think you got a great car and deal there and will now be judging future EV car prices on this formula as a basic guide as value for money.

Hi Nigel, I do like your video's, You do all the shit i'm interested in and can't be bothered to do myself.
By the way, I picked up my Kona Wednesday and loving it, If I get time I will pop over to an Instavolt charger tonight and see how it does, not a great test as it will be on about 50%. With normal driving with heater, i'm getting 4.2 mpkwh, But have some long trips next week so will keep you updated if interested.

The first thing that you've said where my Zoe has an advantage is that the heater is pretty good in the Zoe. The fans are really loud in the Zoe too, louder than the engine in a modern petrol at tick over I'd say. The Zoe pulls a consistent 22kw up to a bit over 80% then it slows a lot. I'm not sure charging speed matters so much once the range is over 300 miles because the need to fast charge will be such a rarity, you definitely have the right car with the 64 kwh model.

As you pointed out these kinds of tests are a little tricky because of all the parameters. I wonder if the cooling fans are used to cool the bms. I thought the batteries are liquid cooled but I could be wrong though the fans may push air through a radiator. In any case something like leaf spy would give a better understanding of what’s going on.

As a ball park :
Batteries for cars are constructed in banks, and in each bank the cells have a standard in-series and in-parallel set of single batteries. For a particular make of battery then each bank of battery can be charged at a maximum rate.
A small battery (39kW) will have a number of banks - lets say 4.
A large battery (64kW) will have more banks - lets say 7.
(yes those number don't work, but hopefully you get the idea.)
The motors used are designed to be used at particular voltage, so a large battery has the banks in parallel - so you get more current - but no more voltage. Since the larger battery has more banks in parallel - you can change it faster, and you can get more amps out of it (power).
The smaller battery car will charge slower, and have less acceleration.
The larger battery can be charge faster and the car can be make to accelerate faster.
The two cars can be charge in the same time (approx)- since the larger battery can be charged faster - more amps - since the banks are in parallel, and the charge rate for each bank is the same.
Batteries really don't like to be discharged and they don't like be over charged, and for those in cars the battery management will attempt to protect the batteries
1) It will warn you when you get low in charge, and reduce power at very lower power and will not tell you about the reserve
2) It will only charge at full power up to 80% charge : and that depends on the charger and on the temperature of the battery
3) above 80% the battery management will reduce the charge rate - to protect the batteries, and above 90% you will get very low rates, and about 98% it will be a trickle rate - or they will fail in a bad way, and you don't want to be in the car when that happens.
4) Batteries hate the cold - and if the batteries are cold the battery management will reduce the charge rate, same with the heat (hence the charge-gate)
5) The Kona battery (large one 64kW) will charge up to about 100kW, but in the UK we have a crap changing system, so a lot of the differences will be down to the crap chargers. The kona small battery will take a smaller rate, but should go up to 50kW.
I agree that the 64kW Kona is a ground breaking car and the better than the 39kW and I hope it makes Hyundai a lot of money as the other car manufactures just don't get it.....
And if you are not bored yet : one final bit of technical detail
Although car batteries and phone batteries are Li-ion the tech it different. In phones, the battery is designed to have a high charge-weight capacity (we like lite phones that last a long time), but the batteries won't last long 1 to 5 years depending on how you use/abuse them. Ie if you discharge and charge to 100% every day - expect 1 year, if you keep 20% to 80% you will get 5 years. The battery management is minimal - you have to do it manually.
Car batteries are heavily managed (you are sitting on a lot of energy - going wrong is not an option), and use tech that is designed for long life, not for best weight. Tesla statistics have shown that their car batteries have 90% capacity or better even after 10 years and for most other companies you should expect the same lifetimes - certainly from Hyundai.

I heard of a man who traded in his long range 64kwh kona for a short range BMW mini ....now that's a puzzle.

What you are seeing here is a cold battery charging issue which is expected, once you warmed it up you got normal charge rates, in a real test you would start out with 100% drive for a least 100 miles heating up the battery and only then rapid charge, does the Kona not have battery temp readout, very poor if it doesn"t.

BMS never switches off. Always cools and cools. Passive cooling (liquid just circulates) when very warm and active cooling (liquid is also cooled with AC compressor) when too warm.
With bigger battery, charging rate (C-rate) is smaller in case of 50kW charger. So 25kWh battery charges at 2C on 50kW charger and 50kWh battery charges at 1C with 50kW charger. The slower the charge rate, the better efficiency, the less heat loss there is. Therefore less cooling needed.

Very good video with interesting results.
What’s strange: so much noise from BMS cooler for so little charging power.
The 39kWh Kona seems to be less capable than the 28kWh Ioniq. That’s surprising...

That noise happened to me the other day just reversing out of my garage. I had not heard it before and I thought something has gone wrong with the Kona. Glad I now know it is the BMS fans and yes they are loud.

In the same way that high battery temperature reduces charge rate, low battery temperature will certainly result in a low charge rate.
Presumably the BMS is programmed with charging rates related to battery temperature and it acts to prevent the battery overheating, but does it have the capability to heat a cold battery so that it can handle a higher charge rate?
To do that, the liquid flowing through the battery pack would need to pass through a heat exchanger, external to the battery pack, to be be either heated or cooled depending on the actual battery temperature. I had presumed the fans were simply blowing cool air over some sort of radiator that the liquid passed through, resulting in the liquid being cooled, but it may be that there is some sort of heater in the system so that the fans can blow warm air over the radiator to heat the liquid.

I think the rate of charge is normal for an electric car - slow at low SoC then faster, then slower from 80% . The estimated time on the electronic to charge may be misleading. A smaller battery or the design may not dissipate heat as well as the bigger battery in the 64kWh. I assume you were the only car using a charger i.e not sharing the stall with another car.

It's my opinion that the batteries are made and supplied by two different manufacturers. The 39kWh by SK Innovations and the 64kWh by LG Chem and both having different BMS and possibly the SK Innovations BMS version may be over protective, similar to the AESC Nissan 40kWh battery even though the Kona 39kWh has active cooling? Mind you some of the loud fan cooling noises being made whilst charging are a concern and I certainly would not be happy if I had to endure that noise, especially as the 64kWh is near silent when charging. Looking forward to your 64kWh same comparison test.

Interesting experiment, Nigel. I think what you have proven is that there is no point planning a 'splash and dash' top up on a cold battery. They also can take some time to warm up to a temperature where they will charge quickly. Zoe owners with the 43kW charge option often find they need several miles at 70 mph ahead of the charger to get a decent rate. You may have seen the videos where Tesla Bjorn says you should always supercharge your Tesla the night before a journey while the battery is still warm from that day's driving, not wait until the morning, as rates will be substantially lower with a cold battery.
I also wonder whether the pack voltage may have some effect on the differences you see. The 39kWh battery is 327v and 64kWh 356v. So a lower current is needed for the 64kWh pack to deliver higher charge rates. I also think that driving with a 150kW motor on the larger pack vs 100kW on the smaller may enable the larger pack to get up to temperature more quickly as you drive too, especially if you drive in a 'spirited' manner.
Finally, is the larger pack liquid cooled? I wonder if that is why you get more fan noise from the smaller pack, which I understand is air cooled.

That's a great review again Nigel; thank you so much for your efforts. Can I just ask; when you are parked on rapid-charge can you use the cars main heater to warm the cabin? and the same question when you are on a slow charge, i.e. 16A + 32A. Much appreciated my friend.. Happy EVing..

This is gonna be a long one, so bear with me Nigel..
As you probably know, I've done some testing with my -13 Leaf, had it since march -15 and drove approx 50'km now. Wanted to look into the Ø (average consumption) now. And possibly find some other answers at the same time, perhaps battery capacity and its losses..
The old Leaf can stop charging at either 80% or 100%.
I tested chargingloss once in -15, charge to 80%, drive to around 3% and charge back to 80%. Numbers I collect from these early tests are:
From car: SOC, Ø, km driven
From Leafspy: Wh used, kWh remain, SOC. The SOC in Leafspy shows different numbers than car, fully charged is around 97.1% and empty is never tested, but around 10-12%.
For charging that time, I collect numbers from my grannycable (EVI, kohns) with digital display with chargingtime, A, V, and of course kWh. In addition the chargepoint has a digital kWh display.
Collected data in that trip is 110.5km, Ø12.2kWh/100km, 79% to ---% (estimated 3%), LeafspySOC 78.9% to 13.6%, 13,786 wh used,
Charging 15.71 kWh on grannycable, 15.3 kWh on chargepoint.
Ø*km has just 2% diviation from wh used, so fairly spot on.
I end up with 9% to 16% chargingloss.
I also have kWh remain on Leafspy, but there is a setting with wh/GID that may be off, so I wouldn't rely on that too much.
Extrapolated I should be able to charge 20.66 kWh 0-100%, 18.6 kWh usable if we say 10% chargeloss. I believe these Leafs are suppose to have 20 kWh usable, so 18.6 I guess sounds about right.
Then in -16 I did a drivestyle-test. 4 trips of 23km each, 2 with steady speed and 2 with "rollercoaster". Speeds where 30-60 km/h, average around 40 km/h.
Sadly I didn't collect charged power, but all the others I've got. Rollercoaster is simulated best economy for fossil, build speed downhill, slow down going up.
Every trip had of course no use of heater, same setting on everything down to volume on radio, and of course same start-turn-endpoint, and the pairs I tried as good as possible to match average speed.
All numbers correspond pretty good to each other, except one: Ø! (average reported in car).
All trips started with 79% charged, everything reset. Trip 1&3 are rollercoaster, 2&4 steady speed.
Tripnumber 1 2 3 4
SOC end 57 63 58 67
Ø in car 14.3 13.8 13.3 13.6
wh Leafspy 4140 2925 3775 2276
Then I'll calculate the average kWh/100km based on the wh used:
Ø calc 18.0 12.7 16.4 9.89
If I extrapolate the numbers to get total battery capacity, from wh used in Leafspy I get a steady 18.4 kWh.
However with Ø shown in car, I get anywhere from 14.6 to 25.3 kWh.
So clearly, this time the average in car is way off...
And, in that test steady speed uses 30-40% less power than "rollercoaster"..!!
In another test I estimated the regen to be around 90-95% efficient.
The other day I drove down to ---% again, and charged up to 80%. Normally I charge to 100%, but remembering the first test I mention, it would be a good comparison.
Granted, I did get a replacement EVI-cable, so it may read different numbers than the one I got that time. And the chargepoint with display is shut down.
It reported 13.65 kWh (vs 15.7 kWh in same test back in -15). So about 15% less than same result 3+ years earlier. 15% degredation, 16.16 kWh available? It's possible, but really sounds like a lot of degredation...
But then I just unplug, replug and charge to 100%.
79 to 100% 6.88 kWh
So total 3% to 100% is 20.53 kWh.
A few days later I charge 82 to 100%. That reads 4.193 kWh which does not correspond to 6.88 on 79-100%.
Again a few days later, I charge 3-100% with 20.63 kWh which does correspond to the 20.53 kWh total done the week before.
Also if extrapolated the 15.7 kWh 3-79% done 3 years ago, it corresponds with no degredation (actually about 2% better capacity today, but that could be down to balancing and slow chargespeed at the end).
So right here I start to think that something weird happens above 80%, maby only when you've gone under 80% before charging. And, possibly, it's been a long time since I regularly charge to 80, but 3 years ago I normally did.
So I am gonna do some 80%-charges in the near future to see how they correspond.
Lately I've got 3 chargings up to 100, and noted Ø and km at some points along the way. Everytime I noted numbers just when it went down to the noted %. 74% could be 74.0 to 74.9, so I tried to eliminate that variable. I later found out that Ø updates as rare as every 30 second, given short trips it may give a noticable variable. But Ø is at worst within 10% diviation between the trips, so with a few variables here and there I'd say it's fairly constant this time.
But, when I look at kWh charged vs Ø*km, I'm looking at around 30-35% chargingloss..!!
That can't be right, right..?
So what is the true consumption..? The car says 16-21 kWh/100km. Calculating 10% chargingloss from my grannycable, I'm looking at 19.4-26.1 kWh/100km.
We've had around 0C here, and for the 2-6 km each trip, the heater runs hard, so I think the Ø is a bit too kind.
I know preheating doesn't count on Ø, so never used it in these tests, and car is always of during charging.
So it seems the more I test, the more confused I get. What numbers can you really trust?
What I found to be most trustworthy is Leafspy and SOC.
I also ran a "speedtest", going back and forth on a small stretch (about 2km each way) in different speeds (40-80 km/h), writing down wh from Leafspy at given points. After a few runs, I saw it was dead accurate, after the trip down, I could calculate the return within 1% or so.
What gives the diviation then?
The batteryheater? No, it should activate only when the batterypac is below -15C or so..
Internal resistance in battery? Sure there is some. Going to my drivestyletest, loads should be higher in the steady speed-runs because it works harder uphill, thus higher resistance. Internal resistance is not counted, so Ø should read false low. But actually it reads false high.
Slow update of Ø? Probably in the latest test. But again going to the steady vs roller, drivingtime is almost the same and car never shut off during test. After 23km driving, sitting with car idling with heater off, the Ø changes maby from 13.0 to 13.1 the next update, not 15..
And why does wh used in Leafspy seem to be trustworthy, but the Ø in car not? Leafspy does get it's number from the car..
Really, I don't know.. Hope you can give some pointers,

It really would be better if you refrained from trying to just "figure out" why you observe what you observe. When you say it seems to you there's some kind of significant issue, you may very well leave a lot of viewers believing that there is in fact an issue - when neither you nor they know that there is.
Charging is fairly complicated stuff, and there are always many factors influencing the rate.
Just to illustrate, consider the fast charger for a second. It has a simplistic nominal rating for it's maximum power, but an engineer would look at maximum current and voltage separately. Why? Because you charge a battery by applying a voltage to it's terminals that is slightly higher than the open-circuit voltage of the battery, but with polarity reversed, causing current to flow in the reverse direction (as compared to discharging). Current flows according to Ohm's law, U = RI, and the *net* voltage at the battery terminals is basically just the sum of the contributions from the battery pack itself and the charger. So if the pack is at 350V and you apply -352V, you effectively have -2V forcing a current through the battery. It is crucial to realize that R, the internal resistance of the battery, is quite low, and the charging voltage therefore only a little higher than the pack voltage. The consequence is that you're not free to simply jack the charger up to maximum voltage. In this example, if you charge at 354 V instead of 352 V, you *double* the charging current.
So, in practice, chargers are current-limited. Voltage is only relevant in that it needs to go high enough to allow charging - a few volts higher than the target voltage that you want to charge to. Some "50 kW" chargers can deliver maximum 100A and 500V, some can deliver 125A and 400V. The latter are in practice 25% faster (assuming the car can fully utilize it) because 400V is sufficient to charge any EV on the market to 100%. A popular configuration in EV battery packs uses 96 cells in series, for a nominal voltage of about 3.65V*96 = 350V. Depending on SoC, the pack will be at about 300V to 400V, and a 100A charger therefore cannot deliver more than 30 kW at the low end, while a 125A one could deliver 300V * 125A = 37.5 kW.
That's just considering the charger, and I'm sure what I've mentioned is a huge simplification glossing over many caveats and ignoring several relevant issues. What speed you actually get, and ought to get, is a much more complicated question than just what the charger is able to deliver.
Making decisions about that - what charging speed the car would *like* to get - is just one of the responsibilities of the BMS - the battery management system. It isn't a fan, and you can't hear if it is running at not. It should be running at all times, and nothing in this video indicates it doesn't. In fact, the fan itself would not normally be considered a part of the BMS, but merely connected to it. It is really better to think of it as a piece of software that makes decisions for the purpose of managing the battery, although in some context it makes sense to think of it as a circuit board (say, if you are an amateur car maker who wants to use the BMS from an Ioniq in your project).
The point isn't to try to teach you the engineering. Nor could I, and not just because of the limitations of RUclips comments. I only have amateur-level knowledge of some bits and pieces of the relevant engineering. But I know enough to realize how much I don't know, and enough to tell you know significantly less than I do.
So I am trying to offer constructive criticism here. Refraining from guessing the technical explanations doesn't mean you shouldn't test "the technical stuff". Lots of people may not know even the fact that you don't always get the same charging speed, and a test like this makes them aware of the fact. It also makes it clear that it is not as simple as charging speed being a function of SoC, even on the same charger. (My guess, btw, is that you received less power initially on the first charging session because the battery pack was cool. But it's just a guess.)
I am personally interested in the technical stuff and would kinda like to understand better how it all works and what tradeoffs are made, noting how different manufacturers choose different tradeoffs. But that isn't what your videos are about. You've stated yourself that your approach is to "get in and try it", not to "spend hours doing research". That approach works well enough for judging how the product actually performs - it is pretty much the normal user perspective. But just like you shouldn't really state as a fact that car A has a crisper turn-in than car B thanks to its double-wishbone suspension unless you actually know what you're talking about, I think your videos would really improve if you simply stated that you feel car A has a crisper turn-in than car B. It would also eliminate some cringe moments, like when you say "the BMS came on". It just shows you don't really know what a BMS is. While that doesn't disqualify you in any way from reviewing electric cars, it kinda does disqualify you from making judgements about whether the BMS is buggy or "has issues". :)

Wow, that seems much more aggressive tapering than I see on the 40 kW leaf. Weird. Re the heating we've found the leaf is the opposite, we need to turn the heating down. Even at around zero degrees outside if we have it any higher than 17 degrees it's too hot. The leaf seems to charge at 45 kW until around 60% charge and them drops down to around 35 kW. It only drops down to the 20s when you get past 70 to 80%. Wonder what's going on.

Nigel, nice set of videos comparing the two versions. The in-car heating issue is getting frustrating and will probably get worse as the temperature drops. I may have to report the Hyundai.

You should shut the ADFS off in order to keep warm air blowing.....

While it may be possible to set the car up at home to be nice and cozy from the start, once at work, there are not charging options. The issue you have thrown up regarding the temperature settings are of concern. You may say, forget the dial figure and just turn it to where you are comfortable, but to have 'cold' air blowing through should only work in the summer with a temperature sensor facing the windscreen. It would appear that everybody should test their dream EV car in the winter to ensure that it will perform as they would like.
There appears to be more questions about people's expectations coming from an ICE environment and being thrown in to an EV option thinking that everything will be the same. At least with an ICE car, you know it will be cold to start with and once the temperature sensor goes out I(Honda Jazz) you will get heat and the temperature gauge will reflect what you need. I would also be interested to learn about the direction of air flow with all the dashboard, screen and footwell settings. Starting from work (with no charging facility) on a cold winter evening, I would expect to have the front screen, overtaking mirror and rear screen defrost buttons pressed and a lot of warm air ultimately being blown out or elements heated to clear everything up for safer driving.
It still leaves the question about winter driving and impact on range - It is wet, and you need the wipers on. It is cold and you need the heater on. It is frosty and you need the rear screen heater and overtaking mirrors elements on. What range then?
Great video and opening up some tantalising questions.

One question to investigate: I do like to put the car to sport and Regen Level 1. That makes the car feel much lighter and powerful, and Regen Level 1 makes it feel like an ICE with its natural engine resistance. Now, it would be great if I could use the brake knowing all goes to regen if I am gently enough. But I don't know how the brakes work. Do they use regen to the limit and only then they physically brake? Or it is someway more progressive, acting on both at the same time and therefore loosing some energy in heat? I have not seen anyway indication in the console on when the physical brakes do start to work. I see the regen acting but I never saw anything in the console that tells you: Now I am using the physical brakes. It would be great if we knew something more about it, would'nt it?

You noted the heating wasn't very good, do you need the HEAT as well as the A/C buttons on to properly heat the car up? It's not clear in the handbook.

Hello Nigel,
Another reviewer is suggesting that the Kona needs to be all wheel drive as the review I have seen shows that in the wet wheelspin is also impossible to eradicate unless you accelerate very gently, what has your experience found please?

Hi there, we have been watching your channel, and are now very interested in buying one, but have a question for you. Does the insurance work out much more expensive ? Like yourself we have found that most of the garages in England aren't interested and don't have a car to show you. We did find a local garage in Northern Ireland that knows a lot about the car and actually have one that they use and we are now going for a test drive. The only down side is, if we do order, the expected delivery date is next September. Thanks

Nigel. We've got a Tesla and it sounds like a jumbo jet sometimes when the bms cooling fans get going.

I think you are mixing the terms here: Battery managment system (B.M.S.)controls the charge current& voltages to each cell (or paralelled thereof) to equalize and protect them. The noise of the fans obviously is to keep the temperature within limits, and not necessarily part of the BMS.

Have you turned off the ADS (auto defogging system)? I think that is the root to the cold air blowing sometimes even when the temperature is set "high". At least it helps on the IONIQ BEV.

My car tapers a lot when charging on DC. But there seems to be a correlation between State of Charge (what’s in the battery) and the Charge Rate (in kWs). In the 38kWh Kona it seems to be about 90. So take the SoC away from 90 and it gives you a rough expected Charge Rate. eg if battery is at 70%, Charge should be about 20 kW. (90-70=20). At 40% SoC, Charge Rate should be about 50kW (90-40=50). It’s very wet finger but seems to work, and is an indication if the Chargepoint is not delivering rather than the car not taking enough. Might be worth seeing if there is a similar correlation in your 64 kWh Kona. (NB Doesn’t seem to work at the very bottom 15% or less, or very top of SoC, 85% or above)

Good video !
I have Renault Zoe 40Khw and the fans will kick in when the battery starts to get too warm in the summer mostly , but in the winter you hardly hear the fans at all.
I wonder because you tried to rapid charge after only a few miles and it at this time of year like the Zoe the battery needs to warm up first even if the state of charge is low. Does the Kona have a Battery Temperature display like the Nissan Leaf ? I can use Canze software and a OBD2 Dongle device that is plugged into the OBD2 socket to see the Battery Temperature , the zoe like's to have a warm battery pack above 20c and a low State of Charge ( 20%) to get maximum speed on a Rapid , which from 20% to 80% takes around 60mins (program is called leaf spy on the nissan leaf ) In the summer i think the result would have been different also maybe the cooling / warming on the bigger battery is better.
I always charge the car at home the night before in winter otherwise if you charge before the battery is warm the charge speed on a Rapid will be low especially in the winter.

Great vid as usual.
But could you please include cost of charge at these public charge points. I'm currently considering EV as my next car and cost and availability of charge points I think is key to my needs.

I would expect charging on a cold battery will always be much slower than a warm battery. Power output from a cold battery is also lower.
Is there no pre conditioning app that allows you to warm the car up before you go out on cold mornings? That should also heat the battery a bit.

Maybe you can use that thermometer to measure the battery temperature before, during and after charging?

Just to clear a few things up was the 39kwh battery preconditioned in the morning using winter mode? I found this makes a big difference with a cold battery.

Looks like it might operate according to an algorithm, when to charge fast and slow according to temperatures and conditions etc. The longevity is the issue I think. For a lot of people rapid charging is not so much of a problem.
But one thing - what is the normal range of the 39KwHr? If its in the order of 170 miles its still a great little car.

You failed to take into consideration that the charging stations don't supply a constant charge rate. We have two electric cars in our family & have swapped over the charge from one to the other at charging stations, we found that the station would reduce the charge rate as it got hotter & the fans kick in as the station heats up.
We also found some other variables which affect the charge rate. Sometimes the rate would drop for no apparent reason, maybe the charger drawing too much current from the local grid.
I wouldn't buy the Kona for another reason, the PLASTICS, bad enough on the inside but on the outside? Makes the car look cheap.
Glad you mention when things are interesting and very interesting as it's not always apparent ;-)

I see you also hilighted my reasons for wanting heated seats in an EV lol. They are essential in the winter in electric cars and a bare minimum expectation on any car over 15k these days.

I agree with you the IONIQ is a better buy based on your tests. It rapid chargers a lot faster and has no rapid gate issues.so it may not go as far between chargers but quicker to charge makes up the time spent at the charger.

With the HVAC issue, have you tried adjusting the flow balance and direction of the air yourself? If so, that might explain some of the unbalanced air temperatures. I have an Ioniq and used to have that problem. I now just set the temperature and put system in auto mode. I'm toasty warm and the heat arrives much faster than any ice I've driven.

The author seems to be a full on newbie in the electric car area and suffers from the "Range anxiety" syndrome.
It would be useful to understand that charging depends also on the amperage of the charger and the temperature of the battery pack. Those are the two main ingredients. Charging at 120A (or 85A in cities) would produce a lot of heat, hence the "I have no idea what the management is doing" bit - the battery pack is being cooled.
Another tip maybe is that there is no point of charging a cold battery from 5X%, since this is bound to be a really slow charge. Rather leave it overnight at home on 10A.
Sorry I do not speak kWh, I only speak A.

The throttling may be because of grid issues rather than the car. The UK's infrastructure is creaky (close to collapse if you believe some insiders) and cold days with high daytime grid usage will cause power distribution issues. Best to try this again overnight I'm afraid when grid usage is lower. Clearly not Nissan levels of rapidgate though.

Wow that charging seems very low compared to my 30kwh leaf.

Just a few comments.
1# Kona has a heat pump, these are increasingly inefficient the closer you get to zero ambient.
2# I'm not sure about the Jona but the cooling/heating systems are shared in the Tesla. The car takes priority - this could explain why it's cooler
3# I suspect your 64 does/would make a racket but it's quite cold in the UK at the moment - it could be that the car is simply heating up the batteries to increase the charge speed
4# Not all charges are created equally, some may deliver less power than you'd expect
5# Charging speed is quite variable due to SoC, battery temperature, ambient temperature etc.

hi there again we have been looking at hyundia s web site and have noticed the kona ev price seems to have gone up ??? or is it me

Could the Fan be unbalanced? Hear with Hyndai if this is the sound in every 39kW Kona , its just not OK and this Model will taken off my shoplist!

Hi Nigel,
Interestingly the Cheatsheet comparison on the Online site, ev-database.uk, shows that the 39kWh Kona has a 38% lower Rapid Charging Rate!
Regards John (Signpost)

For the anoraks - not very clear - too much time to charge

Hi I have a Hyundai plugin hybrid. It has just had its first service. I have very little mileage using the engine maybe 100 miles or more total mileage was 3400 and the bill for the service came back at £150. When I asked why the had changed the oil and air fillets they said that what is done after twelve months. Do you think this is wrong is the garage cheating the customers by doing this. Should electric cars have a different service pricing knowing they will use the engine less. We keep hearing that electric car should be cheaper to service, well let’s see it.
What do you think out there of this. Have any other plugin or full electric cars challenged there pricing on servicing.

I earlier wrote that the reported average consumption in the (my) old Leaf is not correct (every time). I reset everything the other day, down to about 50% now, if you extrapolate the shown numbers the car would report something like 13-15kWh usable, while the truth is around 18 kWh I believe. Showing around 15kWh/100km average now, I think it should be much higher, driving in around 0C with heater on these days.
Doing the math on your travel here however, it seems alot more spot on. So maby it's only Leaf that can't do this right?
77.7 mi (124km) on 60% extrapolate to 206km on 100%.
17.26 kWh/100km * 2.06= 35.55 kWh That shouldn't be very far off the true usable capacity, right?

Is the 39kwh liquid-cooled? Why would a liquid-cooled BMS require such a strong fan?

If this were my car I'd ask Hyundai to check for a faulty bms. The behavior is too inconsistent. I'd also like to know who the battery manufacturer is. SK Innovations has been mentioned as an additional supplier besides LG.

Just a thought, Under battery care, did you have winter mode off?

Does the KONA have active cooling and heating of the battery? Is the battery getting too cold I wonder?

Since you received low charging speeds for both Konas and received fast charging on the 39kWh on the third charge. Did you ever doubted the charging infrastructure to be the problem, NOT the Kona itself?

Thanks for this instructive video, though I can understand your disappointment. Just a minor remark (since you're using the term so often): when you say Battery Management System, you seem to mean "battery cooling" or what some call Active Thermal (battery) Management. I think the term BMS usually refers to the _electronics_ that controls charging/discharging and is found on just about any Lithium-ion battery nowadays, as a minimum to protect it from conditions that could lead to the batteries exploding. All EV's have an elaborate BMS with which one can communicate via the OBD port.

Not sure if I missed it - only 39kW has problems with cabin heating or both?

With a 39kw Kona on order...I’m concerned. We need to understand what is going on here. My first thought is it’s most likely to be to do with temperature. Hyundai need to make more information available about the charging and BMS processes.

So , can you do this same test with your 64kWh Kona EV?

You are mixing kw and kwh in your video. kw is the rate of charge or discharge(like flow rate of 15 litres/min), kwh is total energy (like liters of fuel).

Awesome stuff! Can you do a charge test your car and the 39 at the same to see if they charge at the same rate on the same charger at the same time? This might show the issue is with the charger and not the car.

No heated seats and a potential rapid gate issue.

Join the club ,Zoe same mad heating, seems a lottery

You're geting very inconsistant results, I think (or I hope) there's an issue with that car, try to report it to Hyundai and test an other one. The BMS seems faulty

Hi Nigel
With luck this might show a graph of % charged in red and the charging rate at that level in blue
For our 40Kw leaf (about 13C)
drive.google.com/file/d/1NMmVRT9l8Ai8WHZJ4ou9frhgwkSpKKBO/view?usp=sharing

That device does not measure air temperature.

Much lower charge rate than Ioniq, they may have been using cheaper cells, a lot cheaper!!

Hyundai rapid gate

Kona gate?