It's not clear (Dahon don't say) which of Bafang's extensive mid-drive motors is actually fitted, or if it's CanBus or UART... the later most desirable if you want to be able to tweak the bikes performance.
I doubt I will. I did research them some time ago though, and established which one it was. But that maybe 7 weeks ago. On the control setup - the hub motor version had a large display, while the mid motor version had a small and mean looking display. Although the small display was easy to use, it was small screen but with big buttons. Both of the e-bikes (hub and mid) have an area for I presume electronic controls. The performance was fantastic actually, and besides increasing the top speed, I didn't feel a need to fiddle with the controls. I had thought that changing to 48 volts would not assist warranty and doubted it would be easy to do on those bikes, and also, would decrease the small battery range. The bikes felt very sprightly though, even on setting one the bike felt quick, and two quite powerful.
The specification is supposed to be a Bafang M400, and when I looked I thought it might be that, a 420, a 420, or even, something completely different. IMO the specs changer according to country. I will report back though. As long as its the same setup as what we tested, I'll be happy.
I can report later when I find out their bad points.
I am curious though about how the top speed is calculated? Because if its from the gears rather than the tyres/wheels, a change in the front sprocket would increase the speed. Both bikes have a very low first gear compared to what our bikes have.
I won't need much range. But the batteries are super expensive. While the NCM bikes have a price of only 225 pounds for their 560 32v 15.5 AH battery, the price for a replacement for the K-one battery which is more than one third smaller, is 316 pounds.
I face this type of issue in my yacht, which is an ocean going racing boat that is setup for single or duel handed sailing. The issue with short handed sailing is that instead of steering the boat yourself, you rely on an electronic autopilot, with wind sensors, an gyro compass, a computer all digesting the inputs and then operating an electrically powered set of rudders. The power usage is a bit over 8 amps of 12 volt power. That comes down to for a bike battery (dividing by 2.6 although that figure is debatable) the continuous consumption in bike battery terms is 3.2 amp hours. That might not sound much but over 30 hours, that comes to close to 100 amp hours. So for that NCM bike, I'd need to have 6 of their batteries. Which would cost of course, 1,350 pounds. And actually, that is a lot less than the lithium I was wanting to install, or the AGM Lifeline 6 volt batteries that I did install. So IMO, those NCM batteries were a great price. Although I don't know much about what cells they use. There is a huge variance in cell quality out there.
I wanted to replace all my "house" batteries with lithium - lithium iron phosphate - batteries, which are non combustable as unlike bike lithium batteries, a lithium iron phosphate battery doesn't produce oxygen when it is radically overheated (which won't happen until around 500 C). So no problem I thought ... but I could not insure the boat, and even if I accepted partial insurance, no electronic installer would install such batteries, due to their own insurance issues preventing them from such installations. Of course all insurers insisted on having lithium batteries installed by approved marine electrical companies. Catch-22.
Sorry for all that - but the electronic guys all said - it is not relevant. What actually matters at sea, is re-charging used batteries. Because no matter how much capacity one has, when its run out, one then has to get the power back in. I could go on at length about various other complications! The beauty of lithium, is that they accept charge at a linear rate. So there is no slowing down of accepting charge, like lead acid batteries do, as their resistance increases, they accept less charge, so they have to endure a prolonged absorption charge. Lithium just accepts all its charge at a fast rate, and at 99.x% it then resists a touch more. And at 90% or 70% charge, lithium does not damage its cells, unlike lead acid which sulphates and starts to destroy itself unless fully charged.
For my main bike usage, the same issue applies. It's about getting the power back into the batteries.
So for me with a caravan, I will have to use its solar power (or a petrol generator) to get the power back in. So a large battery is no real help, except at the beginning. I was looking hard actually for 3 amp chargers. But when I did the math on two chargers for each bike, I thought the bottleneck would be on my inverters (which convert the caravan's battery power to 240 volt) which can run the bikes' chargers.
So for me, efficiency of the bike is important. But we also lowered efficiency with the fatter tyres (for the dirt and grass) plus the guards and rack.
We also tested the bikes with the power turned off, and the bikes didn't seem to have extra resistance when riding. Our current folding bikes weigh 17.5 kg. So the difference is only 3.3 kg with the battery flat. The bikes standard are 2.5 kg heavier, but we added plastic guards, fatter tyres and a rear rack. A hub motor also has a bit of extra resistance with the battery turned off, although in my tests I did not feel that resistance, although theoretically it is there. Free wheeling on a mid motor is supposed to be similar to a normal bike, and logically that is the case excluding their extra weight.
The other issue for us is getting exercise. We want to push the pedals, and get that exercise. Which is probably why we were sensitive to the feel of the bike, which had a very smooth integration of power to human effort => fun factor.
The worst thing about the bikes is that they are not step through. We'd have liked that, but at least they are similar to our current bikes in the horizontal bar support.
