Hello, this is my first post. That said, I have read hours and ours of threads on this forum since I started documenting for this e-bike project. I'm posting to show what I plan to use for this project and hopefully get some feedback from you guys since you have much more experience than me on e-bikes.
Hard to say in a few lines, but bare with me:
*the mission profile would be to assist the rider to go up from 25 to around 30-35km/h for 80-100km (15-20mph for 60 mi)
*weight bike + rider without EV ~90kg / 180pounds
*I've used some telemetry data that shows I rarely use more than 400W leg-power, less than 3% of the time (slightly hilly course, around 20km/h average speed). Average power around 250W.
*in regards to energy , an average 1 hour 20km/h tour used some 80Wh. For the EV at 48V this would only be under 2.5Ah if I take some 80% efficiency for the motor, 90% inverter and 90% for the battery pack.
*ran a mission profile of a slow acceleration from 0 to 20km/h in 20seconds electric-only - maximum DC current 4.5A @48V
That said, it looks like I don't need much power or torque, but I want to overprovision as there's little mass or $$$ penalty if I pick beefier inverter and motor. I was thinking of:
*Kelly 24-48V 30Amp Inverter @1.7pounds link:
http://kellycontroller.com/kbs48051el30a24-48v-mini-brushless-dc-controller-p-1170.html
==> this gives a peak 1.5kW @VDC_min; probably it depends on the temperature and one won't always be able to safely pull 30A
Pluses:
-configurable DC current limit. I intend to use this setting to tweak the power / range. Will use this setting to cap max DC current pull from the batteries.
-recovery configurable between 0-20% of torque; it's going to be a RWD bike, so recovery may interesting. Will increase recovery torque until it becomes annoying
*800W 48V Kelly hub motor @they say 27lbs (has to be a mistake, right? It seems like a lot for a motor)
http://kellycontroller.com/hub-motor-48v-800wdisc-brake-p-163.html
Plus: can be equipped with thermal sensor that can be read by the controller.
Battery pack - this is a bit more complicated because I want to build it myself. Here's what I came up with:
*LiFePo4 chemistry - it just seems safer than LiPo; lower power and energy density than LiPo, but more "tame"
*16s 48VDC min pack
*either Phostech pat.C 1200mAh cell or Microvast 1100mAh cell. Both from ebay, both found some tests that show the real capacity may be more something like 1-1.05Ah; 18650 size; I plan to get a few extra just to account for possible cell-to-cell variations in capacity
==> 16 of these should give some 16-18Ah; both cells can take 5c continuous
*I only plan to charge with BMS. Discharge will be directly to the inverter with short-circuit cell protection and current-limited with the inverter
*BMS: not clear. There is the one below from ebay which should do the job, 48V and 60A max with 60V cutoff. Since I want it to be used only for charging I don't care about its weight or volume. I am searching for something better though, something where I can adjust the cutoff voltage when full.
http://www.ebay.com/itm/48V-60A-LiFePo4-Battery-BMS-LFP-PCM-SMT-System-16S-16x-3-2V-eBike-Battery-16x-3V-/321048911039?pt=LH_DefaultDomain_0&hash=item4ac0019cbf
Thanks for reading if you got so far. The basic idea was to draw a mission profile, see max speed to choose voltage, then try to "guesstimate" max current in order to pick the proper cells and the number of parallel circuits. Since I don't plan on mounting a BMS on the bike I need an intelligent inverter, and the Kelly seems to do the job. I would need some input regarding the components picked up or whatever else comes to your mind. Do you have experience with either of them?
Cheers
P.S. This is supposed to be a testing vehicle; I plan to profile temps, record mission profiles, do efficiency maps for the motor and play with cutoff voltages for the battery to improve the system. Then to do a second better bike for the missus
Hard to say in a few lines, but bare with me:
*the mission profile would be to assist the rider to go up from 25 to around 30-35km/h for 80-100km (15-20mph for 60 mi)
*weight bike + rider without EV ~90kg / 180pounds
*I've used some telemetry data that shows I rarely use more than 400W leg-power, less than 3% of the time (slightly hilly course, around 20km/h average speed). Average power around 250W.
*in regards to energy , an average 1 hour 20km/h tour used some 80Wh. For the EV at 48V this would only be under 2.5Ah if I take some 80% efficiency for the motor, 90% inverter and 90% for the battery pack.
*ran a mission profile of a slow acceleration from 0 to 20km/h in 20seconds electric-only - maximum DC current 4.5A @48V
That said, it looks like I don't need much power or torque, but I want to overprovision as there's little mass or $$$ penalty if I pick beefier inverter and motor. I was thinking of:
*Kelly 24-48V 30Amp Inverter @1.7pounds link:
http://kellycontroller.com/kbs48051el30a24-48v-mini-brushless-dc-controller-p-1170.html
==> this gives a peak 1.5kW @VDC_min; probably it depends on the temperature and one won't always be able to safely pull 30A
Pluses:
-configurable DC current limit. I intend to use this setting to tweak the power / range. Will use this setting to cap max DC current pull from the batteries.
-recovery configurable between 0-20% of torque; it's going to be a RWD bike, so recovery may interesting. Will increase recovery torque until it becomes annoying
*800W 48V Kelly hub motor @they say 27lbs (has to be a mistake, right? It seems like a lot for a motor)
http://kellycontroller.com/hub-motor-48v-800wdisc-brake-p-163.html
Plus: can be equipped with thermal sensor that can be read by the controller.
Battery pack - this is a bit more complicated because I want to build it myself. Here's what I came up with:
*LiFePo4 chemistry - it just seems safer than LiPo; lower power and energy density than LiPo, but more "tame"
*16s 48VDC min pack
*either Phostech pat.C 1200mAh cell or Microvast 1100mAh cell. Both from ebay, both found some tests that show the real capacity may be more something like 1-1.05Ah; 18650 size; I plan to get a few extra just to account for possible cell-to-cell variations in capacity
==> 16 of these should give some 16-18Ah; both cells can take 5c continuous
*I only plan to charge with BMS. Discharge will be directly to the inverter with short-circuit cell protection and current-limited with the inverter
*BMS: not clear. There is the one below from ebay which should do the job, 48V and 60A max with 60V cutoff. Since I want it to be used only for charging I don't care about its weight or volume. I am searching for something better though, something where I can adjust the cutoff voltage when full.
http://www.ebay.com/itm/48V-60A-LiFePo4-Battery-BMS-LFP-PCM-SMT-System-16S-16x-3-2V-eBike-Battery-16x-3V-/321048911039?pt=LH_DefaultDomain_0&hash=item4ac0019cbf
Thanks for reading if you got so far. The basic idea was to draw a mission profile, see max speed to choose voltage, then try to "guesstimate" max current in order to pick the proper cells and the number of parallel circuits. Since I don't plan on mounting a BMS on the bike I need an intelligent inverter, and the Kelly seems to do the job. I would need some input regarding the components picked up or whatever else comes to your mind. Do you have experience with either of them?
Cheers
P.S. This is supposed to be a testing vehicle; I plan to profile temps, record mission profiles, do efficiency maps for the motor and play with cutoff voltages for the battery to improve the system. Then to do a second better bike for the missus
