Brakes
I have already mentioned the brake system in earlier posts, and this is only to circumvent (follow?) the Swedish regulations for converting cars. It has nothing to do with the electric conversion.There is one more thing to the brakes though. Most modern cars have vacuum assisted brake servo and so does my A2. However, when the ICE is removed there is no source for vacuum so I will need a separate electric vacuum pump.
Motor and controller
The motor I plan to use is a Kostov K9" 220V. Kostov is a Bulgarian company who manufacture motors for fork lifts and now for DIY (Do It Yourself) electric cars. The motor develops 32 kW sustained and 78 kW peak. The peak power is only available during short accelerations for couple of seconds, but this is usually what you want power to. If you use the max power for much longer the motor and/or controller will overheat and shut down. The motor is rated for a voltage of 220V DC and at peak power the current will be 500A! It is not very big, only 22cm diameter, 46cm long and weighs 45kg!To control the speed of the motor I need a motor controller. The controller applies voltage in shorts bursts thereby limiting the average voltage and the speed. I am planning to use an Evnetics Soliton Jr which can handle up to 340V battery voltage and up to 600A motor current. This will be just right for the motor. I nice feature with the Soliton is that it is configurable via a standard Ethernet connection and a web browser.
Transmission
Transmision? Do you really need a transmission in an electric car? Well, it seems that the easiest way to convert a car to electric is actually to keep the transmission and the clutch. The available (affordable) electric motors have a torque curve that is usually flat up to around 3000rpm and then torque decreases down to the max rpm which is usually around 6000rpm. This means that if you go only one gear you either have to use a high gear to obtain a decent top speed. This means sluggish acceleration and high currents at low speed. Or you chose a low gear that gives you good low speed acceleration, but low top speed. An easier way is to keep the transmission and use two gears; second gear for city driving and fourth gear for highway, for example.Battery and charger
The most important part of the conversion (and the most expensive) is the battery pack. I am planning to use Lithiun Iron Phosfate (LiFePO4) cells which have a good combination of good energy density, life time, and security (they don't go in flames if you overcharge them which I have heard some other LiIon chemistrys do). The newer cells also work pretty well at low temperature which is important if you live in northern Sweden. Each cell has a nominal (the voltage changes during discharge) voltage of 3.2V and the battery pack voltage I am aiming for is 230V nominal. This means I will be using 72 cells. Each cell will hold a charge of 70 or 100Ah. I will decide which when I know the available space for batteries in the car. If I go for the 100Ah cells some math tells us that 72 x 3.2V x 100Ah = 23kWh of energy. The weight of the cells will be around 250kg so the car will probably become around 100-150 kg heavier than before the conversion. The cells I would like to use are manufactured in China by China Aviation Lithium Battery (CALB), but I haven't found a decent price on them yet.To charge the batteries I obviously need a charger. The standard Swedish power outlet is 230V,10A and a standard three phase outlet is 230V or 400V,16A. I have not decided on charger yet, but I would like it to be able to utilise both of these outlets. It will probably be a 3kW charger (230V,16A) since I haven't seen any reasonably priced 400V chargers.
Battery management and monitoring
Basicly the idea about battery monitoring and management is that you should not overcharge nor overdischarge the individual cells in your battery since this will decrease their life time. So, in order to prevent over discharge and overcharge a battery monitoring system can be used to detect potential over discharges (low cell voltage) and potential over charge (high cell voltage). Battery management systems then either disconnect a cell from charging using a shunt or shuts down the whole vehicle during discharge. The act of disconnecting a cell from charge results in a more even charge among the cells in the battery. This is called balancing the cells and specifically this is called top-balancing since the balancing is done near the maximum allowed charge of the cells.There is an ongoing debate in the DIY community about battery management and monitoring (BMS). The agument for not using a BMS is that the most damage to a cell is done when over discharging, not when over charging it. In order to prevent unbalance near the minimum allowed charge bottom balancing can be used onstead of a BMS. This is probably the route I will go and I will likely spend an upcoming post on the topic.
Is variomatic transmission impractical?
ReplyDeleteElectric motors tend to work more efficient at higher rpms compared to gasoline and diesel engines. Typically the current is lowest around 3000-4000 rpm. As far as I understand, automatic transmissions, including variomatics like Audis Multitronic, try to keep a lower rpm to reduce the gas consumption and that renders a higher energy consumption with electric motors. With a manual transmission the driver can choose to run the motor at a higher rpm which makes it more efficient.
ReplyDeleteI'm not sure that the RPM really matters - what will be more important is the top RPM of the motor (will be 11,000 or something) and the effective speed. You'll probably find just 3rd gear is fine. Note that the use of a gearbox has two possible -ve consequences; 1) reduces efficiency, 2) it might not handle the torque and break...
ReplyDeleteIs it a DC motor?
ReplyDeleteThe Kostov is a DC motor with a top RPM of 6500 and a max torque of 175 Nm (at 4200 RPM).
ReplyDeleteThe 1.4 litre petrol engine in the A2 delivers a max torque of 126 NM so the electric motor delivers almost 40% more torque! This is peak torque however, annd it can only be used for short bursts. The gearbox in the 1.4 petrol is designed for a max torque of 200 Nm so there is some margin with that gearbox. The diesel version of the A2, the 1.4 TDI, delivers a max torque of 195Nm and it's gearbox is suitable for torques up to 250Nm. The swedish car building regulations might make it necessary for me to also change the gearbox, and in that case I will use the diesel box. That will give me some more margin for the stronger motor.
Kostov @220V and @600 amps is 132 KW peak electric input not 78 KW.
ReplyDeleteIf you're not running a battery pack to take advantage of the 220 volts (after sag) then you won;t get full use of the RPM's. Consider than the normal LV K9 and use the Soliton to control motor voltage.
144V @ 600 amps = 86 KW peak electric input.
By using new Calb grey cells, 132 KW is achievable, and will make for a hot hatch. Just don't tell the authorities!
Well, 132kW in the little A2 sure would be fun!
ReplyDeleteHas anyone tested to run 600A through a Kostov K9 220V?
According to Kostovs performance figures (http://kostov-motors.com/files/productattachments/6ff70418861d3230f01fc0340802fb1f_S220E01.pdf) the K9 delivers a peak power of 78kW at 500A. In their measurements, the voltage had then dropped from 210V @ 32kW to around 198V @ 78kW resulting in an efficiency of about 79%.
I've seen people testing the CALB grey cells for voltage sag when pulling high currents from them. I think 12C has been tested (12C means 1200A from a 100Ah cell!). What I have not seen is what hight currents does to the life time of the cells. A current of 500A for a 100Ah cell is 5C and CALB states that tha maximum discharge current is 2C, that is 200A. At 200A the Kostov K9-200 delivers 36 kW, which is more than enough for sustained work, but maybe a little poor for accelerations.
I was showing your peak possible electrical input to motor. KW at rear wheel would be roughly:
ReplyDelete230v * 600 *.90 *.80 *.95 = 95 KW
where the losses are battery sag @6C, motor efficiency, and other losses.
I prefer to use electric input as that it more comparable to ICE KW in a apple vs orange comparison.
K9 would be fine with 600 amps in short bursts.
Calb cells @6C for short bursts is no big deal. The more important issue is your long term continuous discharge rate. You want this close to 1C.
New Calb cells have been tested by Jack Richard @ 3C continuous with little heat or other obvious showing of stress - but that is not a life cycle test.
I haven't heard of any DIYer admit to any noticeable cycle life loss attributed to heavy gas pedal usage. Only when pack undersized for continuous duty.